mongoose/mongoose.c
2024-01-23 11:10:15 +00:00

15661 lines
526 KiB
C

// Copyright (c) 2004-2013 Sergey Lyubka
// Copyright (c) 2013-2024 Cesanta Software Limited
// All rights reserved
//
// This software is dual-licensed: you can redistribute it and/or modify
// it under the terms of the GNU General Public License version 2 as
// published by the Free Software Foundation. For the terms of this
// license, see http://www.gnu.org/licenses/
//
// You are free to use this software under the terms of the GNU General
// Public License, but WITHOUT ANY WARRANTY; without even the implied
// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
// See the GNU General Public License for more details.
//
// Alternatively, you can license this software under a commercial
// license, as set out in https://www.mongoose.ws/licensing/
//
// SPDX-License-Identifier: GPL-2.0-only or commercial
#include "mongoose.h"
#ifdef MG_ENABLE_LINES
#line 1 "src/base64.c"
#endif
static int mg_base64_encode_single(int c) {
if (c < 26) {
return c + 'A';
} else if (c < 52) {
return c - 26 + 'a';
} else if (c < 62) {
return c - 52 + '0';
} else {
return c == 62 ? '+' : '/';
}
}
static int mg_base64_decode_single(int c) {
if (c >= 'A' && c <= 'Z') {
return c - 'A';
} else if (c >= 'a' && c <= 'z') {
return c + 26 - 'a';
} else if (c >= '0' && c <= '9') {
return c + 52 - '0';
} else if (c == '+') {
return 62;
} else if (c == '/') {
return 63;
} else if (c == '=') {
return 64;
} else {
return -1;
}
}
size_t mg_base64_update(unsigned char ch, char *to, size_t n) {
unsigned long rem = (n & 3) % 3;
if (rem == 0) {
to[n] = (char) mg_base64_encode_single(ch >> 2);
to[++n] = (char) ((ch & 3) << 4);
} else if (rem == 1) {
to[n] = (char) mg_base64_encode_single(to[n] | (ch >> 4));
to[++n] = (char) ((ch & 15) << 2);
} else {
to[n] = (char) mg_base64_encode_single(to[n] | (ch >> 6));
to[++n] = (char) mg_base64_encode_single(ch & 63);
n++;
}
return n;
}
size_t mg_base64_final(char *to, size_t n) {
size_t saved = n;
// printf("---[%.*s]\n", n, to);
if (n & 3) n = mg_base64_update(0, to, n);
if ((saved & 3) == 2) n--;
// printf(" %d[%.*s]\n", n, n, to);
while (n & 3) to[n++] = '=';
to[n] = '\0';
return n;
}
size_t mg_base64_encode(const unsigned char *p, size_t n, char *to, size_t dl) {
size_t i, len = 0;
if (dl > 0) to[0] = '\0';
if (dl < ((n / 3) + (n % 3 ? 1 : 0)) * 4 + 1) return 0;
for (i = 0; i < n; i++) len = mg_base64_update(p[i], to, len);
len = mg_base64_final(to, len);
return len;
}
size_t mg_base64_decode(const char *src, size_t n, char *dst, size_t dl) {
const char *end = src == NULL ? NULL : src + n; // Cannot add to NULL
size_t len = 0;
if (dl < n / 4 * 3 + 1) goto fail;
while (src != NULL && src + 3 < end) {
int a = mg_base64_decode_single(src[0]),
b = mg_base64_decode_single(src[1]),
c = mg_base64_decode_single(src[2]),
d = mg_base64_decode_single(src[3]);
if (a == 64 || a < 0 || b == 64 || b < 0 || c < 0 || d < 0) {
goto fail;
}
dst[len++] = (char) ((a << 2) | (b >> 4));
if (src[2] != '=') {
dst[len++] = (char) ((b << 4) | (c >> 2));
if (src[3] != '=') dst[len++] = (char) ((c << 6) | d);
}
src += 4;
}
dst[len] = '\0';
return len;
fail:
if (dl > 0) dst[0] = '\0';
return 0;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/device_ch32v307.c"
#endif
#if MG_DEVICE == MG_DEVICE_CH32V307
// RM: https://www.wch-ic.com/downloads/CH32FV2x_V3xRM_PDF.html
#define FLASH_BASE 0x40022000
#define FLASH_ACTLR (FLASH_BASE + 0)
#define FLASH_KEYR (FLASH_BASE + 4)
#define FLASH_OBKEYR (FLASH_BASE + 8)
#define FLASH_STATR (FLASH_BASE + 12)
#define FLASH_CTLR (FLASH_BASE + 16)
#define FLASH_ADDR (FLASH_BASE + 20)
#define FLASH_OBR (FLASH_BASE + 28)
#define FLASH_WPR (FLASH_BASE + 32)
void *mg_flash_start(void) {
return (void *) 0x08000000;
}
size_t mg_flash_size(void) {
return 480 * 1024; // First 320k is 0-wait
}
size_t mg_flash_sector_size(void) {
return 4096;
}
size_t mg_flash_write_align(void) {
return 4;
}
int mg_flash_bank(void) {
return 0;
}
void mg_device_reset(void) {
*((volatile uint32_t *) 0xbeef0000) |= 1U << 7; // NVIC_SystemReset()
}
static void flash_unlock(void) {
static bool unlocked;
if (unlocked == false) {
MG_REG(FLASH_KEYR) = 0x45670123;
MG_REG(FLASH_KEYR) = 0xcdef89ab;
unlocked = true;
}
}
static void flash_wait(void) {
while (MG_REG(FLASH_STATR) & MG_BIT(0)) (void) 0;
}
bool mg_flash_erase(void *addr) {
//MG_INFO(("%p", addr));
flash_unlock();
flash_wait();
MG_REG(FLASH_ADDR) = (uint32_t) addr;
MG_REG(FLASH_CTLR) |= MG_BIT(1) | MG_BIT(6); // PER | STRT;
flash_wait();
return true;
}
static bool is_page_boundary(const void *addr) {
uint32_t val = (uint32_t) addr;
return (val & (mg_flash_sector_size() - 1)) == 0;
}
bool mg_flash_write(void *addr, const void *buf, size_t len) {
//MG_INFO(("%p %p %lu", addr, buf, len));
//mg_hexdump(buf, len);
flash_unlock();
const uint16_t *src = (uint16_t *) buf, *end = &src[len / 2];
uint16_t *dst = (uint16_t *) addr;
MG_REG(FLASH_CTLR) |= MG_BIT(0); // Set PG
//MG_INFO(("CTLR: %#lx", MG_REG(FLASH_CTLR)));
while (src < end) {
if (is_page_boundary(dst)) mg_flash_erase(dst);
*dst++ = *src++;
flash_wait();
}
MG_REG(FLASH_CTLR) &= ~MG_BIT(0); // Clear PG
return true;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/device_dummy.c"
#endif
#if MG_DEVICE == MG_DEVICE_NONE
void *mg_flash_start(void) {
return NULL;
}
size_t mg_flash_size(void) {
return 0;
}
size_t mg_flash_sector_size(void) {
return 0;
}
size_t mg_flash_write_align(void) {
return 0;
}
int mg_flash_bank(void) {
return 0;
}
bool mg_flash_erase(void *location) {
(void) location;
return false;
}
bool mg_flash_swap_bank(void) {
return true;
}
bool mg_flash_write(void *addr, const void *buf, size_t len) {
(void) addr, (void) buf, (void) len;
return false;
}
void mg_device_reset(void) {
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/device_flash.c"
#endif
#if MG_DEVICE == MG_DEVICE_STM32H7 || MG_DEVICE == MG_DEVICE_STM32H5 || \
MG_DEVICE == MG_DEVICE_RT1020 || MG_DEVICE == MG_DEVICE_RT1060
// Flash can be written only if it is erased. Erased flash is 0xff (all bits 1)
// Writes must be mg_flash_write_align() - aligned. Thus if we want to save an
// object, we pad it at the end for alignment.
//
// Objects in the flash sector are stored sequentially:
// | 32-bit size | 32-bit KEY | ..data.. | ..pad.. | 32-bit size | ......
//
// In order to get to the next object, read its size, then align up.
// Traverse the list of saved objects
size_t mg_flash_next(char *p, char *end, uint32_t *key, size_t *size) {
size_t aligned_size = 0, align = mg_flash_write_align(), left = end - p;
uint32_t *p32 = (uint32_t *) p, min_size = sizeof(uint32_t) * 2;
if (p32[0] != 0xffffffff && left > MG_ROUND_UP(min_size, align)) {
if (size) *size = (size_t) p32[0];
if (key) *key = p32[1];
aligned_size = MG_ROUND_UP(p32[0] + sizeof(uint32_t) * 2, align);
if (left < aligned_size) aligned_size = 0; // Out of bounds, fail
}
return aligned_size;
}
// Return the last sector of Bank 2
static char *flash_last_sector(void) {
size_t ss = mg_flash_sector_size(), size = mg_flash_size();
char *base = (char *) mg_flash_start(), *last = base + size - ss;
if (mg_flash_bank() == 2) last -= size / 2;
return last;
}
// Find a saved object with a given key
bool mg_flash_load(void *sector, uint32_t key, void *buf, size_t len) {
char *base = (char *) mg_flash_start(), *s = (char *) sector, *res = NULL;
size_t ss = mg_flash_sector_size(), ofs = 0, n, sz;
bool ok = false;
if (s == NULL) s = flash_last_sector();
if (s < base || s >= base + mg_flash_size()) {
MG_ERROR(("%p is outsize of flash", sector));
} else if (((s - base) % ss) != 0) {
MG_ERROR(("%p is not a sector boundary", sector));
} else {
uint32_t k, scanned = 0;
while ((n = mg_flash_next(s + ofs, s + ss, &k, &sz)) > 0) {
// MG_DEBUG((" > obj %lu, ofs %lu, key %x/%x", scanned, ofs, k, key));
// mg_hexdump(s + ofs, n);
if (k == key && sz == len) {
res = s + ofs + sizeof(uint32_t) * 2;
memcpy(buf, res, len); // Copy object
ok = true; // Keep scanning for the newer versions of it
}
ofs += n, scanned++;
}
MG_DEBUG(("Scanned %u objects, key %x is @ %p", scanned, key, res));
}
return ok;
}
// For all saved objects in the sector, delete old versions of objects
static void mg_flash_sector_cleanup(char *sector) {
// Buffer all saved objects into an IO buffer (backed by RAM)
// erase sector, and re-save them.
struct mg_iobuf io = {0, 0, 0, 2048};
size_t ss = mg_flash_sector_size();
size_t n, size, size2, ofs = 0, hs = sizeof(uint32_t) * 2;
uint32_t key;
// Traverse all objects
MG_DEBUG(("Cleaning up sector %p", sector));
while ((n = mg_flash_next(sector + ofs, sector + ss, &key, &size)) > 0) {
// Delete an old copy of this object in the cache
for (size_t o = 0; o < io.len; o += size2 + hs) {
uint32_t k = *(uint32_t *) (io.buf + o + sizeof(uint32_t));
size2 = *(uint32_t *) (io.buf + o);
if (k == key) {
mg_iobuf_del(&io, o, size2 + hs);
break;
}
}
// And add the new copy
mg_iobuf_add(&io, io.len, sector + ofs, size + hs);
ofs += n;
}
// All objects are cached in RAM now
if (mg_flash_erase(sector)) { // Erase sector. If successful,
for (ofs = 0; ofs < io.len; ofs += size + hs) { // Traverse cached objects
size = *(uint32_t *) (io.buf + ofs);
key = *(uint32_t *) (io.buf + ofs + sizeof(uint32_t));
mg_flash_save(sector, key, io.buf + ofs + hs, size); // Save to flash
}
}
mg_iobuf_free(&io);
}
// Save an object with a given key - append to the end of an object list
bool mg_flash_save(void *sector, uint32_t key, const void *buf, size_t len) {
char *base = (char *) mg_flash_start(), *s = (char *) sector;
size_t ss = mg_flash_sector_size(), ofs = 0, n;
bool ok = false;
if (s == NULL) s = flash_last_sector();
if (s < base || s >= base + mg_flash_size()) {
MG_ERROR(("%p is outsize of flash", sector));
} else if (((s - base) % ss) != 0) {
MG_ERROR(("%p is not a sector boundary", sector));
} else {
char ab[mg_flash_write_align()]; // Aligned write block
uint32_t hdr[2] = {(uint32_t) len, key};
size_t needed = sizeof(hdr) + len;
size_t needed_aligned = MG_ROUND_UP(needed, sizeof(ab));
while ((n = mg_flash_next(s + ofs, s + ss, NULL, NULL)) > 0) ofs += n;
// If there is not enough space left, cleanup sector and re-eval ofs
if (ofs + needed_aligned >= ss) {
mg_flash_sector_cleanup(s);
ofs = 0;
while ((n = mg_flash_next(s + ofs, s + ss, NULL, NULL)) > 0) ofs += n;
}
if (ofs + needed_aligned <= ss) {
// Enough space to save this object
if (sizeof(ab) < sizeof(hdr)) {
// Flash write granularity is 32 bit or less, write with no buffering
ok = mg_flash_write(s + ofs, hdr, sizeof(hdr));
if (ok) mg_flash_write(s + ofs + sizeof(hdr), buf, len);
} else {
// Flash granularity is sizeof(hdr) or more. We need to save in
// 3 chunks: initial block, bulk, rest. This is because we have
// two memory chunks to write: hdr and buf, on aligned boundaries.
n = sizeof(ab) - sizeof(hdr); // Initial chunk that we write
if (n > len) n = len; // is
memset(ab, 0xff, sizeof(ab)); // initialized to all-one
memcpy(ab, hdr, sizeof(hdr)); // contains the header (key + size)
memcpy(ab + sizeof(hdr), buf, n); // and an initial part of buf
MG_INFO(("saving initial block of %lu", sizeof(ab)));
ok = mg_flash_write(s + ofs, ab, sizeof(ab));
if (ok && len > n) {
size_t n2 = MG_ROUND_DOWN(len - n, sizeof(ab));
if (n2 > 0) {
MG_INFO(("saving bulk, %lu", n2));
ok = mg_flash_write(s + ofs + sizeof(ab), (char *) buf + n, n2);
}
if (ok && len > n) {
size_t n3 = len - n - n2;
if (n3 > sizeof(ab)) n3 = sizeof(ab);
memset(ab, 0xff, sizeof(ab));
memcpy(ab, (char *) buf + n + n2, n3);
MG_INFO(("saving rest, %lu", n3));
ok = mg_flash_write(s + ofs + sizeof(ab) + n2, ab, sizeof(ab));
}
}
}
MG_DEBUG(("Saved %lu/%lu bytes @ %p, key %x: %d", len, needed_aligned,
s + ofs, key, ok));
MG_DEBUG(("Sector space left: %lu bytes", ss - ofs - needed_aligned));
} else {
MG_ERROR(("Sector is full"));
}
}
return ok;
}
#else
bool mg_flash_save(void *sector, uint32_t key, const void *buf, size_t len) {
(void) sector, (void) key, (void) buf, (void) len;
return false;
}
bool mg_flash_load(void *sector, uint32_t key, void *buf, size_t len) {
(void) sector, (void) key, (void) buf, (void) len;
return false;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/device_imxrt.c"
#endif
#if MG_DEVICE == MG_DEVICE_RT1020 || MG_DEVICE == MG_DEVICE_RT1060
struct mg_flexspi_lut_seq {
uint8_t seqNum;
uint8_t seqId;
uint16_t reserved;
};
struct mg_flexspi_mem_config {
uint32_t tag;
uint32_t version;
uint32_t reserved0;
uint8_t readSampleClkSrc;
uint8_t csHoldTime;
uint8_t csSetupTime;
uint8_t columnAddressWidth;
uint8_t deviceModeCfgEnable;
uint8_t deviceModeType;
uint16_t waitTimeCfgCommands;
struct mg_flexspi_lut_seq deviceModeSeq;
uint32_t deviceModeArg;
uint8_t configCmdEnable;
uint8_t configModeType[3];
struct mg_flexspi_lut_seq configCmdSeqs[3];
uint32_t reserved1;
uint32_t configCmdArgs[3];
uint32_t reserved2;
uint32_t controllerMiscOption;
uint8_t deviceType;
uint8_t sflashPadType;
uint8_t serialClkFreq;
uint8_t lutCustomSeqEnable;
uint32_t reserved3[2];
uint32_t sflashA1Size;
uint32_t sflashA2Size;
uint32_t sflashB1Size;
uint32_t sflashB2Size;
uint32_t csPadSettingOverride;
uint32_t sclkPadSettingOverride;
uint32_t dataPadSettingOverride;
uint32_t dqsPadSettingOverride;
uint32_t timeoutInMs;
uint32_t commandInterval;
uint16_t dataValidTime[2];
uint16_t busyOffset;
uint16_t busyBitPolarity;
uint32_t lookupTable[64];
struct mg_flexspi_lut_seq lutCustomSeq[12];
uint32_t reserved4[4];
};
struct mg_flexspi_nor_config {
struct mg_flexspi_mem_config memConfig;
uint32_t pageSize;
uint32_t sectorSize;
uint8_t ipcmdSerialClkFreq;
uint8_t isUniformBlockSize;
uint8_t reserved0[2];
uint8_t serialNorType;
uint8_t needExitNoCmdMode;
uint8_t halfClkForNonReadCmd;
uint8_t needRestoreNoCmdMode;
uint32_t blockSize;
uint32_t reserve2[11];
};
/* FLEXSPI memory config block related defintions */
#define MG_FLEXSPI_CFG_BLK_TAG (0x42464346UL) // ascii "FCFB" Big Endian
#define MG_FLEXSPI_CFG_BLK_VERSION (0x56010400UL) // V1.4.0
#define MG_FLEXSPI_LUT_SEQ(cmd0, pad0, op0, cmd1, pad1, op1) \
(MG_FLEXSPI_LUT_OPERAND0(op0) | MG_FLEXSPI_LUT_NUM_PADS0(pad0) | MG_FLEXSPI_LUT_OPCODE0(cmd0) | \
MG_FLEXSPI_LUT_OPERAND1(op1) | MG_FLEXSPI_LUT_NUM_PADS1(pad1) | MG_FLEXSPI_LUT_OPCODE1(cmd1))
#define MG_CMD_SDR 0x01
#define MG_CMD_DDR 0x21
#define MG_DUMMY_SDR 0x0C
#define MG_DUMMY_DDR 0x2C
#define MG_RADDR_SDR 0x02
#define MG_RADDR_DDR 0x22
#define MG_READ_SDR 0x09
#define MG_READ_DDR 0x29
#define MG_WRITE_SDR 0x08
#define MG_WRITE_DDR 0x28
#define MG_STOP 0
#define MG_FLEXSPI_1PAD 0
#define MG_FLEXSPI_2PAD 1
#define MG_FLEXSPI_4PAD 2
#define MG_FLEXSPI_8PAD 3
#define MG_FLEXSPI_QSPI_LUT \
{ \
[0] = MG_FLEXSPI_LUT_SEQ(MG_CMD_SDR, MG_FLEXSPI_1PAD, 0xEB, MG_RADDR_SDR, MG_FLEXSPI_4PAD, \
0x18), \
[1] = MG_FLEXSPI_LUT_SEQ(MG_DUMMY_SDR, MG_FLEXSPI_4PAD, 0x06, MG_READ_SDR, MG_FLEXSPI_4PAD, \
0x04), \
[4 * 1 + 0] = \
MG_FLEXSPI_LUT_SEQ(MG_CMD_SDR, MG_FLEXSPI_1PAD, 0x05, MG_READ_SDR, MG_FLEXSPI_1PAD, 0x04), \
[4 * 3 + 0] = \
MG_FLEXSPI_LUT_SEQ(MG_CMD_SDR, MG_FLEXSPI_1PAD, 0x06, MG_STOP, MG_FLEXSPI_1PAD, 0x0), \
[4 * 5 + 0] = MG_FLEXSPI_LUT_SEQ(MG_CMD_SDR, MG_FLEXSPI_1PAD, 0x20, MG_RADDR_SDR, \
MG_FLEXSPI_1PAD, 0x18), \
[4 * 8 + 0] = MG_FLEXSPI_LUT_SEQ(MG_CMD_SDR, MG_FLEXSPI_1PAD, 0xD8, MG_RADDR_SDR, \
MG_FLEXSPI_1PAD, 0x18), \
[4 * 9 + 0] = MG_FLEXSPI_LUT_SEQ(MG_CMD_SDR, MG_FLEXSPI_1PAD, 0x02, MG_RADDR_SDR, \
MG_FLEXSPI_1PAD, 0x18), \
[4 * 9 + 1] = \
MG_FLEXSPI_LUT_SEQ(MG_WRITE_SDR, MG_FLEXSPI_1PAD, 0x04, MG_STOP, MG_FLEXSPI_1PAD, 0x0), \
[4 * 11 + 0] = \
MG_FLEXSPI_LUT_SEQ(MG_CMD_SDR, MG_FLEXSPI_1PAD, 0x60, MG_STOP, MG_FLEXSPI_1PAD, 0x0), \
}
#define MG_FLEXSPI_LUT_OPERAND0(x) (((uint32_t) (((uint32_t) (x)))) & 0xFFU)
#define MG_FLEXSPI_LUT_NUM_PADS0(x) (((uint32_t) (((uint32_t) (x)) << 8U)) & 0x300U)
#define MG_FLEXSPI_LUT_OPCODE0(x) (((uint32_t) (((uint32_t) (x)) << 10U)) & 0xFC00U)
#define MG_FLEXSPI_LUT_OPERAND1(x) (((uint32_t) (((uint32_t) (x)) << 16U)) & 0xFF0000U)
#define MG_FLEXSPI_LUT_NUM_PADS1(x) (((uint32_t) (((uint32_t) (x)) << 24U)) & 0x3000000U)
#define MG_FLEXSPI_LUT_OPCODE1(x) (((uint32_t) (((uint32_t) (x)) << 26U)) & 0xFC000000U)
#define FLEXSPI_NOR_INSTANCE 0
#if MG_DEVICE == MG_DEVICE_RT1020
struct mg_flexspi_nor_driver_interface {
uint32_t version;
int (*init)(uint32_t instance, struct mg_flexspi_nor_config *config);
int (*program)(uint32_t instance, struct mg_flexspi_nor_config *config, uint32_t dst_addr,
const uint32_t *src);
uint32_t reserved;
int (*erase)(uint32_t instance, struct mg_flexspi_nor_config *config, uint32_t start,
uint32_t lengthInBytes);
uint32_t reserved2;
int (*update_lut)(uint32_t instance, uint32_t seqIndex, const uint32_t *lutBase,
uint32_t seqNumber);
int (*xfer)(uint32_t instance, char *xfer);
void (*clear_cache)(uint32_t instance);
};
#elif MG_DEVICE == MG_DEVICE_RT1060
struct mg_flexspi_nor_driver_interface {
uint32_t version;
int (*init)(uint32_t instance, struct mg_flexspi_nor_config *config);
int (*program)(uint32_t instance, struct mg_flexspi_nor_config *config, uint32_t dst_addr,
const uint32_t *src);
int (*erase_all)(uint32_t instance, struct mg_flexspi_nor_config *config);
int (*erase)(uint32_t instance, struct mg_flexspi_nor_config *config, uint32_t start,
uint32_t lengthInBytes);
int (*read)(uint32_t instance, struct mg_flexspi_nor_config *config, uint32_t *dst, uint32_t addr,
uint32_t lengthInBytes);
void (*clear_cache)(uint32_t instance);
int (*xfer)(uint32_t instance, char *xfer);
int (*update_lut)(uint32_t instance, uint32_t seqIndex, const uint32_t *lutBase,
uint32_t seqNumber);
int (*get_config)(uint32_t instance, struct mg_flexspi_nor_config *config, uint32_t *option);
};
#endif
#define flexspi_nor (*((struct mg_flexspi_nor_driver_interface**) \
(*(uint32_t*)0x0020001c + 16)))
static bool s_flash_irq_disabled;
MG_IRAM void *mg_flash_start(void) {
return (void *) 0x60000000;
}
MG_IRAM size_t mg_flash_size(void) {
return 8 * 1024 * 1024;
}
MG_IRAM size_t mg_flash_sector_size(void) {
return 4 * 1024; // 4k
}
MG_IRAM size_t mg_flash_write_align(void) {
return 256;
}
MG_IRAM int mg_flash_bank(void) {
return 0;
}
MG_IRAM static bool flash_page_start(volatile uint32_t *dst) {
char *base = (char *) mg_flash_start(), *end = base + mg_flash_size();
volatile char *p = (char *) dst;
return p >= base && p < end && ((p - base) % mg_flash_sector_size()) == 0;
}
// Note: the get_config function below works both for RT1020 and 1060
#if MG_DEVICE == MG_DEVICE_RT1020
MG_IRAM static int flexspi_nor_get_config(struct mg_flexspi_nor_config *config) {
struct mg_flexspi_nor_config default_config = {
.memConfig = {.tag = MG_FLEXSPI_CFG_BLK_TAG,
.version = MG_FLEXSPI_CFG_BLK_VERSION,
.readSampleClkSrc = 1, // ReadSampleClk_LoopbackFromDqsPad
.csHoldTime = 3,
.csSetupTime = 3,
.controllerMiscOption = MG_BIT(4),
.deviceType = 1, // serial NOR
.sflashPadType = 4,
.serialClkFreq = 7, // 133MHz
.sflashA1Size = 8 * 1024 * 1024,
.lookupTable = MG_FLEXSPI_QSPI_LUT},
.pageSize = 256,
.sectorSize = 4 * 1024,
.ipcmdSerialClkFreq = 1,
.blockSize = 64 * 1024,
.isUniformBlockSize = false};
*config = default_config;
return 0;
}
#else
MG_IRAM static int flexspi_nor_get_config(struct mg_flexspi_nor_config *config) {
uint32_t options[] = {0xc0000000, 0x00};
MG_ARM_DISABLE_IRQ();
uint32_t status =
flexspi_nor->get_config(FLEXSPI_NOR_INSTANCE, config, options);
if (!s_flash_irq_disabled) {
MG_ARM_ENABLE_IRQ();
}
if (status) {
MG_ERROR(("Failed to extract flash configuration: status %u", status));
}
return status;
}
#endif
MG_IRAM bool mg_flash_erase(void *addr) {
struct mg_flexspi_nor_config config;
if (flexspi_nor_get_config(&config) != 0) {
return false;
}
if (flash_page_start(addr) == false) {
MG_ERROR(("%p is not on a sector boundary", addr));
return false;
}
void *dst = (void *)((char *) addr - (char *) mg_flash_start());
// Note: Interrupts must be disabled before any call to the ROM API on RT1020
// and 1060
MG_ARM_DISABLE_IRQ();
bool ok = (flexspi_nor->erase(FLEXSPI_NOR_INSTANCE, &config, (uint32_t) dst,
mg_flash_sector_size()) == 0);
if (!s_flash_irq_disabled) {
MG_ARM_ENABLE_IRQ(); // Reenable them after the call
}
MG_DEBUG(("Sector starting at %p erasure: %s", addr, ok ? "ok" : "fail"));
return ok;
}
MG_IRAM bool mg_flash_swap_bank() {
return true;
}
static inline void spin(volatile uint32_t count) {
while (count--) (void) 0;
}
static inline void flash_wait(void) {
while ((*((volatile uint32_t *)(0x402A8000 + 0xE0)) & MG_BIT(1)) == 0)
spin(1);
}
MG_IRAM static void *flash_code_location(void) {
return (void *) ((char *) mg_flash_start() + 0x2000);
}
MG_IRAM bool mg_flash_write(void *addr, const void *buf, size_t len) {
struct mg_flexspi_nor_config config;
if (flexspi_nor_get_config(&config) != 0) {
return false;
}
if ((len % mg_flash_write_align()) != 0) {
MG_ERROR(("%lu is not aligned to %lu", len, mg_flash_write_align()));
return false;
}
if ((char *) addr < (char *) mg_flash_start()) {
MG_ERROR(("Invalid flash write address: %p", addr));
return false;
}
uint32_t *dst = (uint32_t *) addr;
uint32_t *src = (uint32_t *) buf;
uint32_t *end = (uint32_t *) ((char *) buf + len);
bool ok = true;
// Note: If we overwrite the flash irq section of the image, we must also
// make sure interrupts are disabled and are not reenabled until we write
// this sector with another irq table.
if ((char *) addr == (char *) flash_code_location()) {
s_flash_irq_disabled = true;
MG_ARM_DISABLE_IRQ();
}
while (ok && src < end) {
if (flash_page_start(dst) && mg_flash_erase(dst) == false) {
break;
}
uint32_t status;
uint32_t dst_ofs = (uint32_t) dst - (uint32_t) mg_flash_start();
if ((char *) buf >= (char *) mg_flash_start()) {
// If we copy from FLASH to FLASH, then we first need to copy the source
// to RAM
size_t tmp_buf_size = mg_flash_write_align() / sizeof(uint32_t);
uint32_t tmp[tmp_buf_size];
for (size_t i = 0; i < tmp_buf_size; i++) {
flash_wait();
tmp[i] = src[i];
}
MG_ARM_DISABLE_IRQ();
status = flexspi_nor->program(FLEXSPI_NOR_INSTANCE, &config,
(uint32_t) dst_ofs, tmp);
} else {
MG_ARM_DISABLE_IRQ();
status = flexspi_nor->program(FLEXSPI_NOR_INSTANCE, &config,
(uint32_t) dst_ofs, src);
}
if (!s_flash_irq_disabled) {
MG_ARM_ENABLE_IRQ();
}
src = (uint32_t *) ((char *) src + mg_flash_write_align());
dst = (uint32_t *) ((char *) dst + mg_flash_write_align());
if (status != 0) {
ok = false;
}
}
MG_DEBUG(("Flash write %lu bytes @ %p: %s.", len, dst, ok ? "ok" : "fail"));
return ok;
}
MG_IRAM void mg_device_reset(void) {
MG_DEBUG(("Resetting device..."));
*(volatile unsigned long *) 0xe000ed0c = 0x5fa0004;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/device_stm32h5.c"
#endif
#if MG_DEVICE == MG_DEVICE_STM32H5
#define FLASH_BASE 0x40022000 // Base address of the flash controller
#define FLASH_KEYR (FLASH_BASE + 0x4) // See RM0481 7.11
#define FLASH_OPTKEYR (FLASH_BASE + 0xc)
#define FLASH_OPTCR (FLASH_BASE + 0x1c)
#define FLASH_NSSR (FLASH_BASE + 0x20)
#define FLASH_NSCR (FLASH_BASE + 0x28)
#define FLASH_NSCCR (FLASH_BASE + 0x30)
#define FLASH_OPTSR_CUR (FLASH_BASE + 0x50)
#define FLASH_OPTSR_PRG (FLASH_BASE + 0x54)
void *mg_flash_start(void) {
return (void *) 0x08000000;
}
size_t mg_flash_size(void) {
return 2 * 1024 * 1024; // 2Mb
}
size_t mg_flash_sector_size(void) {
return 8 * 1024; // 8k
}
size_t mg_flash_write_align(void) {
return 16; // 128 bit
}
int mg_flash_bank(void) {
return MG_REG(FLASH_OPTCR) & MG_BIT(31) ? 2 : 1;
}
static void flash_unlock(void) {
static bool unlocked = false;
if (unlocked == false) {
MG_REG(FLASH_KEYR) = 0x45670123;
MG_REG(FLASH_KEYR) = 0Xcdef89ab;
MG_REG(FLASH_OPTKEYR) = 0x08192a3b;
MG_REG(FLASH_OPTKEYR) = 0x4c5d6e7f;
unlocked = true;
}
}
static int flash_page_start(volatile uint32_t *dst) {
char *base = (char *) mg_flash_start(), *end = base + mg_flash_size();
volatile char *p = (char *) dst;
return p >= base && p < end && ((p - base) % mg_flash_sector_size()) == 0;
}
static bool flash_is_err(void) {
return MG_REG(FLASH_NSSR) & ((MG_BIT(8) - 1) << 17); // RM0481 7.11.9
}
static void flash_wait(void) {
while ((MG_REG(FLASH_NSSR) & MG_BIT(0)) &&
(MG_REG(FLASH_NSSR) & MG_BIT(16)) == 0) {
(void) 0;
}
}
static void flash_clear_err(void) {
flash_wait(); // Wait until ready
MG_REG(FLASH_NSCCR) = ((MG_BIT(9) - 1) << 16U); // Clear all errors
}
static bool flash_bank_is_swapped(void) {
return MG_REG(FLASH_OPTCR) & MG_BIT(31); // RM0481 7.11.8
}
bool mg_flash_erase(void *location) {
bool ok = false;
if (flash_page_start(location) == false) {
MG_ERROR(("%p is not on a sector boundary"));
} else {
uintptr_t diff = (char *) location - (char *) mg_flash_start();
uint32_t sector = diff / mg_flash_sector_size();
uint32_t saved_cr = MG_REG(FLASH_NSCR); // Save CR value
flash_unlock();
flash_clear_err();
MG_REG(FLASH_NSCR) = 0;
if ((sector < 128 && flash_bank_is_swapped()) ||
(sector > 127 && !flash_bank_is_swapped())) {
MG_REG(FLASH_NSCR) |= MG_BIT(31); // Set FLASH_CR_BKSEL
}
if (sector > 127) sector -= 128;
MG_REG(FLASH_NSCR) |= MG_BIT(2) | (sector << 6); // Erase | sector_num
MG_REG(FLASH_NSCR) |= MG_BIT(5); // Start erasing
flash_wait();
ok = !flash_is_err();
MG_DEBUG(("Erase sector %lu @ %p: %s. CR %#lx SR %#lx", sector, location,
ok ? "ok" : "fail", MG_REG(FLASH_NSCR), MG_REG(FLASH_NSSR)));
// mg_hexdump(location, 32);
MG_REG(FLASH_NSCR) = saved_cr; // Restore saved CR
}
return ok;
}
bool mg_flash_swap_bank(void) {
uint32_t desired = flash_bank_is_swapped() ? 0 : MG_BIT(31);
flash_unlock();
flash_clear_err();
// printf("OPTSR_PRG 1 %#lx\n", FLASH->OPTSR_PRG);
MG_SET_BITS(MG_REG(FLASH_OPTSR_PRG), MG_BIT(31), desired);
// printf("OPTSR_PRG 2 %#lx\n", FLASH->OPTSR_PRG);
MG_REG(FLASH_OPTCR) |= MG_BIT(1); // OPTSTART
while ((MG_REG(FLASH_OPTSR_CUR) & MG_BIT(31)) != desired) (void) 0;
return true;
}
bool mg_flash_write(void *addr, const void *buf, size_t len) {
if ((len % mg_flash_write_align()) != 0) {
MG_ERROR(("%lu is not aligned to %lu", len, mg_flash_write_align()));
return false;
}
uint32_t *dst = (uint32_t *) addr;
uint32_t *src = (uint32_t *) buf;
uint32_t *end = (uint32_t *) ((char *) buf + len);
bool ok = true;
flash_unlock();
flash_clear_err();
MG_ARM_DISABLE_IRQ();
// MG_DEBUG(("Starting flash write %lu bytes @ %p", len, addr));
MG_REG(FLASH_NSCR) = MG_BIT(1); // Set programming flag
while (ok && src < end) {
if (flash_page_start(dst) && mg_flash_erase(dst) == false) break;
*(volatile uint32_t *) dst++ = *src++;
flash_wait();
if (flash_is_err()) ok = false;
}
MG_ARM_ENABLE_IRQ();
MG_DEBUG(("Flash write %lu bytes @ %p: %s. CR %#lx SR %#lx", len, dst,
flash_is_err() ? "fail" : "ok", MG_REG(FLASH_NSCR),
MG_REG(FLASH_NSSR)));
MG_REG(FLASH_NSCR) = 0; // Clear flags
return ok;
}
void mg_device_reset(void) {
// SCB->AIRCR = ((0x5fa << SCB_AIRCR_VECTKEY_Pos)|SCB_AIRCR_SYSRESETREQ_Msk);
*(volatile unsigned long *) 0xe000ed0c = 0x5fa0004;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/device_stm32h7.c"
#endif
#if MG_DEVICE == MG_DEVICE_STM32H7
#define FLASH_BASE1 0x52002000 // Base address for bank1
#define FLASH_BASE2 0x52002100 // Base address for bank2
#define FLASH_KEYR 0x04 // See RM0433 4.9.2
#define FLASH_OPTKEYR 0x08
#define FLASH_OPTCR 0x18
#define FLASH_SR 0x10
#define FLASH_CR 0x0c
#define FLASH_CCR 0x14
#define FLASH_OPTSR_CUR 0x1c
#define FLASH_OPTSR_PRG 0x20
#define FLASH_SIZE_REG 0x1ff1e880
MG_IRAM void *mg_flash_start(void) {
return (void *) 0x08000000;
}
MG_IRAM size_t mg_flash_size(void) {
return MG_REG(FLASH_SIZE_REG) * 1024;
}
MG_IRAM size_t mg_flash_sector_size(void) {
return 128 * 1024; // 128k
}
MG_IRAM size_t mg_flash_write_align(void) {
return 32; // 256 bit
}
MG_IRAM int mg_flash_bank(void) {
if (mg_flash_size() < 2 * 1024 * 1024) return 0; // No dual bank support
return MG_REG(FLASH_BASE1 + FLASH_OPTCR) & MG_BIT(31) ? 2 : 1;
}
MG_IRAM static void flash_unlock(void) {
static bool unlocked = false;
if (unlocked == false) {
MG_REG(FLASH_BASE1 + FLASH_KEYR) = 0x45670123;
MG_REG(FLASH_BASE1 + FLASH_KEYR) = 0xcdef89ab;
if (mg_flash_bank() > 0) {
MG_REG(FLASH_BASE2 + FLASH_KEYR) = 0x45670123;
MG_REG(FLASH_BASE2 + FLASH_KEYR) = 0xcdef89ab;
}
MG_REG(FLASH_BASE1 + FLASH_OPTKEYR) = 0x08192a3b; // opt reg is "shared"
MG_REG(FLASH_BASE1 + FLASH_OPTKEYR) = 0x4c5d6e7f; // thus unlock once
unlocked = true;
}
}
MG_IRAM static bool flash_page_start(volatile uint32_t *dst) {
char *base = (char *) mg_flash_start(), *end = base + mg_flash_size();
volatile char *p = (char *) dst;
return p >= base && p < end && ((p - base) % mg_flash_sector_size()) == 0;
}
MG_IRAM static bool flash_is_err(uint32_t bank) {
return MG_REG(bank + FLASH_SR) & ((MG_BIT(11) - 1) << 17); // RM0433 4.9.5
}
MG_IRAM static void flash_wait(uint32_t bank) {
while (MG_REG(bank + FLASH_SR) & (MG_BIT(0) | MG_BIT(2))) (void) 0;
}
MG_IRAM static void flash_clear_err(uint32_t bank) {
flash_wait(bank); // Wait until ready
MG_REG(bank + FLASH_CCR) = ((MG_BIT(11) - 1) << 16U); // Clear all errors
}
MG_IRAM static bool flash_bank_is_swapped(uint32_t bank) {
return MG_REG(bank + FLASH_OPTCR) & MG_BIT(31); // RM0433 4.9.7
}
// Figure out flash bank based on the address
MG_IRAM static uint32_t flash_bank(void *addr) {
size_t ofs = (char *) addr - (char *) mg_flash_start();
if (mg_flash_bank() == 0) return FLASH_BASE1;
return ofs < mg_flash_size() / 2 ? FLASH_BASE1 : FLASH_BASE2;
}
MG_IRAM bool mg_flash_erase(void *addr) {
bool ok = false;
if (flash_page_start(addr) == false) {
MG_ERROR(("%p is not on a sector boundary", addr));
} else {
uintptr_t diff = (char *) addr - (char *) mg_flash_start();
uint32_t sector = diff / mg_flash_sector_size();
uint32_t bank = flash_bank(addr);
uint32_t saved_cr = MG_REG(bank + FLASH_CR); // Save CR value
flash_unlock();
if (sector > 7) sector -= 8;
flash_clear_err(bank);
MG_REG(bank + FLASH_CR) = MG_BIT(5); // 32-bit write parallelism
MG_REG(bank + FLASH_CR) |= (sector & 7U) << 8U; // Sector to erase
MG_REG(bank + FLASH_CR) |= MG_BIT(2); // Sector erase bit
MG_REG(bank + FLASH_CR) |= MG_BIT(7); // Start erasing
ok = !flash_is_err(bank);
MG_DEBUG(("Erase sector %lu @ %p %s. CR %#lx SR %#lx", sector, addr,
ok ? "ok" : "fail", MG_REG(bank + FLASH_CR),
MG_REG(bank + FLASH_SR)));
MG_REG(bank + FLASH_CR) = saved_cr; // Restore CR
}
return ok;
}
MG_IRAM bool mg_flash_swap_bank() {
if (mg_flash_bank() == 0) return true;
uint32_t bank = FLASH_BASE1;
uint32_t desired = flash_bank_is_swapped(bank) ? 0 : MG_BIT(31);
flash_unlock();
flash_clear_err(bank);
// printf("OPTSR_PRG 1 %#lx\n", FLASH->OPTSR_PRG);
MG_SET_BITS(MG_REG(bank + FLASH_OPTSR_PRG), MG_BIT(31), desired);
// printf("OPTSR_PRG 2 %#lx\n", FLASH->OPTSR_PRG);
MG_REG(bank + FLASH_OPTCR) |= MG_BIT(1); // OPTSTART
while ((MG_REG(bank + FLASH_OPTSR_CUR) & MG_BIT(31)) != desired) (void) 0;
return true;
}
MG_IRAM bool mg_flash_write(void *addr, const void *buf, size_t len) {
if ((len % mg_flash_write_align()) != 0) {
MG_ERROR(("%lu is not aligned to %lu", len, mg_flash_write_align()));
return false;
}
uint32_t bank = flash_bank(addr);
uint32_t *dst = (uint32_t *) addr;
uint32_t *src = (uint32_t *) buf;
uint32_t *end = (uint32_t *) ((char *) buf + len);
bool ok = true;
flash_unlock();
flash_clear_err(bank);
MG_REG(bank + FLASH_CR) = MG_BIT(1); // Set programming flag
MG_REG(bank + FLASH_CR) |= MG_BIT(5); // 32-bit write parallelism
MG_DEBUG(("Writing flash @ %p, %lu bytes", addr, len));
MG_ARM_DISABLE_IRQ();
while (ok && src < end) {
if (flash_page_start(dst) && mg_flash_erase(dst) == false) break;
*(volatile uint32_t *) dst++ = *src++;
flash_wait(bank);
if (flash_is_err(bank)) ok = false;
}
MG_ARM_ENABLE_IRQ();
MG_DEBUG(("Flash write %lu bytes @ %p: %s. CR %#lx SR %#lx", len, dst,
ok ? "ok" : "fail", MG_REG(bank + FLASH_CR),
MG_REG(bank + FLASH_SR)));
MG_REG(bank + FLASH_CR) &= ~MG_BIT(1); // Clear programming flag
return ok;
}
MG_IRAM void mg_device_reset(void) {
// SCB->AIRCR = ((0x5fa << SCB_AIRCR_VECTKEY_Pos)|SCB_AIRCR_SYSRESETREQ_Msk);
*(volatile unsigned long *) 0xe000ed0c = 0x5fa0004;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/dns.c"
#endif
struct dns_data {
struct dns_data *next;
struct mg_connection *c;
uint64_t expire;
uint16_t txnid;
};
static void mg_sendnsreq(struct mg_connection *, struct mg_str *, int,
struct mg_dns *, bool);
static void mg_dns_free(struct dns_data **head, struct dns_data *d) {
LIST_DELETE(struct dns_data, head, d);
free(d);
}
void mg_resolve_cancel(struct mg_connection *c) {
struct dns_data *tmp, *d;
struct dns_data **head = (struct dns_data **) &c->mgr->active_dns_requests;
for (d = *head; d != NULL; d = tmp) {
tmp = d->next;
if (d->c == c) mg_dns_free(head, d);
}
}
static size_t mg_dns_parse_name_depth(const uint8_t *s, size_t len, size_t ofs,
char *to, size_t tolen, size_t j,
int depth) {
size_t i = 0;
if (tolen > 0 && depth == 0) to[0] = '\0';
if (depth > 5) return 0;
// MG_INFO(("ofs %lx %x %x", (unsigned long) ofs, s[ofs], s[ofs + 1]));
while (ofs + i + 1 < len) {
size_t n = s[ofs + i];
if (n == 0) {
i++;
break;
}
if (n & 0xc0) {
size_t ptr = (((n & 0x3f) << 8) | s[ofs + i + 1]); // 12 is hdr len
// MG_INFO(("PTR %lx", (unsigned long) ptr));
if (ptr + 1 < len && (s[ptr] & 0xc0) == 0 &&
mg_dns_parse_name_depth(s, len, ptr, to, tolen, j, depth + 1) == 0)
return 0;
i += 2;
break;
}
if (ofs + i + n + 1 >= len) return 0;
if (j > 0) {
if (j < tolen) to[j] = '.';
j++;
}
if (j + n < tolen) memcpy(&to[j], &s[ofs + i + 1], n);
j += n;
i += n + 1;
if (j < tolen) to[j] = '\0'; // Zero-terminate this chunk
// MG_INFO(("--> [%s]", to));
}
if (tolen > 0) to[tolen - 1] = '\0'; // Make sure make sure it is nul-term
return i;
}
static size_t mg_dns_parse_name(const uint8_t *s, size_t n, size_t ofs,
char *dst, size_t dstlen) {
return mg_dns_parse_name_depth(s, n, ofs, dst, dstlen, 0, 0);
}
size_t mg_dns_parse_rr(const uint8_t *buf, size_t len, size_t ofs,
bool is_question, struct mg_dns_rr *rr) {
const uint8_t *s = buf + ofs, *e = &buf[len];
memset(rr, 0, sizeof(*rr));
if (len < sizeof(struct mg_dns_header)) return 0; // Too small
if (len > 512) return 0; // Too large, we don't expect that
if (s >= e) return 0; // Overflow
if ((rr->nlen = (uint16_t) mg_dns_parse_name(buf, len, ofs, NULL, 0)) == 0)
return 0;
s += rr->nlen + 4;
if (s > e) return 0;
rr->atype = (uint16_t) (((uint16_t) s[-4] << 8) | s[-3]);
rr->aclass = (uint16_t) (((uint16_t) s[-2] << 8) | s[-1]);
if (is_question) return (size_t) (rr->nlen + 4);
s += 6;
if (s > e) return 0;
rr->alen = (uint16_t) (((uint16_t) s[-2] << 8) | s[-1]);
if (s + rr->alen > e) return 0;
return (size_t) (rr->nlen + rr->alen + 10);
}
bool mg_dns_parse(const uint8_t *buf, size_t len, struct mg_dns_message *dm) {
const struct mg_dns_header *h = (struct mg_dns_header *) buf;
struct mg_dns_rr rr;
size_t i, n, ofs = sizeof(*h);
memset(dm, 0, sizeof(*dm));
if (len < sizeof(*h)) return 0; // Too small, headers dont fit
if (mg_ntohs(h->num_questions) > 1) return 0; // Sanity
if (mg_ntohs(h->num_answers) > 15) return 0; // Sanity
dm->txnid = mg_ntohs(h->txnid);
for (i = 0; i < mg_ntohs(h->num_questions); i++) {
if ((n = mg_dns_parse_rr(buf, len, ofs, true, &rr)) == 0) return false;
// MG_INFO(("Q %lu %lu %hu/%hu", ofs, n, rr.atype, rr.aclass));
ofs += n;
}
for (i = 0; i < mg_ntohs(h->num_answers); i++) {
if ((n = mg_dns_parse_rr(buf, len, ofs, false, &rr)) == 0) return false;
// MG_INFO(("A -- %lu %lu %hu/%hu %s", ofs, n, rr.atype, rr.aclass,
// dm->name));
mg_dns_parse_name(buf, len, ofs, dm->name, sizeof(dm->name));
ofs += n;
if (rr.alen == 4 && rr.atype == 1 && rr.aclass == 1) {
dm->addr.is_ip6 = false;
memcpy(&dm->addr.ip, &buf[ofs - 4], 4);
dm->resolved = true;
break; // Return success
} else if (rr.alen == 16 && rr.atype == 28 && rr.aclass == 1) {
dm->addr.is_ip6 = true;
memcpy(&dm->addr.ip, &buf[ofs - 16], 16);
dm->resolved = true;
break; // Return success
}
}
return true;
}
static void dns_cb(struct mg_connection *c, int ev, void *ev_data) {
struct dns_data *d, *tmp;
struct dns_data **head = (struct dns_data **) &c->mgr->active_dns_requests;
if (ev == MG_EV_POLL) {
uint64_t now = *(uint64_t *) ev_data;
for (d = *head; d != NULL; d = tmp) {
tmp = d->next;
// MG_DEBUG ("%lu %lu dns poll", d->expire, now));
if (now > d->expire) mg_error(d->c, "DNS timeout");
}
} else if (ev == MG_EV_READ) {
struct mg_dns_message dm;
int resolved = 0;
if (mg_dns_parse(c->recv.buf, c->recv.len, &dm) == false) {
MG_ERROR(("Unexpected DNS response:"));
mg_hexdump(c->recv.buf, c->recv.len);
} else {
// MG_VERBOSE(("%s %d", dm.name, dm.resolved));
for (d = *head; d != NULL; d = tmp) {
tmp = d->next;
// MG_INFO(("d %p %hu %hu", d, d->txnid, dm.txnid));
if (dm.txnid != d->txnid) continue;
if (d->c->is_resolving) {
if (dm.resolved) {
dm.addr.port = d->c->rem.port; // Save port
d->c->rem = dm.addr; // Copy resolved address
MG_DEBUG(
("%lu %s is %M", d->c->id, dm.name, mg_print_ip, &d->c->rem));
mg_connect_resolved(d->c);
#if MG_ENABLE_IPV6
} else if (dm.addr.is_ip6 == false && dm.name[0] != '\0' &&
c->mgr->use_dns6 == false) {
struct mg_str x = mg_str(dm.name);
mg_sendnsreq(d->c, &x, c->mgr->dnstimeout, &c->mgr->dns6, true);
#endif
} else {
mg_error(d->c, "%s DNS lookup failed", dm.name);
}
} else {
MG_ERROR(("%lu already resolved", d->c->id));
}
mg_dns_free(head, d);
resolved = 1;
}
}
if (!resolved) MG_ERROR(("stray DNS reply"));
c->recv.len = 0;
} else if (ev == MG_EV_CLOSE) {
for (d = *head; d != NULL; d = tmp) {
tmp = d->next;
mg_error(d->c, "DNS error");
mg_dns_free(head, d);
}
}
}
static bool mg_dns_send(struct mg_connection *c, const struct mg_str *name,
uint16_t txnid, bool ipv6) {
struct {
struct mg_dns_header header;
uint8_t data[256];
} pkt;
size_t i, n;
memset(&pkt, 0, sizeof(pkt));
pkt.header.txnid = mg_htons(txnid);
pkt.header.flags = mg_htons(0x100);
pkt.header.num_questions = mg_htons(1);
for (i = n = 0; i < sizeof(pkt.data) - 5; i++) {
if (name->ptr[i] == '.' || i >= name->len) {
pkt.data[n] = (uint8_t) (i - n);
memcpy(&pkt.data[n + 1], name->ptr + n, i - n);
n = i + 1;
}
if (i >= name->len) break;
}
memcpy(&pkt.data[n], "\x00\x00\x01\x00\x01", 5); // A query
n += 5;
if (ipv6) pkt.data[n - 3] = 0x1c; // AAAA query
// memcpy(&pkt.data[n], "\xc0\x0c\x00\x1c\x00\x01", 6); // AAAA query
// n += 6;
return mg_send(c, &pkt, sizeof(pkt.header) + n);
}
static void mg_sendnsreq(struct mg_connection *c, struct mg_str *name, int ms,
struct mg_dns *dnsc, bool ipv6) {
struct dns_data *d = NULL;
if (dnsc->url == NULL) {
mg_error(c, "DNS server URL is NULL. Call mg_mgr_init()");
} else if (dnsc->c == NULL) {
dnsc->c = mg_connect(c->mgr, dnsc->url, NULL, NULL);
if (dnsc->c != NULL) {
dnsc->c->pfn = dns_cb;
// dnsc->c->is_hexdumping = 1;
}
}
if (dnsc->c == NULL) {
mg_error(c, "resolver");
} else if ((d = (struct dns_data *) calloc(1, sizeof(*d))) == NULL) {
mg_error(c, "resolve OOM");
} else {
struct dns_data *reqs = (struct dns_data *) c->mgr->active_dns_requests;
d->txnid = reqs ? (uint16_t) (reqs->txnid + 1) : 1;
d->next = (struct dns_data *) c->mgr->active_dns_requests;
c->mgr->active_dns_requests = d;
d->expire = mg_millis() + (uint64_t) ms;
d->c = c;
c->is_resolving = 1;
MG_VERBOSE(("%lu resolving %.*s @ %s, txnid %hu", c->id, (int) name->len,
name->ptr, dnsc->url, d->txnid));
if (!mg_dns_send(dnsc->c, name, d->txnid, ipv6)) {
mg_error(dnsc->c, "DNS send");
}
}
}
void mg_resolve(struct mg_connection *c, const char *url) {
struct mg_str host = mg_url_host(url);
c->rem.port = mg_htons(mg_url_port(url));
if (mg_aton(host, &c->rem)) {
// host is an IP address, do not fire name resolution
mg_connect_resolved(c);
} else {
// host is not an IP, send DNS resolution request
struct mg_dns *dns = c->mgr->use_dns6 ? &c->mgr->dns6 : &c->mgr->dns4;
mg_sendnsreq(c, &host, c->mgr->dnstimeout, dns, c->mgr->use_dns6);
}
}
#ifdef MG_ENABLE_LINES
#line 1 "src/event.c"
#endif
void mg_call(struct mg_connection *c, int ev, void *ev_data) {
#if MG_ENABLE_PROFILE
const char *names[] = {
"EV_ERROR", "EV_OPEN", "EV_POLL", "EV_RESOLVE",
"EV_CONNECT", "EV_ACCEPT", "EV_TLS_HS", "EV_READ",
"EV_WRITE", "EV_CLOSE", "EV_HTTP_MSG", "EV_HTTP_CHUNK",
"EV_WS_OPEN", "EV_WS_MSG", "EV_WS_CTL", "EV_MQTT_CMD",
"EV_MQTT_MSG", "EV_MQTT_OPEN", "EV_SNTP_TIME", "EV_USER"};
if (ev != MG_EV_POLL && ev < (int) (sizeof(names) / sizeof(names[0]))) {
MG_PROF_ADD(c, names[ev]);
}
#endif
// Run user-defined handler first, in order to give it an ability
// to intercept processing (e.g. clean input buffer) before the
// protocol handler kicks in
if (c->fn != NULL) c->fn(c, ev, ev_data);
if (c->pfn != NULL) c->pfn(c, ev, ev_data);
}
void mg_error(struct mg_connection *c, const char *fmt, ...) {
char buf[64];
va_list ap;
va_start(ap, fmt);
mg_vsnprintf(buf, sizeof(buf), fmt, &ap);
va_end(ap);
MG_ERROR(("%lu %ld %s", c->id, c->fd, buf));
c->is_closing = 1; // Set is_closing before sending MG_EV_CALL
mg_call(c, MG_EV_ERROR, buf); // Let user handler override it
}
#ifdef MG_ENABLE_LINES
#line 1 "src/fmt.c"
#endif
static bool is_digit(int c) {
return c >= '0' && c <= '9';
}
static int addexp(char *buf, int e, int sign) {
int n = 0;
buf[n++] = 'e';
buf[n++] = (char) sign;
if (e > 400) return 0;
if (e < 10) buf[n++] = '0';
if (e >= 100) buf[n++] = (char) (e / 100 + '0'), e -= 100 * (e / 100);
if (e >= 10) buf[n++] = (char) (e / 10 + '0'), e -= 10 * (e / 10);
buf[n++] = (char) (e + '0');
return n;
}
static int xisinf(double x) {
union {
double f;
uint64_t u;
} ieee754 = {x};
return ((unsigned) (ieee754.u >> 32) & 0x7fffffff) == 0x7ff00000 &&
((unsigned) ieee754.u == 0);
}
static int xisnan(double x) {
union {
double f;
uint64_t u;
} ieee754 = {x};
return ((unsigned) (ieee754.u >> 32) & 0x7fffffff) +
((unsigned) ieee754.u != 0) >
0x7ff00000;
}
static size_t mg_dtoa(char *dst, size_t dstlen, double d, int width, bool tz) {
char buf[40];
int i, s = 0, n = 0, e = 0;
double t, mul, saved;
if (d == 0.0) return mg_snprintf(dst, dstlen, "%s", "0");
if (xisinf(d)) return mg_snprintf(dst, dstlen, "%s", d > 0 ? "inf" : "-inf");
if (xisnan(d)) return mg_snprintf(dst, dstlen, "%s", "nan");
if (d < 0.0) d = -d, buf[s++] = '-';
// Round
saved = d;
mul = 1.0;
while (d >= 10.0 && d / mul >= 10.0) mul *= 10.0;
while (d <= 1.0 && d / mul <= 1.0) mul /= 10.0;
for (i = 0, t = mul * 5; i < width; i++) t /= 10.0;
d += t;
// Calculate exponent, and 'mul' for scientific representation
mul = 1.0;
while (d >= 10.0 && d / mul >= 10.0) mul *= 10.0, e++;
while (d < 1.0 && d / mul < 1.0) mul /= 10.0, e--;
// printf(" --> %g %d %g %g\n", saved, e, t, mul);
if (e >= width && width > 1) {
n = (int) mg_dtoa(buf, sizeof(buf), saved / mul, width, tz);
// printf(" --> %.*g %d [%.*s]\n", 10, d / t, e, n, buf);
n += addexp(buf + s + n, e, '+');
return mg_snprintf(dst, dstlen, "%.*s", n, buf);
} else if (e <= -width && width > 1) {
n = (int) mg_dtoa(buf, sizeof(buf), saved / mul, width, tz);
// printf(" --> %.*g %d [%.*s]\n", 10, d / mul, e, n, buf);
n += addexp(buf + s + n, -e, '-');
return mg_snprintf(dst, dstlen, "%.*s", n, buf);
} else {
for (i = 0, t = mul; t >= 1.0 && s + n < (int) sizeof(buf); i++) {
int ch = (int) (d / t);
if (n > 0 || ch > 0) buf[s + n++] = (char) (ch + '0');
d -= ch * t;
t /= 10.0;
}
// printf(" --> [%g] -> %g %g (%d) [%.*s]\n", saved, d, t, n, s + n, buf);
if (n == 0) buf[s++] = '0';
while (t >= 1.0 && n + s < (int) sizeof(buf)) buf[n++] = '0', t /= 10.0;
if (s + n < (int) sizeof(buf)) buf[n + s++] = '.';
// printf(" 1--> [%g] -> [%.*s]\n", saved, s + n, buf);
for (i = 0, t = 0.1; s + n < (int) sizeof(buf) && n < width; i++) {
int ch = (int) (d / t);
buf[s + n++] = (char) (ch + '0');
d -= ch * t;
t /= 10.0;
}
}
while (tz && n > 0 && buf[s + n - 1] == '0') n--; // Trim trailing zeroes
if (n > 0 && buf[s + n - 1] == '.') n--; // Trim trailing dot
n += s;
if (n >= (int) sizeof(buf)) n = (int) sizeof(buf) - 1;
buf[n] = '\0';
return mg_snprintf(dst, dstlen, "%s", buf);
}
static size_t mg_lld(char *buf, int64_t val, bool is_signed, bool is_hex) {
const char *letters = "0123456789abcdef";
uint64_t v = (uint64_t) val;
size_t s = 0, n, i;
if (is_signed && val < 0) buf[s++] = '-', v = (uint64_t) (-val);
// This loop prints a number in reverse order. I guess this is because we
// write numbers from right to left: least significant digit comes last.
// Maybe because we use Arabic numbers, and Arabs write RTL?
if (is_hex) {
for (n = 0; v; v >>= 4) buf[s + n++] = letters[v & 15];
} else {
for (n = 0; v; v /= 10) buf[s + n++] = letters[v % 10];
}
// Reverse a string
for (i = 0; i < n / 2; i++) {
char t = buf[s + i];
buf[s + i] = buf[s + n - i - 1], buf[s + n - i - 1] = t;
}
if (val == 0) buf[n++] = '0'; // Handle special case
return n + s;
}
static size_t scpy(void (*out)(char, void *), void *ptr, char *buf,
size_t len) {
size_t i = 0;
while (i < len && buf[i] != '\0') out(buf[i++], ptr);
return i;
}
size_t mg_xprintf(void (*out)(char, void *), void *ptr, const char *fmt, ...) {
size_t len = 0;
va_list ap;
va_start(ap, fmt);
len = mg_vxprintf(out, ptr, fmt, &ap);
va_end(ap);
return len;
}
size_t mg_vxprintf(void (*out)(char, void *), void *param, const char *fmt,
va_list *ap) {
size_t i = 0, n = 0;
while (fmt[i] != '\0') {
if (fmt[i] == '%') {
size_t j, k, x = 0, is_long = 0, w = 0 /* width */, pr = ~0U /* prec */;
char pad = ' ', minus = 0, c = fmt[++i];
if (c == '#') x++, c = fmt[++i];
if (c == '-') minus++, c = fmt[++i];
if (c == '0') pad = '0', c = fmt[++i];
while (is_digit(c)) w *= 10, w += (size_t) (c - '0'), c = fmt[++i];
if (c == '.') {
c = fmt[++i];
if (c == '*') {
pr = (size_t) va_arg(*ap, int);
c = fmt[++i];
} else {
pr = 0;
while (is_digit(c)) pr *= 10, pr += (size_t) (c - '0'), c = fmt[++i];
}
}
while (c == 'h') c = fmt[++i]; // Treat h and hh as int
if (c == 'l') {
is_long++, c = fmt[++i];
if (c == 'l') is_long++, c = fmt[++i];
}
if (c == 'p') x = 1, is_long = 1;
if (c == 'd' || c == 'u' || c == 'x' || c == 'X' || c == 'p' ||
c == 'g' || c == 'f') {
bool s = (c == 'd'), h = (c == 'x' || c == 'X' || c == 'p');
char tmp[40];
size_t xl = x ? 2 : 0;
if (c == 'g' || c == 'f') {
double v = va_arg(*ap, double);
if (pr == ~0U) pr = 6;
k = mg_dtoa(tmp, sizeof(tmp), v, (int) pr, c == 'g');
} else if (is_long == 2) {
int64_t v = va_arg(*ap, int64_t);
k = mg_lld(tmp, v, s, h);
} else if (is_long == 1) {
long v = va_arg(*ap, long);
k = mg_lld(tmp, s ? (int64_t) v : (int64_t) (unsigned long) v, s, h);
} else {
int v = va_arg(*ap, int);
k = mg_lld(tmp, s ? (int64_t) v : (int64_t) (unsigned) v, s, h);
}
for (j = 0; j < xl && w > 0; j++) w--;
for (j = 0; pad == ' ' && !minus && k < w && j + k < w; j++)
n += scpy(out, param, &pad, 1);
n += scpy(out, param, (char *) "0x", xl);
for (j = 0; pad == '0' && k < w && j + k < w; j++)
n += scpy(out, param, &pad, 1);
n += scpy(out, param, tmp, k);
for (j = 0; pad == ' ' && minus && k < w && j + k < w; j++)
n += scpy(out, param, &pad, 1);
} else if (c == 'm' || c == 'M') {
mg_pm_t f = va_arg(*ap, mg_pm_t);
if (c == 'm') out('"', param);
n += f(out, param, ap);
if (c == 'm') n += 2, out('"', param);
} else if (c == 'c') {
int ch = va_arg(*ap, int);
out((char) ch, param);
n++;
} else if (c == 's') {
char *p = va_arg(*ap, char *);
if (pr == ~0U) pr = p == NULL ? 0 : strlen(p);
for (j = 0; !minus && pr < w && j + pr < w; j++)
n += scpy(out, param, &pad, 1);
n += scpy(out, param, p, pr);
for (j = 0; minus && pr < w && j + pr < w; j++)
n += scpy(out, param, &pad, 1);
} else if (c == '%') {
out('%', param);
n++;
} else {
out('%', param);
out(c, param);
n += 2;
}
i++;
} else {
out(fmt[i], param), n++, i++;
}
}
return n;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/fs.c"
#endif
struct mg_fd *mg_fs_open(struct mg_fs *fs, const char *path, int flags) {
struct mg_fd *fd = (struct mg_fd *) calloc(1, sizeof(*fd));
if (fd != NULL) {
fd->fd = fs->op(path, flags);
fd->fs = fs;
if (fd->fd == NULL) {
free(fd);
fd = NULL;
}
}
return fd;
}
void mg_fs_close(struct mg_fd *fd) {
if (fd != NULL) {
fd->fs->cl(fd->fd);
free(fd);
}
}
char *mg_file_read(struct mg_fs *fs, const char *path, size_t *sizep) {
struct mg_fd *fd;
char *data = NULL;
size_t size = 0;
fs->st(path, &size, NULL);
if ((fd = mg_fs_open(fs, path, MG_FS_READ)) != NULL) {
data = (char *) calloc(1, size + 1);
if (data != NULL) {
if (fs->rd(fd->fd, data, size) != size) {
free(data);
data = NULL;
} else {
data[size] = '\0';
if (sizep != NULL) *sizep = size;
}
}
mg_fs_close(fd);
}
return data;
}
bool mg_file_write(struct mg_fs *fs, const char *path, const void *buf,
size_t len) {
bool result = false;
struct mg_fd *fd;
char tmp[MG_PATH_MAX];
mg_snprintf(tmp, sizeof(tmp), "%s..%d", path, rand());
if ((fd = mg_fs_open(fs, tmp, MG_FS_WRITE)) != NULL) {
result = fs->wr(fd->fd, buf, len) == len;
mg_fs_close(fd);
if (result) {
fs->rm(path);
fs->mv(tmp, path);
} else {
fs->rm(tmp);
}
}
return result;
}
bool mg_file_printf(struct mg_fs *fs, const char *path, const char *fmt, ...) {
va_list ap;
char *data;
bool result = false;
va_start(ap, fmt);
data = mg_vmprintf(fmt, &ap);
va_end(ap);
result = mg_file_write(fs, path, data, strlen(data));
free(data);
return result;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/fs_fat.c"
#endif
#if MG_ENABLE_FATFS
#include <ff.h>
static int mg_days_from_epoch(int y, int m, int d) {
y -= m <= 2;
int era = y / 400;
int yoe = y - era * 400;
int doy = (153 * (m + (m > 2 ? -3 : 9)) + 2) / 5 + d - 1;
int doe = yoe * 365 + yoe / 4 - yoe / 100 + doy;
return era * 146097 + doe - 719468;
}
static time_t mg_timegm(const struct tm *t) {
int year = t->tm_year + 1900;
int month = t->tm_mon; // 0-11
if (month > 11) {
year += month / 12;
month %= 12;
} else if (month < 0) {
int years_diff = (11 - month) / 12;
year -= years_diff;
month += 12 * years_diff;
}
int x = mg_days_from_epoch(year, month + 1, t->tm_mday);
return 60 * (60 * (24L * x + t->tm_hour) + t->tm_min) + t->tm_sec;
}
static time_t ff_time_to_epoch(uint16_t fdate, uint16_t ftime) {
struct tm tm;
memset(&tm, 0, sizeof(struct tm));
tm.tm_sec = (ftime << 1) & 0x3e;
tm.tm_min = ((ftime >> 5) & 0x3f);
tm.tm_hour = ((ftime >> 11) & 0x1f);
tm.tm_mday = (fdate & 0x1f);
tm.tm_mon = ((fdate >> 5) & 0x0f) - 1;
tm.tm_year = ((fdate >> 9) & 0x7f) + 80;
return mg_timegm(&tm);
}
static int ff_stat(const char *path, size_t *size, time_t *mtime) {
FILINFO fi;
if (path[0] == '\0') {
if (size) *size = 0;
if (mtime) *mtime = 0;
return MG_FS_DIR;
} else if (f_stat(path, &fi) == 0) {
if (size) *size = (size_t) fi.fsize;
if (mtime) *mtime = ff_time_to_epoch(fi.fdate, fi.ftime);
return MG_FS_READ | MG_FS_WRITE | ((fi.fattrib & AM_DIR) ? MG_FS_DIR : 0);
} else {
return 0;
}
}
static void ff_list(const char *dir, void (*fn)(const char *, void *),
void *userdata) {
DIR d;
FILINFO fi;
if (f_opendir(&d, dir) == FR_OK) {
while (f_readdir(&d, &fi) == FR_OK && fi.fname[0] != '\0') {
if (!strcmp(fi.fname, ".") || !strcmp(fi.fname, "..")) continue;
fn(fi.fname, userdata);
}
f_closedir(&d);
}
}
static void *ff_open(const char *path, int flags) {
FIL f;
unsigned char mode = FA_READ;
if (flags & MG_FS_WRITE) mode |= FA_WRITE | FA_OPEN_ALWAYS | FA_OPEN_APPEND;
if (f_open(&f, path, mode) == 0) {
FIL *fp;
if ((fp = calloc(1, sizeof(*fp))) != NULL) {
memcpy(fp, &f, sizeof(*fp));
return fp;
}
}
return NULL;
}
static void ff_close(void *fp) {
if (fp != NULL) {
f_close((FIL *) fp);
free(fp);
}
}
static size_t ff_read(void *fp, void *buf, size_t len) {
UINT n = 0, misalign = ((size_t) buf) & 3;
if (misalign) {
char aligned[4];
f_read((FIL *) fp, aligned, len > misalign ? misalign : len, &n);
memcpy(buf, aligned, n);
} else {
f_read((FIL *) fp, buf, len, &n);
}
return n;
}
static size_t ff_write(void *fp, const void *buf, size_t len) {
UINT n = 0;
return f_write((FIL *) fp, (char *) buf, len, &n) == FR_OK ? n : 0;
}
static size_t ff_seek(void *fp, size_t offset) {
f_lseek((FIL *) fp, offset);
return offset;
}
static bool ff_rename(const char *from, const char *to) {
return f_rename(from, to) == FR_OK;
}
static bool ff_remove(const char *path) {
return f_unlink(path) == FR_OK;
}
static bool ff_mkdir(const char *path) {
return f_mkdir(path) == FR_OK;
}
struct mg_fs mg_fs_fat = {ff_stat, ff_list, ff_open, ff_close, ff_read,
ff_write, ff_seek, ff_rename, ff_remove, ff_mkdir};
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/fs_packed.c"
#endif
struct packed_file {
const char *data;
size_t size;
size_t pos;
};
#if MG_ENABLE_PACKED_FS
#else
const char *mg_unpack(const char *path, size_t *size, time_t *mtime) {
*size = 0, *mtime = 0;
(void) path;
return NULL;
}
const char *mg_unlist(size_t no) {
(void) no;
return NULL;
}
#endif
struct mg_str mg_unpacked(const char *path) {
size_t len = 0;
const char *buf = mg_unpack(path, &len, NULL);
return mg_str_n(buf, len);
}
static int is_dir_prefix(const char *prefix, size_t n, const char *path) {
// MG_INFO(("[%.*s] [%s] %c", (int) n, prefix, path, path[n]));
return n < strlen(path) && strncmp(prefix, path, n) == 0 &&
(n == 0 || path[n] == '/' || path[n - 1] == '/');
}
static int packed_stat(const char *path, size_t *size, time_t *mtime) {
const char *p;
size_t i, n = strlen(path);
if (mg_unpack(path, size, mtime)) return MG_FS_READ; // Regular file
// Scan all files. If `path` is a dir prefix for any of them, it's a dir
for (i = 0; (p = mg_unlist(i)) != NULL; i++) {
if (is_dir_prefix(path, n, p)) return MG_FS_DIR;
}
return 0;
}
static void packed_list(const char *dir, void (*fn)(const char *, void *),
void *userdata) {
char buf[MG_PATH_MAX], tmp[sizeof(buf)];
const char *path, *begin, *end;
size_t i, n = strlen(dir);
tmp[0] = '\0'; // Previously listed entry
for (i = 0; (path = mg_unlist(i)) != NULL; i++) {
if (!is_dir_prefix(dir, n, path)) continue;
begin = &path[n + 1];
end = strchr(begin, '/');
if (end == NULL) end = begin + strlen(begin);
mg_snprintf(buf, sizeof(buf), "%.*s", (int) (end - begin), begin);
buf[sizeof(buf) - 1] = '\0';
// If this entry has been already listed, skip
// NOTE: we're assuming that file list is sorted alphabetically
if (strcmp(buf, tmp) == 0) continue;
fn(buf, userdata); // Not yet listed, call user function
strcpy(tmp, buf); // And save this entry as listed
}
}
static void *packed_open(const char *path, int flags) {
size_t size = 0;
const char *data = mg_unpack(path, &size, NULL);
struct packed_file *fp = NULL;
if (data == NULL) return NULL;
if (flags & MG_FS_WRITE) return NULL;
if ((fp = (struct packed_file *) calloc(1, sizeof(*fp))) != NULL) {
fp->size = size;
fp->data = data;
}
return (void *) fp;
}
static void packed_close(void *fp) {
if (fp != NULL) free(fp);
}
static size_t packed_read(void *fd, void *buf, size_t len) {
struct packed_file *fp = (struct packed_file *) fd;
if (fp->pos + len > fp->size) len = fp->size - fp->pos;
memcpy(buf, &fp->data[fp->pos], len);
fp->pos += len;
return len;
}
static size_t packed_write(void *fd, const void *buf, size_t len) {
(void) fd, (void) buf, (void) len;
return 0;
}
static size_t packed_seek(void *fd, size_t offset) {
struct packed_file *fp = (struct packed_file *) fd;
fp->pos = offset;
if (fp->pos > fp->size) fp->pos = fp->size;
return fp->pos;
}
static bool packed_rename(const char *from, const char *to) {
(void) from, (void) to;
return false;
}
static bool packed_remove(const char *path) {
(void) path;
return false;
}
static bool packed_mkdir(const char *path) {
(void) path;
return false;
}
struct mg_fs mg_fs_packed = {
packed_stat, packed_list, packed_open, packed_close, packed_read,
packed_write, packed_seek, packed_rename, packed_remove, packed_mkdir};
#ifdef MG_ENABLE_LINES
#line 1 "src/fs_posix.c"
#endif
#if MG_ENABLE_POSIX_FS
#ifndef MG_STAT_STRUCT
#define MG_STAT_STRUCT stat
#endif
#ifndef MG_STAT_FUNC
#define MG_STAT_FUNC stat
#endif
static int p_stat(const char *path, size_t *size, time_t *mtime) {
#if !defined(S_ISDIR)
MG_ERROR(("stat() API is not supported. %p %p %p", path, size, mtime));
return 0;
#else
#if MG_ARCH == MG_ARCH_WIN32
struct _stati64 st;
wchar_t tmp[MG_PATH_MAX];
MultiByteToWideChar(CP_UTF8, 0, path, -1, tmp, sizeof(tmp) / sizeof(tmp[0]));
if (_wstati64(tmp, &st) != 0) return 0;
// If path is a symlink, windows reports 0 in st.st_size.
// Get a real file size by opening it and jumping to the end
if (st.st_size == 0 && (st.st_mode & _S_IFREG)) {
FILE *fp = _wfopen(tmp, L"rb");
if (fp != NULL) {
fseek(fp, 0, SEEK_END);
if (ftell(fp) > 0) st.st_size = ftell(fp); // Use _ftelli64 on win10+
fclose(fp);
}
}
#else
struct MG_STAT_STRUCT st;
if (MG_STAT_FUNC(path, &st) != 0) return 0;
#endif
if (size) *size = (size_t) st.st_size;
if (mtime) *mtime = st.st_mtime;
return MG_FS_READ | MG_FS_WRITE | (S_ISDIR(st.st_mode) ? MG_FS_DIR : 0);
#endif
}
#if MG_ARCH == MG_ARCH_WIN32
struct dirent {
char d_name[MAX_PATH];
};
typedef struct win32_dir {
HANDLE handle;
WIN32_FIND_DATAW info;
struct dirent result;
} DIR;
#if 0
int gettimeofday(struct timeval *tv, void *tz) {
FILETIME ft;
unsigned __int64 tmpres = 0;
if (tv != NULL) {
GetSystemTimeAsFileTime(&ft);
tmpres |= ft.dwHighDateTime;
tmpres <<= 32;
tmpres |= ft.dwLowDateTime;
tmpres /= 10; // convert into microseconds
tmpres -= (int64_t) 11644473600000000;
tv->tv_sec = (long) (tmpres / 1000000UL);
tv->tv_usec = (long) (tmpres % 1000000UL);
}
(void) tz;
return 0;
}
#endif
static int to_wchar(const char *path, wchar_t *wbuf, size_t wbuf_len) {
int ret;
char buf[MAX_PATH * 2], buf2[MAX_PATH * 2], *p;
strncpy(buf, path, sizeof(buf));
buf[sizeof(buf) - 1] = '\0';
// Trim trailing slashes. Leave backslash for paths like "X:\"
p = buf + strlen(buf) - 1;
while (p > buf && p[-1] != ':' && (p[0] == '\\' || p[0] == '/')) *p-- = '\0';
memset(wbuf, 0, wbuf_len * sizeof(wchar_t));
ret = MultiByteToWideChar(CP_UTF8, 0, buf, -1, wbuf, (int) wbuf_len);
// Convert back to Unicode. If doubly-converted string does not match the
// original, something is fishy, reject.
WideCharToMultiByte(CP_UTF8, 0, wbuf, (int) wbuf_len, buf2, sizeof(buf2),
NULL, NULL);
if (strcmp(buf, buf2) != 0) {
wbuf[0] = L'\0';
ret = 0;
}
return ret;
}
DIR *opendir(const char *name) {
DIR *d = NULL;
wchar_t wpath[MAX_PATH];
DWORD attrs;
if (name == NULL) {
SetLastError(ERROR_BAD_ARGUMENTS);
} else if ((d = (DIR *) calloc(1, sizeof(*d))) == NULL) {
SetLastError(ERROR_NOT_ENOUGH_MEMORY);
} else {
to_wchar(name, wpath, sizeof(wpath) / sizeof(wpath[0]));
attrs = GetFileAttributesW(wpath);
if (attrs != 0Xffffffff && (attrs & FILE_ATTRIBUTE_DIRECTORY)) {
(void) wcscat(wpath, L"\\*");
d->handle = FindFirstFileW(wpath, &d->info);
d->result.d_name[0] = '\0';
} else {
free(d);
d = NULL;
}
}
return d;
}
int closedir(DIR *d) {
int result = 0;
if (d != NULL) {
if (d->handle != INVALID_HANDLE_VALUE)
result = FindClose(d->handle) ? 0 : -1;
free(d);
} else {
result = -1;
SetLastError(ERROR_BAD_ARGUMENTS);
}
return result;
}
struct dirent *readdir(DIR *d) {
struct dirent *result = NULL;
if (d != NULL) {
memset(&d->result, 0, sizeof(d->result));
if (d->handle != INVALID_HANDLE_VALUE) {
result = &d->result;
WideCharToMultiByte(CP_UTF8, 0, d->info.cFileName, -1, result->d_name,
sizeof(result->d_name), NULL, NULL);
if (!FindNextFileW(d->handle, &d->info)) {
FindClose(d->handle);
d->handle = INVALID_HANDLE_VALUE;
}
} else {
SetLastError(ERROR_FILE_NOT_FOUND);
}
} else {
SetLastError(ERROR_BAD_ARGUMENTS);
}
return result;
}
#endif
static void p_list(const char *dir, void (*fn)(const char *, void *),
void *userdata) {
#if MG_ENABLE_DIRLIST
struct dirent *dp;
DIR *dirp;
if ((dirp = (opendir(dir))) == NULL) return;
while ((dp = readdir(dirp)) != NULL) {
if (!strcmp(dp->d_name, ".") || !strcmp(dp->d_name, "..")) continue;
fn(dp->d_name, userdata);
}
closedir(dirp);
#else
(void) dir, (void) fn, (void) userdata;
#endif
}
static void *p_open(const char *path, int flags) {
#if MG_ARCH == MG_ARCH_WIN32
const char *mode = flags == MG_FS_READ ? "rb" : "a+b";
wchar_t b1[MG_PATH_MAX], b2[10];
MultiByteToWideChar(CP_UTF8, 0, path, -1, b1, sizeof(b1) / sizeof(b1[0]));
MultiByteToWideChar(CP_UTF8, 0, mode, -1, b2, sizeof(b2) / sizeof(b2[0]));
return (void *) _wfopen(b1, b2);
#else
const char *mode = flags == MG_FS_READ ? "rbe" : "a+be"; // e for CLOEXEC
return (void *) fopen(path, mode);
#endif
}
static void p_close(void *fp) {
fclose((FILE *) fp);
}
static size_t p_read(void *fp, void *buf, size_t len) {
return fread(buf, 1, len, (FILE *) fp);
}
static size_t p_write(void *fp, const void *buf, size_t len) {
return fwrite(buf, 1, len, (FILE *) fp);
}
static size_t p_seek(void *fp, size_t offset) {
#if (defined(_FILE_OFFSET_BITS) && _FILE_OFFSET_BITS == 64) || \
(defined(_POSIX_C_SOURCE) && _POSIX_C_SOURCE >= 200112L) || \
(defined(_XOPEN_SOURCE) && _XOPEN_SOURCE >= 600)
if (fseeko((FILE *) fp, (off_t) offset, SEEK_SET) != 0) (void) 0;
#else
if (fseek((FILE *) fp, (long) offset, SEEK_SET) != 0) (void) 0;
#endif
return (size_t) ftell((FILE *) fp);
}
static bool p_rename(const char *from, const char *to) {
return rename(from, to) == 0;
}
static bool p_remove(const char *path) {
return remove(path) == 0;
}
static bool p_mkdir(const char *path) {
return mkdir(path, 0775) == 0;
}
#else
static int p_stat(const char *path, size_t *size, time_t *mtime) {
(void) path, (void) size, (void) mtime;
return 0;
}
static void p_list(const char *path, void (*fn)(const char *, void *),
void *userdata) {
(void) path, (void) fn, (void) userdata;
}
static void *p_open(const char *path, int flags) {
(void) path, (void) flags;
return NULL;
}
static void p_close(void *fp) {
(void) fp;
}
static size_t p_read(void *fd, void *buf, size_t len) {
(void) fd, (void) buf, (void) len;
return 0;
}
static size_t p_write(void *fd, const void *buf, size_t len) {
(void) fd, (void) buf, (void) len;
return 0;
}
static size_t p_seek(void *fd, size_t offset) {
(void) fd, (void) offset;
return (size_t) ~0;
}
static bool p_rename(const char *from, const char *to) {
(void) from, (void) to;
return false;
}
static bool p_remove(const char *path) {
(void) path;
return false;
}
static bool p_mkdir(const char *path) {
(void) path;
return false;
}
#endif
struct mg_fs mg_fs_posix = {p_stat, p_list, p_open, p_close, p_read,
p_write, p_seek, p_rename, p_remove, p_mkdir};
#ifdef MG_ENABLE_LINES
#line 1 "src/http.c"
#endif
bool mg_to_size_t(struct mg_str str, size_t *val);
bool mg_to_size_t(struct mg_str str, size_t *val) {
size_t i = 0, max = (size_t) -1, max2 = max / 10, result = 0, ndigits = 0;
while (i < str.len && (str.ptr[i] == ' ' || str.ptr[i] == '\t')) i++;
if (i < str.len && str.ptr[i] == '-') return false;
while (i < str.len && str.ptr[i] >= '0' && str.ptr[i] <= '9') {
size_t digit = (size_t) (str.ptr[i] - '0');
if (result > max2) return false; // Overflow
result *= 10;
if (result > max - digit) return false; // Overflow
result += digit;
i++, ndigits++;
}
while (i < str.len && (str.ptr[i] == ' ' || str.ptr[i] == '\t')) i++;
if (ndigits == 0) return false; // #2322: Content-Length = 1 * DIGIT
if (i != str.len) return false; // Ditto
*val = (size_t) result;
return true;
}
// Chunk deletion marker is the MSB in the "processed" counter
#define MG_DMARK ((size_t) 1 << (sizeof(size_t) * 8 - 1))
// Multipart POST example:
// --xyz
// Content-Disposition: form-data; name="val"
//
// abcdef
// --xyz
// Content-Disposition: form-data; name="foo"; filename="a.txt"
// Content-Type: text/plain
//
// hello world
//
// --xyz--
size_t mg_http_next_multipart(struct mg_str body, size_t ofs,
struct mg_http_part *part) {
struct mg_str cd = mg_str_n("Content-Disposition", 19);
const char *s = body.ptr;
size_t b = ofs, h1, h2, b1, b2, max = body.len;
// Init part params
if (part != NULL) part->name = part->filename = part->body = mg_str_n(0, 0);
// Skip boundary
while (b + 2 < max && s[b] != '\r' && s[b + 1] != '\n') b++;
if (b <= ofs || b + 2 >= max) return 0;
// MG_INFO(("B: %zu %zu [%.*s]", ofs, b - ofs, (int) (b - ofs), s));
// Skip headers
h1 = h2 = b + 2;
for (;;) {
while (h2 + 2 < max && s[h2] != '\r' && s[h2 + 1] != '\n') h2++;
if (h2 == h1) break;
if (h2 + 2 >= max) return 0;
// MG_INFO(("Header: [%.*s]", (int) (h2 - h1), &s[h1]));
if (part != NULL && h1 + cd.len + 2 < h2 && s[h1 + cd.len] == ':' &&
mg_ncasecmp(&s[h1], cd.ptr, cd.len) == 0) {
struct mg_str v = mg_str_n(&s[h1 + cd.len + 2], h2 - (h1 + cd.len + 2));
part->name = mg_http_get_header_var(v, mg_str_n("name", 4));
part->filename = mg_http_get_header_var(v, mg_str_n("filename", 8));
}
h1 = h2 = h2 + 2;
}
b1 = b2 = h2 + 2;
while (b2 + 2 + (b - ofs) + 2 < max && !(s[b2] == '\r' && s[b2 + 1] == '\n' &&
memcmp(&s[b2 + 2], s, b - ofs) == 0))
b2++;
if (b2 + 2 >= max) return 0;
if (part != NULL) part->body = mg_str_n(&s[b1], b2 - b1);
// MG_INFO(("Body: [%.*s]", (int) (b2 - b1), &s[b1]));
return b2 + 2;
}
void mg_http_bauth(struct mg_connection *c, const char *user,
const char *pass) {
struct mg_str u = mg_str(user), p = mg_str(pass);
size_t need = c->send.len + 36 + (u.len + p.len) * 2;
if (c->send.size < need) mg_iobuf_resize(&c->send, need);
if (c->send.size >= need) {
size_t i, n = 0;
char *buf = (char *) &c->send.buf[c->send.len];
memcpy(buf, "Authorization: Basic ", 21); // DON'T use mg_send!
for (i = 0; i < u.len; i++) {
n = mg_base64_update(((unsigned char *) u.ptr)[i], buf + 21, n);
}
if (p.len > 0) {
n = mg_base64_update(':', buf + 21, n);
for (i = 0; i < p.len; i++) {
n = mg_base64_update(((unsigned char *) p.ptr)[i], buf + 21, n);
}
}
n = mg_base64_final(buf + 21, n);
c->send.len += 21 + (size_t) n + 2;
memcpy(&c->send.buf[c->send.len - 2], "\r\n", 2);
} else {
MG_ERROR(("%lu oom %d->%d ", c->id, (int) c->send.size, (int) need));
}
}
struct mg_str mg_http_var(struct mg_str buf, struct mg_str name) {
struct mg_str k, v, result = mg_str_n(NULL, 0);
while (mg_split(&buf, &k, &v, '&')) {
if (name.len == k.len && mg_ncasecmp(name.ptr, k.ptr, k.len) == 0) {
result = v;
break;
}
}
return result;
}
int mg_http_get_var(const struct mg_str *buf, const char *name, char *dst,
size_t dst_len) {
int len;
if (dst == NULL || dst_len == 0) {
len = -2; // Bad destination
} else if (buf->ptr == NULL || name == NULL || buf->len == 0) {
len = -1; // Bad source
dst[0] = '\0';
} else {
struct mg_str v = mg_http_var(*buf, mg_str(name));
if (v.ptr == NULL) {
len = -4; // Name does not exist
} else {
len = mg_url_decode(v.ptr, v.len, dst, dst_len, 1);
if (len < 0) len = -3; // Failed to decode
}
}
return len;
}
static bool isx(int c) {
return (c >= '0' && c <= '9') || (c >= 'a' && c <= 'f') ||
(c >= 'A' && c <= 'F');
}
int mg_url_decode(const char *src, size_t src_len, char *dst, size_t dst_len,
int is_form_url_encoded) {
size_t i, j;
for (i = j = 0; i < src_len && j + 1 < dst_len; i++, j++) {
if (src[i] == '%') {
// Use `i + 2 < src_len`, not `i < src_len - 2`, note small src_len
if (i + 2 < src_len && isx(src[i + 1]) && isx(src[i + 2])) {
mg_unhex(src + i + 1, 2, (uint8_t *) &dst[j]);
i += 2;
} else {
return -1;
}
} else if (is_form_url_encoded && src[i] == '+') {
dst[j] = ' ';
} else {
dst[j] = src[i];
}
}
if (j < dst_len) dst[j] = '\0'; // Null-terminate the destination
return i >= src_len && j < dst_len ? (int) j : -1;
}
static bool isok(uint8_t c) {
return c == '\n' || c == '\r' || c >= ' ';
}
int mg_http_get_request_len(const unsigned char *buf, size_t buf_len) {
size_t i;
for (i = 0; i < buf_len; i++) {
if (!isok(buf[i])) return -1;
if ((i > 0 && buf[i] == '\n' && buf[i - 1] == '\n') ||
(i > 3 && buf[i] == '\n' && buf[i - 1] == '\r' && buf[i - 2] == '\n'))
return (int) i + 1;
}
return 0;
}
struct mg_str *mg_http_get_header(struct mg_http_message *h, const char *name) {
size_t i, n = strlen(name), max = sizeof(h->headers) / sizeof(h->headers[0]);
for (i = 0; i < max && h->headers[i].name.len > 0; i++) {
struct mg_str *k = &h->headers[i].name, *v = &h->headers[i].value;
if (n == k->len && mg_ncasecmp(k->ptr, name, n) == 0) return v;
}
return NULL;
}
// Is it a valid utf-8 continuation byte
static bool vcb(uint8_t c) {
return (c & 0xc0) == 0x80;
}
// Get character length (valid utf-8). Used to parse method, URI, headers
static size_t clen(const char *s, const char *end) {
const unsigned char *u = (unsigned char *) s, c = *u;
long n = (long) (end - s);
if (c > ' ' && c < '~') return 1; // Usual ascii printed char
if ((c & 0xe0) == 0xc0 && n > 1 && vcb(u[1])) return 2; // 2-byte UTF8
if ((c & 0xf0) == 0xe0 && n > 2 && vcb(u[1]) && vcb(u[2])) return 3;
if ((c & 0xf8) == 0xf0 && n > 3 && vcb(u[1]) && vcb(u[2]) && vcb(u[3]))
return 4;
return 0;
}
// Skip until the newline. Return advanced `s`, or NULL on error
static const char *skiptorn(const char *s, const char *end, struct mg_str *v) {
v->ptr = s;
while (s < end && s[0] != '\n' && s[0] != '\r') s++, v->len++; // To newline
if (s >= end || (s[0] == '\r' && s[1] != '\n')) return NULL; // Stray \r
if (s < end && s[0] == '\r') s++; // Skip \r
if (s >= end || *s++ != '\n') return NULL; // Skip \n
return s;
}
static bool mg_http_parse_headers(const char *s, const char *end,
struct mg_http_header *h, size_t max_hdrs) {
size_t i, n;
for (i = 0; i < max_hdrs; i++) {
struct mg_str k = {NULL, 0}, v = {NULL, 0};
if (s >= end) return false;
if (s[0] == '\n' || (s[0] == '\r' && s[1] == '\n')) break;
k.ptr = s;
while (s < end && s[0] != ':' && (n = clen(s, end)) > 0) s += n, k.len += n;
if (k.len == 0) return false; // Empty name
if (s >= end || clen(s, end) == 0) return false; // Invalid UTF-8
if (*s++ != ':') return false; // Invalid, not followed by :
// if (clen(s, end) == 0) return false; // Invalid UTF-8
while (s < end && s[0] == ' ') s++; // Skip spaces
if ((s = skiptorn(s, end, &v)) == NULL) return false;
while (v.len > 0 && v.ptr[v.len - 1] == ' ') v.len--; // Trim spaces
// MG_INFO(("--HH [%.*s] [%.*s]", (int) k.len, k.ptr, (int) v.len, v.ptr));
h[i].name = k, h[i].value = v; // Success. Assign values
}
return true;
}
int mg_http_parse(const char *s, size_t len, struct mg_http_message *hm) {
int is_response, req_len = mg_http_get_request_len((unsigned char *) s, len);
const char *end = s == NULL ? NULL : s + req_len, *qs; // Cannot add to NULL
struct mg_str *cl;
size_t n;
memset(hm, 0, sizeof(*hm));
if (req_len <= 0) return req_len;
hm->message.ptr = hm->head.ptr = s;
hm->body.ptr = end;
hm->head.len = (size_t) req_len;
hm->message.len = hm->body.len = (size_t) -1; // Set body length to infinite
// Parse request line
hm->method.ptr = s;
while (s < end && (n = clen(s, end)) > 0) s += n, hm->method.len += n;
while (s < end && s[0] == ' ') s++; // Skip spaces
hm->uri.ptr = s;
while (s < end && (n = clen(s, end)) > 0) s += n, hm->uri.len += n;
while (s < end && s[0] == ' ') s++; // Skip spaces
if ((s = skiptorn(s, end, &hm->proto)) == NULL) return false;
// If URI contains '?' character, setup query string
if ((qs = (const char *) memchr(hm->uri.ptr, '?', hm->uri.len)) != NULL) {
hm->query.ptr = qs + 1;
hm->query.len = (size_t) (&hm->uri.ptr[hm->uri.len] - (qs + 1));
hm->uri.len = (size_t) (qs - hm->uri.ptr);
}
// Sanity check. Allow protocol/reason to be empty
// Do this check after hm->method.len and hm->uri.len are finalised
if (hm->method.len == 0 || hm->uri.len == 0) return -1;
if (!mg_http_parse_headers(s, end, hm->headers,
sizeof(hm->headers) / sizeof(hm->headers[0])))
return -1; // error when parsing
if ((cl = mg_http_get_header(hm, "Content-Length")) != NULL) {
if (mg_to_size_t(*cl, &hm->body.len) == false) return -1;
hm->message.len = (size_t) req_len + hm->body.len;
}
// mg_http_parse() is used to parse both HTTP requests and HTTP
// responses. If HTTP response does not have Content-Length set, then
// body is read until socket is closed, i.e. body.len is infinite (~0).
//
// For HTTP requests though, according to
// http://tools.ietf.org/html/rfc7231#section-8.1.3,
// only POST and PUT methods have defined body semantics.
// Therefore, if Content-Length is not specified and methods are
// not one of PUT or POST, set body length to 0.
//
// So, if it is HTTP request, and Content-Length is not set,
// and method is not (PUT or POST) then reset body length to zero.
is_response = mg_ncasecmp(hm->method.ptr, "HTTP/", 5) == 0;
if (hm->body.len == (size_t) ~0 && !is_response &&
mg_vcasecmp(&hm->method, "PUT") != 0 &&
mg_vcasecmp(&hm->method, "POST") != 0) {
hm->body.len = 0;
hm->message.len = (size_t) req_len;
}
// The 204 (No content) responses also have 0 body length
if (hm->body.len == (size_t) ~0 && is_response &&
mg_vcasecmp(&hm->uri, "204") == 0) {
hm->body.len = 0;
hm->message.len = (size_t) req_len;
}
if (hm->message.len < (size_t) req_len) return -1; // Overflow protection
return req_len;
}
static void mg_http_vprintf_chunk(struct mg_connection *c, const char *fmt,
va_list *ap) {
size_t len = c->send.len;
mg_send(c, " \r\n", 10);
mg_vxprintf(mg_pfn_iobuf, &c->send, fmt, ap);
if (c->send.len >= len + 10) {
mg_snprintf((char *) c->send.buf + len, 9, "%08lx", c->send.len - len - 10);
c->send.buf[len + 8] = '\r';
if (c->send.len == len + 10) c->is_resp = 0; // Last chunk, reset marker
}
mg_send(c, "\r\n", 2);
}
void mg_http_printf_chunk(struct mg_connection *c, const char *fmt, ...) {
va_list ap;
va_start(ap, fmt);
mg_http_vprintf_chunk(c, fmt, &ap);
va_end(ap);
}
void mg_http_write_chunk(struct mg_connection *c, const char *buf, size_t len) {
mg_printf(c, "%lx\r\n", (unsigned long) len);
mg_send(c, buf, len);
mg_send(c, "\r\n", 2);
if (len == 0) c->is_resp = 0;
}
// clang-format off
static const char *mg_http_status_code_str(int status_code) {
switch (status_code) {
case 100: return "Continue";
case 101: return "Switching Protocols";
case 102: return "Processing";
case 200: return "OK";
case 201: return "Created";
case 202: return "Accepted";
case 203: return "Non-authoritative Information";
case 204: return "No Content";
case 205: return "Reset Content";
case 206: return "Partial Content";
case 207: return "Multi-Status";
case 208: return "Already Reported";
case 226: return "IM Used";
case 300: return "Multiple Choices";
case 301: return "Moved Permanently";
case 302: return "Found";
case 303: return "See Other";
case 304: return "Not Modified";
case 305: return "Use Proxy";
case 307: return "Temporary Redirect";
case 308: return "Permanent Redirect";
case 400: return "Bad Request";
case 401: return "Unauthorized";
case 402: return "Payment Required";
case 403: return "Forbidden";
case 404: return "Not Found";
case 405: return "Method Not Allowed";
case 406: return "Not Acceptable";
case 407: return "Proxy Authentication Required";
case 408: return "Request Timeout";
case 409: return "Conflict";
case 410: return "Gone";
case 411: return "Length Required";
case 412: return "Precondition Failed";
case 413: return "Payload Too Large";
case 414: return "Request-URI Too Long";
case 415: return "Unsupported Media Type";
case 416: return "Requested Range Not Satisfiable";
case 417: return "Expectation Failed";
case 418: return "I'm a teapot";
case 421: return "Misdirected Request";
case 422: return "Unprocessable Entity";
case 423: return "Locked";
case 424: return "Failed Dependency";
case 426: return "Upgrade Required";
case 428: return "Precondition Required";
case 429: return "Too Many Requests";
case 431: return "Request Header Fields Too Large";
case 444: return "Connection Closed Without Response";
case 451: return "Unavailable For Legal Reasons";
case 499: return "Client Closed Request";
case 500: return "Internal Server Error";
case 501: return "Not Implemented";
case 502: return "Bad Gateway";
case 503: return "Service Unavailable";
case 504: return "Gateway Timeout";
case 505: return "HTTP Version Not Supported";
case 506: return "Variant Also Negotiates";
case 507: return "Insufficient Storage";
case 508: return "Loop Detected";
case 510: return "Not Extended";
case 511: return "Network Authentication Required";
case 599: return "Network Connect Timeout Error";
default: return "";
}
}
// clang-format on
void mg_http_reply(struct mg_connection *c, int code, const char *headers,
const char *fmt, ...) {
va_list ap;
size_t len;
mg_printf(c, "HTTP/1.1 %d %s\r\n%sContent-Length: \r\n\r\n", code,
mg_http_status_code_str(code), headers == NULL ? "" : headers);
len = c->send.len;
va_start(ap, fmt);
mg_vxprintf(mg_pfn_iobuf, &c->send, fmt, &ap);
va_end(ap);
if (c->send.len > 16) {
size_t n = mg_snprintf((char *) &c->send.buf[len - 15], 11, "%-10lu",
(unsigned long) (c->send.len - len));
c->send.buf[len - 15 + n] = ' '; // Change ending 0 to space
}
c->is_resp = 0;
}
static void http_cb(struct mg_connection *, int, void *);
static void restore_http_cb(struct mg_connection *c) {
mg_fs_close((struct mg_fd *) c->pfn_data);
c->pfn_data = NULL;
c->pfn = http_cb;
c->is_resp = 0;
}
char *mg_http_etag(char *buf, size_t len, size_t size, time_t mtime);
char *mg_http_etag(char *buf, size_t len, size_t size, time_t mtime) {
mg_snprintf(buf, len, "\"%lld.%lld\"", (int64_t) mtime, (int64_t) size);
return buf;
}
static void static_cb(struct mg_connection *c, int ev, void *ev_data) {
if (ev == MG_EV_WRITE || ev == MG_EV_POLL) {
struct mg_fd *fd = (struct mg_fd *) c->pfn_data;
// Read to send IO buffer directly, avoid extra on-stack buffer
size_t n, max = MG_IO_SIZE, space;
size_t *cl = (size_t *) &c->data[(sizeof(c->data) - sizeof(size_t)) /
sizeof(size_t) * sizeof(size_t)];
if (c->send.size < max) mg_iobuf_resize(&c->send, max);
if (c->send.len >= c->send.size) return; // Rate limit
if ((space = c->send.size - c->send.len) > *cl) space = *cl;
n = fd->fs->rd(fd->fd, c->send.buf + c->send.len, space);
c->send.len += n;
*cl -= n;
if (n == 0) restore_http_cb(c);
} else if (ev == MG_EV_CLOSE) {
restore_http_cb(c);
}
(void) ev_data;
}
// Known mime types. Keep it outside guess_content_type() function, since
// some environments don't like it defined there.
// clang-format off
static struct mg_str s_known_types[] = {
MG_C_STR("html"), MG_C_STR("text/html; charset=utf-8"),
MG_C_STR("htm"), MG_C_STR("text/html; charset=utf-8"),
MG_C_STR("css"), MG_C_STR("text/css; charset=utf-8"),
MG_C_STR("js"), MG_C_STR("text/javascript; charset=utf-8"),
MG_C_STR("gif"), MG_C_STR("image/gif"),
MG_C_STR("png"), MG_C_STR("image/png"),
MG_C_STR("jpg"), MG_C_STR("image/jpeg"),
MG_C_STR("jpeg"), MG_C_STR("image/jpeg"),
MG_C_STR("woff"), MG_C_STR("font/woff"),
MG_C_STR("ttf"), MG_C_STR("font/ttf"),
MG_C_STR("svg"), MG_C_STR("image/svg+xml"),
MG_C_STR("txt"), MG_C_STR("text/plain; charset=utf-8"),
MG_C_STR("avi"), MG_C_STR("video/x-msvideo"),
MG_C_STR("csv"), MG_C_STR("text/csv"),
MG_C_STR("doc"), MG_C_STR("application/msword"),
MG_C_STR("exe"), MG_C_STR("application/octet-stream"),
MG_C_STR("gz"), MG_C_STR("application/gzip"),
MG_C_STR("ico"), MG_C_STR("image/x-icon"),
MG_C_STR("json"), MG_C_STR("application/json"),
MG_C_STR("mov"), MG_C_STR("video/quicktime"),
MG_C_STR("mp3"), MG_C_STR("audio/mpeg"),
MG_C_STR("mp4"), MG_C_STR("video/mp4"),
MG_C_STR("mpeg"), MG_C_STR("video/mpeg"),
MG_C_STR("pdf"), MG_C_STR("application/pdf"),
MG_C_STR("shtml"), MG_C_STR("text/html; charset=utf-8"),
MG_C_STR("tgz"), MG_C_STR("application/tar-gz"),
MG_C_STR("wav"), MG_C_STR("audio/wav"),
MG_C_STR("webp"), MG_C_STR("image/webp"),
MG_C_STR("zip"), MG_C_STR("application/zip"),
MG_C_STR("3gp"), MG_C_STR("video/3gpp"),
{0, 0},
};
// clang-format on
static struct mg_str guess_content_type(struct mg_str path, const char *extra) {
struct mg_str k, v, s = mg_str(extra);
size_t i = 0;
// Shrink path to its extension only
while (i < path.len && path.ptr[path.len - i - 1] != '.') i++;
path.ptr += path.len - i;
path.len = i;
// Process user-provided mime type overrides, if any
while (mg_commalist(&s, &k, &v)) {
if (mg_strcmp(path, k) == 0) return v;
}
// Process built-in mime types
for (i = 0; s_known_types[i].ptr != NULL; i += 2) {
if (mg_strcmp(path, s_known_types[i]) == 0) return s_known_types[i + 1];
}
return mg_str("text/plain; charset=utf-8");
}
static int getrange(struct mg_str *s, size_t *a, size_t *b) {
size_t i, numparsed = 0;
for (i = 0; i + 6 < s->len; i++) {
struct mg_str k, v = mg_str_n(s->ptr + i + 6, s->len - i - 6);
if (memcmp(&s->ptr[i], "bytes=", 6) != 0) continue;
if (mg_split(&v, &k, NULL, '-')) {
if (mg_to_size_t(k, a)) numparsed++;
if (v.len > 0 && mg_to_size_t(v, b)) numparsed++;
} else {
if (mg_to_size_t(v, a)) numparsed++;
}
break;
}
return (int) numparsed;
}
void mg_http_serve_file(struct mg_connection *c, struct mg_http_message *hm,
const char *path,
const struct mg_http_serve_opts *opts) {
char etag[64], tmp[MG_PATH_MAX];
struct mg_fs *fs = opts->fs == NULL ? &mg_fs_posix : opts->fs;
struct mg_fd *fd = NULL;
size_t size = 0;
time_t mtime = 0;
struct mg_str *inm = NULL;
struct mg_str mime = guess_content_type(mg_str(path), opts->mime_types);
bool gzip = false;
if (path != NULL) {
// If a browser sends us "Accept-Encoding: gzip", try to open .gz first
struct mg_str *ae = mg_http_get_header(hm, "Accept-Encoding");
if (ae != NULL && mg_strstr(*ae, mg_str("gzip")) != NULL) {
mg_snprintf(tmp, sizeof(tmp), "%s.gz", path);
fd = mg_fs_open(fs, tmp, MG_FS_READ);
if (fd != NULL) gzip = true, path = tmp;
}
// No luck opening .gz? Open what we've told to open
if (fd == NULL) fd = mg_fs_open(fs, path, MG_FS_READ);
}
// Failed to open, and page404 is configured? Open it, then
if (fd == NULL && opts->page404 != NULL) {
fd = mg_fs_open(fs, opts->page404, MG_FS_READ);
mime = guess_content_type(mg_str(path), opts->mime_types);
path = opts->page404;
}
if (fd == NULL || fs->st(path, &size, &mtime) == 0) {
mg_http_reply(c, 404, opts->extra_headers, "Not found\n");
mg_fs_close(fd);
// NOTE: mg_http_etag() call should go first!
} else if (mg_http_etag(etag, sizeof(etag), size, mtime) != NULL &&
(inm = mg_http_get_header(hm, "If-None-Match")) != NULL &&
mg_vcasecmp(inm, etag) == 0) {
mg_fs_close(fd);
mg_http_reply(c, 304, opts->extra_headers, "");
} else {
int n, status = 200;
char range[100];
size_t r1 = 0, r2 = 0, cl = size;
// Handle Range header
struct mg_str *rh = mg_http_get_header(hm, "Range");
range[0] = '\0';
if (rh != NULL && (n = getrange(rh, &r1, &r2)) > 0) {
// If range is specified like "400-", set second limit to content len
if (n == 1) r2 = cl - 1;
if (r1 > r2 || r2 >= cl) {
status = 416;
cl = 0;
mg_snprintf(range, sizeof(range), "Content-Range: bytes */%lld\r\n",
(int64_t) size);
} else {
status = 206;
cl = r2 - r1 + 1;
mg_snprintf(range, sizeof(range),
"Content-Range: bytes %llu-%llu/%llu\r\n", (uint64_t) r1,
(uint64_t) (r1 + cl - 1), (uint64_t) size);
fs->sk(fd->fd, r1);
}
}
mg_printf(c,
"HTTP/1.1 %d %s\r\n"
"Content-Type: %.*s\r\n"
"Etag: %s\r\n"
"Content-Length: %llu\r\n"
"%s%s%s\r\n",
status, mg_http_status_code_str(status), (int) mime.len, mime.ptr,
etag, (uint64_t) cl, gzip ? "Content-Encoding: gzip\r\n" : "",
range, opts->extra_headers ? opts->extra_headers : "");
if (mg_vcasecmp(&hm->method, "HEAD") == 0) {
c->is_draining = 1;
c->is_resp = 0;
mg_fs_close(fd);
} else {
// Track to-be-sent content length at the end of c->data, aligned
size_t *clp = (size_t *) &c->data[(sizeof(c->data) - sizeof(size_t)) /
sizeof(size_t) * sizeof(size_t)];
c->pfn = static_cb;
c->pfn_data = fd;
*clp = cl;
}
}
}
struct printdirentrydata {
struct mg_connection *c;
struct mg_http_message *hm;
const struct mg_http_serve_opts *opts;
const char *dir;
};
#if MG_ENABLE_DIRLIST
static void printdirentry(const char *name, void *userdata) {
struct printdirentrydata *d = (struct printdirentrydata *) userdata;
struct mg_fs *fs = d->opts->fs == NULL ? &mg_fs_posix : d->opts->fs;
size_t size = 0;
time_t t = 0;
char path[MG_PATH_MAX], sz[40], mod[40];
int flags, n = 0;
// MG_DEBUG(("[%s] [%s]", d->dir, name));
if (mg_snprintf(path, sizeof(path), "%s%c%s", d->dir, '/', name) >
sizeof(path)) {
MG_ERROR(("%s truncated", name));
} else if ((flags = fs->st(path, &size, &t)) == 0) {
MG_ERROR(("%lu stat(%s): %d", d->c->id, path, errno));
} else {
const char *slash = flags & MG_FS_DIR ? "/" : "";
if (flags & MG_FS_DIR) {
mg_snprintf(sz, sizeof(sz), "%s", "[DIR]");
} else {
mg_snprintf(sz, sizeof(sz), "%lld", (uint64_t) size);
}
#if defined(MG_HTTP_DIRLIST_TIME_FMT)
{
char time_str[40];
struct tm *time_info = localtime(&t);
strftime(time_str, sizeof time_str, "%Y/%m/%d %H:%M:%S", time_info);
mg_snprintf(mod, sizeof(mod), "%s", time_str);
}
#else
mg_snprintf(mod, sizeof(mod), "%lu", (unsigned long) t);
#endif
n = (int) mg_url_encode(name, strlen(name), path, sizeof(path));
mg_printf(d->c,
" <tr><td><a href=\"%.*s%s\">%s%s</a></td>"
"<td name=%lu>%s</td><td name=%lld>%s</td></tr>\n",
n, path, slash, name, slash, (unsigned long) t, mod,
flags & MG_FS_DIR ? (int64_t) -1 : (int64_t) size, sz);
}
}
static void listdir(struct mg_connection *c, struct mg_http_message *hm,
const struct mg_http_serve_opts *opts, char *dir) {
const char *sort_js_code =
"<script>function srt(tb, sc, so, d) {"
"var tr = Array.prototype.slice.call(tb.rows, 0),"
"tr = tr.sort(function (a, b) { var c1 = a.cells[sc], c2 = b.cells[sc],"
"n1 = c1.getAttribute('name'), n2 = c2.getAttribute('name'), "
"t1 = a.cells[2].getAttribute('name'), "
"t2 = b.cells[2].getAttribute('name'); "
"return so * (t1 < 0 && t2 >= 0 ? -1 : t2 < 0 && t1 >= 0 ? 1 : "
"n1 ? parseInt(n2) - parseInt(n1) : "
"c1.textContent.trim().localeCompare(c2.textContent.trim())); });";
const char *sort_js_code2 =
"for (var i = 0; i < tr.length; i++) tb.appendChild(tr[i]); "
"if (!d) window.location.hash = ('sc=' + sc + '&so=' + so); "
"};"
"window.onload = function() {"
"var tb = document.getElementById('tb');"
"var m = /sc=([012]).so=(1|-1)/.exec(window.location.hash) || [0, 2, 1];"
"var sc = m[1], so = m[2]; document.onclick = function(ev) { "
"var c = ev.target.rel; if (c) {if (c == sc) so *= -1; srt(tb, c, so); "
"sc = c; ev.preventDefault();}};"
"srt(tb, sc, so, true);"
"}"
"</script>";
struct mg_fs *fs = opts->fs == NULL ? &mg_fs_posix : opts->fs;
struct printdirentrydata d = {c, hm, opts, dir};
char tmp[10], buf[MG_PATH_MAX];
size_t off, n;
int len = mg_url_decode(hm->uri.ptr, hm->uri.len, buf, sizeof(buf), 0);
struct mg_str uri = len > 0 ? mg_str_n(buf, (size_t) len) : hm->uri;
mg_printf(c,
"HTTP/1.1 200 OK\r\n"
"Content-Type: text/html; charset=utf-8\r\n"
"%s"
"Content-Length: \r\n\r\n",
opts->extra_headers == NULL ? "" : opts->extra_headers);
off = c->send.len; // Start of body
mg_printf(c,
"<!DOCTYPE html><html><head><title>Index of %.*s</title>%s%s"
"<style>th,td {text-align: left; padding-right: 1em; "
"font-family: monospace; }</style></head>"
"<body><h1>Index of %.*s</h1><table cellpadding=\"0\"><thead>"
"<tr><th><a href=\"#\" rel=\"0\">Name</a></th><th>"
"<a href=\"#\" rel=\"1\">Modified</a></th>"
"<th><a href=\"#\" rel=\"2\">Size</a></th></tr>"
"<tr><td colspan=\"3\"><hr></td></tr>"
"</thead>"
"<tbody id=\"tb\">\n",
(int) uri.len, uri.ptr, sort_js_code, sort_js_code2, (int) uri.len,
uri.ptr);
mg_printf(c, "%s",
" <tr><td><a href=\"..\">..</a></td>"
"<td name=-1></td><td name=-1>[DIR]</td></tr>\n");
fs->ls(dir, printdirentry, &d);
mg_printf(c,
"</tbody><tfoot><tr><td colspan=\"3\"><hr></td></tr></tfoot>"
"</table><address>Mongoose v.%s</address></body></html>\n",
MG_VERSION);
n = mg_snprintf(tmp, sizeof(tmp), "%lu", (unsigned long) (c->send.len - off));
if (n > sizeof(tmp)) n = 0;
memcpy(c->send.buf + off - 12, tmp, n); // Set content length
c->is_resp = 0; // Mark response end
}
#endif
// Resolve requested file into `path` and return its fs->st() result
static int uri_to_path2(struct mg_connection *c, struct mg_http_message *hm,
struct mg_fs *fs, struct mg_str url, struct mg_str dir,
char *path, size_t path_size) {
int flags, tmp;
// Append URI to the root_dir, and sanitize it
size_t n = mg_snprintf(path, path_size, "%.*s", (int) dir.len, dir.ptr);
if (n + 2 >= path_size) {
mg_http_reply(c, 400, "", "Exceeded path size");
return -1;
}
path[path_size - 1] = '\0';
// Terminate root dir with slash
if (n > 0 && path[n - 1] != '/') path[n++] = '/', path[n] = '\0';
if (url.len < hm->uri.len) {
mg_url_decode(hm->uri.ptr + url.len, hm->uri.len - url.len, path + n,
path_size - n, 0);
}
path[path_size - 1] = '\0'; // Double-check
if (!mg_path_is_sane(path)) {
mg_http_reply(c, 400, "", "Invalid path");
return -1;
}
n = strlen(path);
while (n > 1 && path[n - 1] == '/') path[--n] = 0; // Trim trailing slashes
flags = mg_vcmp(&hm->uri, "/") == 0 ? MG_FS_DIR : fs->st(path, NULL, NULL);
MG_VERBOSE(("%lu %.*s -> %s %d", c->id, (int) hm->uri.len, hm->uri.ptr, path,
flags));
if (flags == 0) {
// Do nothing - let's caller decide
} else if ((flags & MG_FS_DIR) && hm->uri.len > 0 &&
hm->uri.ptr[hm->uri.len - 1] != '/') {
mg_printf(c,
"HTTP/1.1 301 Moved\r\n"
"Location: %.*s/\r\n"
"Content-Length: 0\r\n"
"\r\n",
(int) hm->uri.len, hm->uri.ptr);
c->is_resp = 0;
flags = -1;
} else if (flags & MG_FS_DIR) {
if (((mg_snprintf(path + n, path_size - n, "/" MG_HTTP_INDEX) > 0 &&
(tmp = fs->st(path, NULL, NULL)) != 0) ||
(mg_snprintf(path + n, path_size - n, "/index.shtml") > 0 &&
(tmp = fs->st(path, NULL, NULL)) != 0))) {
flags = tmp;
} else if ((mg_snprintf(path + n, path_size - n, "/" MG_HTTP_INDEX ".gz") >
0 &&
(tmp = fs->st(path, NULL, NULL)) !=
0)) { // check for gzipped index
flags = tmp;
path[n + 1 + strlen(MG_HTTP_INDEX)] =
'\0'; // Remove appended .gz in index file name
} else {
path[n] = '\0'; // Remove appended index file name
}
}
return flags;
}
static int uri_to_path(struct mg_connection *c, struct mg_http_message *hm,
const struct mg_http_serve_opts *opts, char *path,
size_t path_size) {
struct mg_fs *fs = opts->fs == NULL ? &mg_fs_posix : opts->fs;
struct mg_str k, v, s = mg_str(opts->root_dir), u = {0, 0}, p = {0, 0};
while (mg_commalist(&s, &k, &v)) {
if (v.len == 0) v = k, k = mg_str("/"), u = k, p = v;
if (hm->uri.len < k.len) continue;
if (mg_strcmp(k, mg_str_n(hm->uri.ptr, k.len)) != 0) continue;
u = k, p = v;
}
return uri_to_path2(c, hm, fs, u, p, path, path_size);
}
void mg_http_serve_dir(struct mg_connection *c, struct mg_http_message *hm,
const struct mg_http_serve_opts *opts) {
char path[MG_PATH_MAX];
const char *sp = opts->ssi_pattern;
int flags = uri_to_path(c, hm, opts, path, sizeof(path));
if (flags < 0) {
// Do nothing: the response has already been sent by uri_to_path()
} else if (flags & MG_FS_DIR) {
#if MG_ENABLE_DIRLIST
listdir(c, hm, opts, path);
#else
mg_http_reply(c, 403, "", "Forbidden\n");
#endif
} else if (flags && sp != NULL &&
mg_globmatch(sp, strlen(sp), path, strlen(path))) {
mg_http_serve_ssi(c, opts->root_dir, path);
} else {
mg_http_serve_file(c, hm, path, opts);
}
}
static bool mg_is_url_safe(int c) {
return (c >= '0' && c <= '9') || (c >= 'a' && c <= 'z') ||
(c >= 'A' && c <= 'Z') || c == '.' || c == '_' || c == '-' || c == '~';
}
size_t mg_url_encode(const char *s, size_t sl, char *buf, size_t len) {
size_t i, n = 0;
for (i = 0; i < sl; i++) {
int c = *(unsigned char *) &s[i];
if (n + 4 >= len) return 0;
if (mg_is_url_safe(c)) {
buf[n++] = s[i];
} else {
buf[n++] = '%';
mg_hex(&s[i], 1, &buf[n]);
n += 2;
}
}
if (len > 0 && n < len - 1) buf[n] = '\0'; // Null-terminate the destination
if (len > 0) buf[len - 1] = '\0'; // Always.
return n;
}
void mg_http_creds(struct mg_http_message *hm, char *user, size_t userlen,
char *pass, size_t passlen) {
struct mg_str *v = mg_http_get_header(hm, "Authorization");
user[0] = pass[0] = '\0';
if (v != NULL && v->len > 6 && memcmp(v->ptr, "Basic ", 6) == 0) {
char buf[256];
size_t n = mg_base64_decode(v->ptr + 6, v->len - 6, buf, sizeof(buf));
const char *p = (const char *) memchr(buf, ':', n > 0 ? n : 0);
if (p != NULL) {
mg_snprintf(user, userlen, "%.*s", p - buf, buf);
mg_snprintf(pass, passlen, "%.*s", n - (size_t) (p - buf) - 1, p + 1);
}
} else if (v != NULL && v->len > 7 && memcmp(v->ptr, "Bearer ", 7) == 0) {
mg_snprintf(pass, passlen, "%.*s", (int) v->len - 7, v->ptr + 7);
} else if ((v = mg_http_get_header(hm, "Cookie")) != NULL) {
struct mg_str t = mg_http_get_header_var(*v, mg_str_n("access_token", 12));
if (t.len > 0) mg_snprintf(pass, passlen, "%.*s", (int) t.len, t.ptr);
} else {
mg_http_get_var(&hm->query, "access_token", pass, passlen);
}
}
static struct mg_str stripquotes(struct mg_str s) {
return s.len > 1 && s.ptr[0] == '"' && s.ptr[s.len - 1] == '"'
? mg_str_n(s.ptr + 1, s.len - 2)
: s;
}
struct mg_str mg_http_get_header_var(struct mg_str s, struct mg_str v) {
size_t i;
for (i = 0; v.len > 0 && i + v.len + 2 < s.len; i++) {
if (s.ptr[i + v.len] == '=' && memcmp(&s.ptr[i], v.ptr, v.len) == 0) {
const char *p = &s.ptr[i + v.len + 1], *b = p, *x = &s.ptr[s.len];
int q = p < x && *p == '"' ? 1 : 0;
while (p < x &&
(q ? p == b || *p != '"' : *p != ';' && *p != ' ' && *p != ','))
p++;
// MG_INFO(("[%.*s] [%.*s] [%.*s]", (int) s.len, s.ptr, (int) v.len,
// v.ptr, (int) (p - b), b));
return stripquotes(mg_str_n(b, (size_t) (p - b + q)));
}
}
return mg_str_n(NULL, 0);
}
bool mg_http_match_uri(const struct mg_http_message *hm, const char *glob) {
return mg_match(hm->uri, mg_str(glob), NULL);
}
long mg_http_upload(struct mg_connection *c, struct mg_http_message *hm,
struct mg_fs *fs, const char *path, size_t max_size) {
char buf[20] = "0";
long res = 0, offset;
mg_http_get_var(&hm->query, "offset", buf, sizeof(buf));
offset = strtol(buf, NULL, 0);
if (hm->body.len == 0) {
mg_http_reply(c, 200, "", "%ld", res); // Nothing to write
} else {
struct mg_fd *fd;
size_t current_size = 0;
MG_DEBUG(("%s -> %d bytes @ %ld", path, (int) hm->body.len, offset));
if (offset == 0) fs->rm(path); // If offset if 0, truncate file
fs->st(path, &current_size, NULL);
if (offset < 0) {
mg_http_reply(c, 400, "", "offset required");
res = -1;
} else if (offset > 0 && current_size != (size_t) offset) {
mg_http_reply(c, 400, "", "%s: offset mismatch", path);
res = -2;
} else if ((size_t) offset + hm->body.len > max_size) {
mg_http_reply(c, 400, "", "%s: over max size of %lu", path,
(unsigned long) max_size);
res = -3;
} else if ((fd = mg_fs_open(fs, path, MG_FS_WRITE)) == NULL) {
mg_http_reply(c, 400, "", "open(%s): %d", path, errno);
res = -4;
} else {
res = offset + (long) fs->wr(fd->fd, hm->body.ptr, hm->body.len);
mg_fs_close(fd);
mg_http_reply(c, 200, "", "%ld", res);
}
}
return res;
}
int mg_http_status(const struct mg_http_message *hm) {
return atoi(hm->uri.ptr);
}
static bool is_hex_digit(int c) {
return (c >= '0' && c <= '9') || (c >= 'a' && c <= 'f') ||
(c >= 'A' && c <= 'F');
}
static int skip_chunk(const char *buf, int len, int *pl, int *dl) {
int i = 0, n = 0;
if (len < 3) return 0;
while (i < len && is_hex_digit(buf[i])) i++;
if (i == 0) return -1; // Error, no length specified
if (i > (int) sizeof(int) * 2) return -1; // Chunk length is too big
if (len < i + 1 || buf[i] != '\r' || buf[i + 1] != '\n') return -1; // Error
n = (int) mg_unhexn(buf, (size_t) i); // Decode chunk length
if (n < 0) return -1; // Error
if (n > len - i - 4) return 0; // Chunk not yet fully buffered
if (buf[i + n + 2] != '\r' || buf[i + n + 3] != '\n') return -1; // Error
*pl = i + 2, *dl = n;
return i + 2 + n + 2;
}
static void http_cb(struct mg_connection *c, int ev, void *ev_data) {
if (ev == MG_EV_READ || ev == MG_EV_CLOSE) {
struct mg_http_message hm;
size_t ofs = 0; // Parsing offset
while (c->is_resp == 0 && ofs < c->recv.len) {
const char *buf = (char *) c->recv.buf + ofs;
int n = mg_http_parse(buf, c->recv.len - ofs, &hm);
struct mg_str *te; // Transfer - encoding header
bool is_chunked = false;
if (n < 0) {
mg_error(c, "HTTP parse, %lu bytes", c->recv.len);
mg_hexdump(c->recv.buf, c->recv.len > 16 ? 16 : c->recv.len);
return;
}
if (n == 0) break; // Request is not buffered yet
if (ev == MG_EV_CLOSE) { // If client did not set Content-Length
hm.message.len = c->recv.len - ofs; // and closes now, deliver MSG
hm.body.len = hm.message.len - (size_t) (hm.body.ptr - hm.message.ptr);
}
if ((te = mg_http_get_header(&hm, "Transfer-Encoding")) != NULL) {
if (mg_vcasecmp(te, "chunked") == 0) {
is_chunked = true;
} else {
mg_error(c, "Invalid Transfer-Encoding"); // See #2460
return;
}
}
if (is_chunked) {
// For chunked data, strip off prefixes and suffixes from chunks
// and relocate them right after the headers, then report a message
char *s = (char *) c->recv.buf + ofs + n;
int o = 0, pl, dl, cl, len = (int) (c->recv.len - ofs - (size_t) n);
// Find zero-length chunk (the end of the body)
while ((cl = skip_chunk(s + o, len - o, &pl, &dl)) > 0 && dl) o += cl;
if (cl == 0) break; // No zero-len chunk, buffer more data
if (cl < 0) {
mg_error(c, "Invalid chunk");
break;
}
// Zero chunk found. Second pass: strip + relocate
o = 0, hm.body.len = 0, hm.message.len = (size_t) n;
while ((cl = skip_chunk(s + o, len - o, &pl, &dl)) > 0) {
memmove(s + hm.body.len, s + o + pl, (size_t) dl);
o += cl, hm.body.len += (size_t) dl, hm.message.len += (size_t) dl;
if (dl == 0) break;
}
ofs += (size_t) (n + o);
} else { // Normal, non-chunked data
size_t len = c->recv.len - ofs - (size_t) n;
if (hm.body.len > len) break; // Buffer more data
ofs += (size_t) n + hm.body.len;
}
if (c->is_accepted) c->is_resp = 1; // Start generating response
mg_call(c, MG_EV_HTTP_MSG, &hm); // User handler can clear is_resp
}
if (ofs > 0) mg_iobuf_del(&c->recv, 0, ofs); // Delete processed data
}
(void) ev_data;
}
static void mg_hfn(struct mg_connection *c, int ev, void *ev_data) {
if (ev == MG_EV_HTTP_MSG) {
struct mg_http_message *hm = (struct mg_http_message *) ev_data;
if (mg_http_match_uri(hm, "/quit")) {
mg_http_reply(c, 200, "", "ok\n");
c->is_draining = 1;
c->data[0] = 'X';
} else if (mg_http_match_uri(hm, "/debug")) {
int level = (int) mg_json_get_long(hm->body, "$.level", MG_LL_DEBUG);
mg_log_set(level);
mg_http_reply(c, 200, "", "Debug level set to %d\n", level);
} else {
mg_http_reply(c, 200, "", "hi\n");
}
} else if (ev == MG_EV_CLOSE) {
if (c->data[0] == 'X') *(bool *) c->fn_data = true;
}
}
void mg_hello(const char *url) {
struct mg_mgr mgr;
bool done = false;
mg_mgr_init(&mgr);
if (mg_http_listen(&mgr, url, mg_hfn, &done) == NULL) done = true;
while (done == false) mg_mgr_poll(&mgr, 100);
mg_mgr_free(&mgr);
}
struct mg_connection *mg_http_connect(struct mg_mgr *mgr, const char *url,
mg_event_handler_t fn, void *fn_data) {
struct mg_connection *c = mg_connect(mgr, url, fn, fn_data);
if (c != NULL) c->pfn = http_cb;
return c;
}
struct mg_connection *mg_http_listen(struct mg_mgr *mgr, const char *url,
mg_event_handler_t fn, void *fn_data) {
struct mg_connection *c = mg_listen(mgr, url, fn, fn_data);
if (c != NULL) c->pfn = http_cb;
return c;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/iobuf.c"
#endif
static size_t roundup(size_t size, size_t align) {
return align == 0 ? size : (size + align - 1) / align * align;
}
int mg_iobuf_resize(struct mg_iobuf *io, size_t new_size) {
int ok = 1;
new_size = roundup(new_size, io->align);
if (new_size == 0) {
mg_bzero(io->buf, io->size);
free(io->buf);
io->buf = NULL;
io->len = io->size = 0;
} else if (new_size != io->size) {
// NOTE(lsm): do not use realloc here. Use calloc/free only, to ease the
// porting to some obscure platforms like FreeRTOS
void *p = calloc(1, new_size);
if (p != NULL) {
size_t len = new_size < io->len ? new_size : io->len;
if (len > 0 && io->buf != NULL) memmove(p, io->buf, len);
mg_bzero(io->buf, io->size);
free(io->buf);
io->buf = (unsigned char *) p;
io->size = new_size;
} else {
ok = 0;
MG_ERROR(("%lld->%lld", (uint64_t) io->size, (uint64_t) new_size));
}
}
return ok;
}
int mg_iobuf_init(struct mg_iobuf *io, size_t size, size_t align) {
io->buf = NULL;
io->align = align;
io->size = io->len = 0;
return mg_iobuf_resize(io, size);
}
size_t mg_iobuf_add(struct mg_iobuf *io, size_t ofs, const void *buf,
size_t len) {
size_t new_size = roundup(io->len + len, io->align);
mg_iobuf_resize(io, new_size); // Attempt to resize
if (new_size != io->size) len = 0; // Resize failure, append nothing
if (ofs < io->len) memmove(io->buf + ofs + len, io->buf + ofs, io->len - ofs);
if (buf != NULL) memmove(io->buf + ofs, buf, len);
if (ofs > io->len) io->len += ofs - io->len;
io->len += len;
return len;
}
size_t mg_iobuf_del(struct mg_iobuf *io, size_t ofs, size_t len) {
if (ofs > io->len) ofs = io->len;
if (ofs + len > io->len) len = io->len - ofs;
if (io->buf) memmove(io->buf + ofs, io->buf + ofs + len, io->len - ofs - len);
if (io->buf) mg_bzero(io->buf + io->len - len, len);
io->len -= len;
return len;
}
void mg_iobuf_free(struct mg_iobuf *io) {
mg_iobuf_resize(io, 0);
}
#ifdef MG_ENABLE_LINES
#line 1 "src/json.c"
#endif
static const char *escapeseq(int esc) {
return esc ? "\b\f\n\r\t\\\"" : "bfnrt\\\"";
}
static char json_esc(int c, int esc) {
const char *p, *esc1 = escapeseq(esc), *esc2 = escapeseq(!esc);
for (p = esc1; *p != '\0'; p++) {
if (*p == c) return esc2[p - esc1];
}
return 0;
}
static int mg_pass_string(const char *s, int len) {
int i;
for (i = 0; i < len; i++) {
if (s[i] == '\\' && i + 1 < len && json_esc(s[i + 1], 1)) {
i++;
} else if (s[i] == '\0') {
return MG_JSON_INVALID;
} else if (s[i] == '"') {
return i;
}
}
return MG_JSON_INVALID;
}
static double mg_atod(const char *p, int len, int *numlen) {
double d = 0.0;
int i = 0, sign = 1;
// Sign
if (i < len && *p == '-') {
sign = -1, i++;
} else if (i < len && *p == '+') {
i++;
}
// Decimal
for (; i < len && p[i] >= '0' && p[i] <= '9'; i++) {
d *= 10.0;
d += p[i] - '0';
}
d *= sign;
// Fractional
if (i < len && p[i] == '.') {
double frac = 0.0, base = 0.1;
i++;
for (; i < len && p[i] >= '0' && p[i] <= '9'; i++) {
frac += base * (p[i] - '0');
base /= 10.0;
}
d += frac * sign;
}
// Exponential
if (i < len && (p[i] == 'e' || p[i] == 'E')) {
int j, exp = 0, minus = 0;
i++;
if (i < len && p[i] == '-') minus = 1, i++;
if (i < len && p[i] == '+') i++;
while (i < len && p[i] >= '0' && p[i] <= '9' && exp < 308)
exp = exp * 10 + (p[i++] - '0');
if (minus) exp = -exp;
for (j = 0; j < exp; j++) d *= 10.0;
for (j = 0; j < -exp; j++) d /= 10.0;
}
if (numlen != NULL) *numlen = i;
return d;
}
// Iterate over object or array elements
size_t mg_json_next(struct mg_str obj, size_t ofs, struct mg_str *key,
struct mg_str *val) {
if (ofs >= obj.len) {
ofs = 0; // Out of boundaries, stop scanning
} else if (obj.len < 2 || (*obj.ptr != '{' && *obj.ptr != '[')) {
ofs = 0; // Not an array or object, stop
} else {
struct mg_str sub = mg_str_n(obj.ptr + ofs, obj.len - ofs);
if (ofs == 0) ofs++, sub.ptr++, sub.len--;
if (*obj.ptr == '[') { // Iterate over an array
int n = 0, o = mg_json_get(sub, "$", &n);
if (n < 0 || o < 0 || (size_t) (o + n) > sub.len) {
ofs = 0; // Error parsing key, stop scanning
} else {
if (key) *key = mg_str_n(NULL, 0);
if (val) *val = mg_str_n(sub.ptr + o, (size_t) n);
ofs = (size_t) (&sub.ptr[o + n] - obj.ptr);
}
} else { // Iterate over an object
int n = 0, o = mg_json_get(sub, "$", &n);
if (n < 0 || o < 0 || (size_t) (o + n) > sub.len) {
ofs = 0; // Error parsing key, stop scanning
} else {
if (key) *key = mg_str_n(sub.ptr + o, (size_t) n);
sub.ptr += o + n, sub.len -= (size_t) (o + n);
while (sub.len > 0 && *sub.ptr != ':') sub.len--, sub.ptr++;
if (sub.len > 0 && *sub.ptr == ':') sub.len--, sub.ptr++;
n = 0, o = mg_json_get(sub, "$", &n);
if (n < 0 || o < 0 || (size_t) (o + n) > sub.len) {
ofs = 0; // Error parsing value, stop scanning
} else {
if (val) *val = mg_str_n(sub.ptr + o, (size_t) n);
ofs = (size_t) (&sub.ptr[o + n] - obj.ptr);
}
}
}
//MG_INFO(("SUB ofs %u %.*s", ofs, sub.len, sub.ptr));
while (ofs && ofs < obj.len &&
(obj.ptr[ofs] == ' ' || obj.ptr[ofs] == '\t' ||
obj.ptr[ofs] == '\n' || obj.ptr[ofs] == '\r')) {
ofs++;
}
if (ofs && ofs < obj.len && obj.ptr[ofs] == ',') ofs++;
if (ofs > obj.len) ofs = 0;
}
return ofs;
}
int mg_json_get(struct mg_str json, const char *path, int *toklen) {
const char *s = json.ptr;
int len = (int) json.len;
enum { S_VALUE, S_KEY, S_COLON, S_COMMA_OR_EOO } expecting = S_VALUE;
unsigned char nesting[MG_JSON_MAX_DEPTH];
int i = 0; // Current offset in `s`
int j = 0; // Offset in `s` we're looking for (return value)
int depth = 0; // Current depth (nesting level)
int ed = 0; // Expected depth
int pos = 1; // Current position in `path`
int ci = -1, ei = -1; // Current and expected index in array
if (toklen) *toklen = 0;
if (path[0] != '$') return MG_JSON_INVALID;
#define MG_CHECKRET(x) \
do { \
if (depth == ed && path[pos] == '\0' && ci == ei) { \
if (toklen) *toklen = i - j + 1; \
return j; \
} \
} while (0)
// In the ascii table, the distance between `[` and `]` is 2.
// Ditto for `{` and `}`. Hence +2 in the code below.
#define MG_EOO(x) \
do { \
if (depth == ed && ci != ei) return MG_JSON_NOT_FOUND; \
if (c != nesting[depth - 1] + 2) return MG_JSON_INVALID; \
depth--; \
MG_CHECKRET(x); \
} while (0)
for (i = 0; i < len; i++) {
unsigned char c = ((unsigned char *) s)[i];
if (c == ' ' || c == '\t' || c == '\n' || c == '\r') continue;
switch (expecting) {
case S_VALUE:
// p("V %s [%.*s] %d %d %d %d\n", path, pos, path, depth, ed, ci, ei);
if (depth == ed) j = i;
if (c == '{') {
if (depth >= (int) sizeof(nesting)) return MG_JSON_TOO_DEEP;
if (depth == ed && path[pos] == '.' && ci == ei) {
// If we start the object, reset array indices
ed++, pos++, ci = ei = -1;
}
nesting[depth++] = c;
expecting = S_KEY;
break;
} else if (c == '[') {
if (depth >= (int) sizeof(nesting)) return MG_JSON_TOO_DEEP;
if (depth == ed && path[pos] == '[' && ei == ci) {
ed++, pos++, ci = 0;
for (ei = 0; path[pos] != ']' && path[pos] != '\0'; pos++) {
ei *= 10;
ei += path[pos] - '0';
}
if (path[pos] != 0) pos++;
}
nesting[depth++] = c;
break;
} else if (c == ']' && depth > 0) { // Empty array
MG_EOO(']');
} else if (c == 't' && i + 3 < len && memcmp(&s[i], "true", 4) == 0) {
i += 3;
} else if (c == 'n' && i + 3 < len && memcmp(&s[i], "null", 4) == 0) {
i += 3;
} else if (c == 'f' && i + 4 < len && memcmp(&s[i], "false", 5) == 0) {
i += 4;
} else if (c == '-' || ((c >= '0' && c <= '9'))) {
int numlen = 0;
mg_atod(&s[i], len - i, &numlen);
i += numlen - 1;
} else if (c == '"') {
int n = mg_pass_string(&s[i + 1], len - i - 1);
if (n < 0) return n;
i += n + 1;
} else {
return MG_JSON_INVALID;
}
MG_CHECKRET('V');
if (depth == ed && ei >= 0) ci++;
expecting = S_COMMA_OR_EOO;
break;
case S_KEY:
if (c == '"') {
int n = mg_pass_string(&s[i + 1], len - i - 1);
if (n < 0) return n;
if (i + 1 + n >= len) return MG_JSON_NOT_FOUND;
if (depth < ed) return MG_JSON_NOT_FOUND;
if (depth == ed && path[pos - 1] != '.') return MG_JSON_NOT_FOUND;
// printf("K %s [%.*s] [%.*s] %d %d %d %d %d\n", path, pos, path, n,
// &s[i + 1], n, depth, ed, ci, ei);
// NOTE(cpq): in the check sequence below is important.
// strncmp() must go first: it fails fast if the remaining length
// of the path is smaller than `n`.
if (depth == ed && path[pos - 1] == '.' &&
strncmp(&s[i + 1], &path[pos], (size_t) n) == 0 &&
(path[pos + n] == '\0' || path[pos + n] == '.' ||
path[pos + n] == '[')) {
pos += n;
}
i += n + 1;
expecting = S_COLON;
} else if (c == '}') { // Empty object
MG_EOO('}');
expecting = S_COMMA_OR_EOO;
if (depth == ed && ei >= 0) ci++;
} else {
return MG_JSON_INVALID;
}
break;
case S_COLON:
if (c == ':') {
expecting = S_VALUE;
} else {
return MG_JSON_INVALID;
}
break;
case S_COMMA_OR_EOO:
if (depth <= 0) {
return MG_JSON_INVALID;
} else if (c == ',') {
expecting = (nesting[depth - 1] == '{') ? S_KEY : S_VALUE;
} else if (c == ']' || c == '}') {
if (depth == ed && c == '}' && path[pos - 1] == '.')
return MG_JSON_NOT_FOUND;
if (depth == ed && c == ']' && path[pos - 1] == ',')
return MG_JSON_NOT_FOUND;
MG_EOO('O');
if (depth == ed && ei >= 0) ci++;
} else {
return MG_JSON_INVALID;
}
break;
}
}
return MG_JSON_NOT_FOUND;
}
bool mg_json_get_num(struct mg_str json, const char *path, double *v) {
int n, toklen, found = 0;
if ((n = mg_json_get(json, path, &toklen)) >= 0 &&
(json.ptr[n] == '-' || (json.ptr[n] >= '0' && json.ptr[n] <= '9'))) {
if (v != NULL) *v = mg_atod(json.ptr + n, toklen, NULL);
found = 1;
}
return found;
}
bool mg_json_get_bool(struct mg_str json, const char *path, bool *v) {
int found = 0, off = mg_json_get(json, path, NULL);
if (off >= 0 && (json.ptr[off] == 't' || json.ptr[off] == 'f')) {
if (v != NULL) *v = json.ptr[off] == 't';
found = 1;
}
return found;
}
bool mg_json_unescape(struct mg_str s, char *to, size_t n) {
size_t i, j;
for (i = 0, j = 0; i < s.len && j < n; i++, j++) {
if (s.ptr[i] == '\\' && i + 5 < s.len && s.ptr[i + 1] == 'u') {
// \uXXXX escape. We could process a simple one-byte chars
// \u00xx from the ASCII range. More complex chars would require
// dragging in a UTF8 library, which is too much for us
if (s.ptr[i + 2] != '0' || s.ptr[i + 3] != '0') return false; // Give up
((unsigned char *) to)[j] = (unsigned char) mg_unhexn(s.ptr + i + 4, 2);
i += 5;
} else if (s.ptr[i] == '\\' && i + 1 < s.len) {
char c = json_esc(s.ptr[i + 1], 0);
if (c == 0) return false;
to[j] = c;
i++;
} else {
to[j] = s.ptr[i];
}
}
if (j >= n) return false;
if (n > 0) to[j] = '\0';
return true;
}
char *mg_json_get_str(struct mg_str json, const char *path) {
char *result = NULL;
int len = 0, off = mg_json_get(json, path, &len);
if (off >= 0 && len > 1 && json.ptr[off] == '"') {
if ((result = (char *) calloc(1, (size_t) len)) != NULL &&
!mg_json_unescape(mg_str_n(json.ptr + off + 1, (size_t) (len - 2)),
result, (size_t) len)) {
free(result);
result = NULL;
}
}
return result;
}
char *mg_json_get_b64(struct mg_str json, const char *path, int *slen) {
char *result = NULL;
int len = 0, off = mg_json_get(json, path, &len);
if (off >= 0 && json.ptr[off] == '"' && len > 1 &&
(result = (char *) calloc(1, (size_t) len)) != NULL) {
size_t k = mg_base64_decode(json.ptr + off + 1, (size_t) (len - 2), result,
(size_t) len);
if (slen != NULL) *slen = (int) k;
}
return result;
}
char *mg_json_get_hex(struct mg_str json, const char *path, int *slen) {
char *result = NULL;
int len = 0, off = mg_json_get(json, path, &len);
if (off >= 0 && json.ptr[off] == '"' && len > 1 &&
(result = (char *) calloc(1, (size_t) len / 2)) != NULL) {
mg_unhex(json.ptr + off + 1, (size_t) (len - 2), (uint8_t *) result);
result[len / 2 - 1] = '\0';
if (slen != NULL) *slen = len / 2 - 1;
}
return result;
}
long mg_json_get_long(struct mg_str json, const char *path, long dflt) {
double dv;
long result = dflt;
if (mg_json_get_num(json, path, &dv)) result = (long) dv;
return result;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/log.c"
#endif
int mg_log_level = MG_LL_INFO;
static mg_pfn_t s_log_func = mg_pfn_stdout;
static void *s_log_func_param = NULL;
void mg_log_set_fn(mg_pfn_t fn, void *param) {
s_log_func = fn;
s_log_func_param = param;
}
static void logc(unsigned char c) {
s_log_func((char) c, s_log_func_param);
}
static void logs(const char *buf, size_t len) {
size_t i;
for (i = 0; i < len; i++) logc(((unsigned char *) buf)[i]);
}
#if MG_ENABLE_CUSTOM_LOG
// Let user define their own mg_log_prefix() and mg_log()
#else
void mg_log_prefix(int level, const char *file, int line, const char *fname) {
const char *p = strrchr(file, '/');
char buf[41];
size_t n;
if (p == NULL) p = strrchr(file, '\\');
n = mg_snprintf(buf, sizeof(buf), "%-6llx %d %s:%d:%s", mg_millis(), level,
p == NULL ? file : p + 1, line, fname);
if (n > sizeof(buf) - 2) n = sizeof(buf) - 2;
while (n < sizeof(buf)) buf[n++] = ' ';
logs(buf, n - 1);
}
void mg_log(const char *fmt, ...) {
va_list ap;
va_start(ap, fmt);
mg_vxprintf(s_log_func, s_log_func_param, fmt, &ap);
va_end(ap);
logs("\r\n", 2);
}
#endif
static unsigned char nibble(unsigned c) {
return (unsigned char) (c < 10 ? c + '0' : c + 'W');
}
#define ISPRINT(x) ((x) >= ' ' && (x) <= '~')
void mg_hexdump(const void *buf, size_t len) {
const unsigned char *p = (const unsigned char *) buf;
unsigned char ascii[16], alen = 0;
size_t i;
for (i = 0; i < len; i++) {
if ((i % 16) == 0) {
// Print buffered ascii chars
if (i > 0) logs(" ", 2), logs((char *) ascii, 16), logc('\n'), alen = 0;
// Print hex address, then \t
logc(nibble((i >> 12) & 15)), logc(nibble((i >> 8) & 15)),
logc(nibble((i >> 4) & 15)), logc('0'), logs(" ", 3);
}
logc(nibble(p[i] >> 4)), logc(nibble(p[i] & 15)); // Two nibbles, e.g. c5
logc(' '); // Space after hex number
ascii[alen++] = ISPRINT(p[i]) ? p[i] : '.'; // Add to the ascii buf
}
while (alen < 16) logs(" ", 3), ascii[alen++] = ' ';
logs(" ", 2), logs((char *) ascii, 16), logc('\n');
}
#ifdef MG_ENABLE_LINES
#line 1 "src/md5.c"
#endif
// This code implements the MD5 message-digest algorithm.
// The algorithm is due to Ron Rivest. This code was
// written by Colin Plumb in 1993, no copyright is claimed.
// This code is in the public domain; do with it what you wish.
//
// Equivalent code is available from RSA Data Security, Inc.
// This code has been tested against that, and is equivalent,
// except that you don't need to include two pages of legalese
// with every copy.
//
// To compute the message digest of a chunk of bytes, declare an
// MD5Context structure, pass it to MD5Init, call MD5Update as
// needed on buffers full of bytes, and then call MD5Final, which
// will fill a supplied 16-byte array with the digest.
#if defined(MG_ENABLE_MD5) && MG_ENABLE_MD5
static void mg_byte_reverse(unsigned char *buf, unsigned longs) {
if (MG_BIG_ENDIAN) {
do {
uint32_t t = (uint32_t) ((unsigned) buf[3] << 8 | buf[2]) << 16 |
((unsigned) buf[1] << 8 | buf[0]);
*(uint32_t *) buf = t;
buf += 4;
} while (--longs);
} else {
(void) buf, (void) longs; // Little endian. Do nothing
}
}
#define F1(x, y, z) (z ^ (x & (y ^ z)))
#define F2(x, y, z) F1(z, x, y)
#define F3(x, y, z) (x ^ y ^ z)
#define F4(x, y, z) (y ^ (x | ~z))
#define MD5STEP(f, w, x, y, z, data, s) \
(w += f(x, y, z) + data, w = w << s | w >> (32 - s), w += x)
/*
* Start MD5 accumulation. Set bit count to 0 and buffer to mysterious
* initialization constants.
*/
void mg_md5_init(mg_md5_ctx *ctx) {
ctx->buf[0] = 0x67452301;
ctx->buf[1] = 0xefcdab89;
ctx->buf[2] = 0x98badcfe;
ctx->buf[3] = 0x10325476;
ctx->bits[0] = 0;
ctx->bits[1] = 0;
}
static void mg_md5_transform(uint32_t buf[4], uint32_t const in[16]) {
uint32_t a, b, c, d;
a = buf[0];
b = buf[1];
c = buf[2];
d = buf[3];
MD5STEP(F1, a, b, c, d, in[0] + 0xd76aa478, 7);
MD5STEP(F1, d, a, b, c, in[1] + 0xe8c7b756, 12);
MD5STEP(F1, c, d, a, b, in[2] + 0x242070db, 17);
MD5STEP(F1, b, c, d, a, in[3] + 0xc1bdceee, 22);
MD5STEP(F1, a, b, c, d, in[4] + 0xf57c0faf, 7);
MD5STEP(F1, d, a, b, c, in[5] + 0x4787c62a, 12);
MD5STEP(F1, c, d, a, b, in[6] + 0xa8304613, 17);
MD5STEP(F1, b, c, d, a, in[7] + 0xfd469501, 22);
MD5STEP(F1, a, b, c, d, in[8] + 0x698098d8, 7);
MD5STEP(F1, d, a, b, c, in[9] + 0x8b44f7af, 12);
MD5STEP(F1, c, d, a, b, in[10] + 0xffff5bb1, 17);
MD5STEP(F1, b, c, d, a, in[11] + 0x895cd7be, 22);
MD5STEP(F1, a, b, c, d, in[12] + 0x6b901122, 7);
MD5STEP(F1, d, a, b, c, in[13] + 0xfd987193, 12);
MD5STEP(F1, c, d, a, b, in[14] + 0xa679438e, 17);
MD5STEP(F1, b, c, d, a, in[15] + 0x49b40821, 22);
MD5STEP(F2, a, b, c, d, in[1] + 0xf61e2562, 5);
MD5STEP(F2, d, a, b, c, in[6] + 0xc040b340, 9);
MD5STEP(F2, c, d, a, b, in[11] + 0x265e5a51, 14);
MD5STEP(F2, b, c, d, a, in[0] + 0xe9b6c7aa, 20);
MD5STEP(F2, a, b, c, d, in[5] + 0xd62f105d, 5);
MD5STEP(F2, d, a, b, c, in[10] + 0x02441453, 9);
MD5STEP(F2, c, d, a, b, in[15] + 0xd8a1e681, 14);
MD5STEP(F2, b, c, d, a, in[4] + 0xe7d3fbc8, 20);
MD5STEP(F2, a, b, c, d, in[9] + 0x21e1cde6, 5);
MD5STEP(F2, d, a, b, c, in[14] + 0xc33707d6, 9);
MD5STEP(F2, c, d, a, b, in[3] + 0xf4d50d87, 14);
MD5STEP(F2, b, c, d, a, in[8] + 0x455a14ed, 20);
MD5STEP(F2, a, b, c, d, in[13] + 0xa9e3e905, 5);
MD5STEP(F2, d, a, b, c, in[2] + 0xfcefa3f8, 9);
MD5STEP(F2, c, d, a, b, in[7] + 0x676f02d9, 14);
MD5STEP(F2, b, c, d, a, in[12] + 0x8d2a4c8a, 20);
MD5STEP(F3, a, b, c, d, in[5] + 0xfffa3942, 4);
MD5STEP(F3, d, a, b, c, in[8] + 0x8771f681, 11);
MD5STEP(F3, c, d, a, b, in[11] + 0x6d9d6122, 16);
MD5STEP(F3, b, c, d, a, in[14] + 0xfde5380c, 23);
MD5STEP(F3, a, b, c, d, in[1] + 0xa4beea44, 4);
MD5STEP(F3, d, a, b, c, in[4] + 0x4bdecfa9, 11);
MD5STEP(F3, c, d, a, b, in[7] + 0xf6bb4b60, 16);
MD5STEP(F3, b, c, d, a, in[10] + 0xbebfbc70, 23);
MD5STEP(F3, a, b, c, d, in[13] + 0x289b7ec6, 4);
MD5STEP(F3, d, a, b, c, in[0] + 0xeaa127fa, 11);
MD5STEP(F3, c, d, a, b, in[3] + 0xd4ef3085, 16);
MD5STEP(F3, b, c, d, a, in[6] + 0x04881d05, 23);
MD5STEP(F3, a, b, c, d, in[9] + 0xd9d4d039, 4);
MD5STEP(F3, d, a, b, c, in[12] + 0xe6db99e5, 11);
MD5STEP(F3, c, d, a, b, in[15] + 0x1fa27cf8, 16);
MD5STEP(F3, b, c, d, a, in[2] + 0xc4ac5665, 23);
MD5STEP(F4, a, b, c, d, in[0] + 0xf4292244, 6);
MD5STEP(F4, d, a, b, c, in[7] + 0x432aff97, 10);
MD5STEP(F4, c, d, a, b, in[14] + 0xab9423a7, 15);
MD5STEP(F4, b, c, d, a, in[5] + 0xfc93a039, 21);
MD5STEP(F4, a, b, c, d, in[12] + 0x655b59c3, 6);
MD5STEP(F4, d, a, b, c, in[3] + 0x8f0ccc92, 10);
MD5STEP(F4, c, d, a, b, in[10] + 0xffeff47d, 15);
MD5STEP(F4, b, c, d, a, in[1] + 0x85845dd1, 21);
MD5STEP(F4, a, b, c, d, in[8] + 0x6fa87e4f, 6);
MD5STEP(F4, d, a, b, c, in[15] + 0xfe2ce6e0, 10);
MD5STEP(F4, c, d, a, b, in[6] + 0xa3014314, 15);
MD5STEP(F4, b, c, d, a, in[13] + 0x4e0811a1, 21);
MD5STEP(F4, a, b, c, d, in[4] + 0xf7537e82, 6);
MD5STEP(F4, d, a, b, c, in[11] + 0xbd3af235, 10);
MD5STEP(F4, c, d, a, b, in[2] + 0x2ad7d2bb, 15);
MD5STEP(F4, b, c, d, a, in[9] + 0xeb86d391, 21);
buf[0] += a;
buf[1] += b;
buf[2] += c;
buf[3] += d;
}
void mg_md5_update(mg_md5_ctx *ctx, const unsigned char *buf, size_t len) {
uint32_t t;
t = ctx->bits[0];
if ((ctx->bits[0] = t + ((uint32_t) len << 3)) < t) ctx->bits[1]++;
ctx->bits[1] += (uint32_t) len >> 29;
t = (t >> 3) & 0x3f;
if (t) {
unsigned char *p = (unsigned char *) ctx->in + t;
t = 64 - t;
if (len < t) {
memcpy(p, buf, len);
return;
}
memcpy(p, buf, t);
mg_byte_reverse(ctx->in, 16);
mg_md5_transform(ctx->buf, (uint32_t *) ctx->in);
buf += t;
len -= t;
}
while (len >= 64) {
memcpy(ctx->in, buf, 64);
mg_byte_reverse(ctx->in, 16);
mg_md5_transform(ctx->buf, (uint32_t *) ctx->in);
buf += 64;
len -= 64;
}
memcpy(ctx->in, buf, len);
}
void mg_md5_final(mg_md5_ctx *ctx, unsigned char digest[16]) {
unsigned count;
unsigned char *p;
uint32_t *a;
count = (ctx->bits[0] >> 3) & 0x3F;
p = ctx->in + count;
*p++ = 0x80;
count = 64 - 1 - count;
if (count < 8) {
memset(p, 0, count);
mg_byte_reverse(ctx->in, 16);
mg_md5_transform(ctx->buf, (uint32_t *) ctx->in);
memset(ctx->in, 0, 56);
} else {
memset(p, 0, count - 8);
}
mg_byte_reverse(ctx->in, 14);
a = (uint32_t *) ctx->in;
a[14] = ctx->bits[0];
a[15] = ctx->bits[1];
mg_md5_transform(ctx->buf, (uint32_t *) ctx->in);
mg_byte_reverse((unsigned char *) ctx->buf, 4);
memcpy(digest, ctx->buf, 16);
memset((char *) ctx, 0, sizeof(*ctx));
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/mqtt.c"
#endif
#define MQTT_CLEAN_SESSION 0x02
#define MQTT_HAS_WILL 0x04
#define MQTT_WILL_RETAIN 0x20
#define MQTT_HAS_PASSWORD 0x40
#define MQTT_HAS_USER_NAME 0x80
struct mg_mqtt_pmap {
uint8_t id;
uint8_t type;
};
static const struct mg_mqtt_pmap s_prop_map[] = {
{MQTT_PROP_PAYLOAD_FORMAT_INDICATOR, MQTT_PROP_TYPE_BYTE},
{MQTT_PROP_MESSAGE_EXPIRY_INTERVAL, MQTT_PROP_TYPE_INT},
{MQTT_PROP_CONTENT_TYPE, MQTT_PROP_TYPE_STRING},
{MQTT_PROP_RESPONSE_TOPIC, MQTT_PROP_TYPE_STRING},
{MQTT_PROP_CORRELATION_DATA, MQTT_PROP_TYPE_BINARY_DATA},
{MQTT_PROP_SUBSCRIPTION_IDENTIFIER, MQTT_PROP_TYPE_VARIABLE_INT},
{MQTT_PROP_SESSION_EXPIRY_INTERVAL, MQTT_PROP_TYPE_INT},
{MQTT_PROP_ASSIGNED_CLIENT_IDENTIFIER, MQTT_PROP_TYPE_STRING},
{MQTT_PROP_SERVER_KEEP_ALIVE, MQTT_PROP_TYPE_SHORT},
{MQTT_PROP_AUTHENTICATION_METHOD, MQTT_PROP_TYPE_STRING},
{MQTT_PROP_AUTHENTICATION_DATA, MQTT_PROP_TYPE_BINARY_DATA},
{MQTT_PROP_REQUEST_PROBLEM_INFORMATION, MQTT_PROP_TYPE_BYTE},
{MQTT_PROP_WILL_DELAY_INTERVAL, MQTT_PROP_TYPE_INT},
{MQTT_PROP_REQUEST_RESPONSE_INFORMATION, MQTT_PROP_TYPE_BYTE},
{MQTT_PROP_RESPONSE_INFORMATION, MQTT_PROP_TYPE_STRING},
{MQTT_PROP_SERVER_REFERENCE, MQTT_PROP_TYPE_STRING},
{MQTT_PROP_REASON_STRING, MQTT_PROP_TYPE_STRING},
{MQTT_PROP_RECEIVE_MAXIMUM, MQTT_PROP_TYPE_SHORT},
{MQTT_PROP_TOPIC_ALIAS_MAXIMUM, MQTT_PROP_TYPE_SHORT},
{MQTT_PROP_TOPIC_ALIAS, MQTT_PROP_TYPE_SHORT},
{MQTT_PROP_MAXIMUM_QOS, MQTT_PROP_TYPE_BYTE},
{MQTT_PROP_RETAIN_AVAILABLE, MQTT_PROP_TYPE_BYTE},
{MQTT_PROP_USER_PROPERTY, MQTT_PROP_TYPE_STRING_PAIR},
{MQTT_PROP_MAXIMUM_PACKET_SIZE, MQTT_PROP_TYPE_INT},
{MQTT_PROP_WILDCARD_SUBSCRIPTION_AVAILABLE, MQTT_PROP_TYPE_BYTE},
{MQTT_PROP_SUBSCRIPTION_IDENTIFIER_AVAILABLE, MQTT_PROP_TYPE_BYTE},
{MQTT_PROP_SHARED_SUBSCRIPTION_AVAILABLE, MQTT_PROP_TYPE_BYTE}};
void mg_mqtt_send_header(struct mg_connection *c, uint8_t cmd, uint8_t flags,
uint32_t len) {
uint8_t buf[1 + sizeof(len)], *vlen = &buf[1];
buf[0] = (uint8_t) ((cmd << 4) | flags);
do {
*vlen = len % 0x80;
len /= 0x80;
if (len > 0) *vlen |= 0x80;
vlen++;
} while (len > 0 && vlen < &buf[sizeof(buf)]);
mg_send(c, buf, (size_t) (vlen - buf));
}
static void mg_send_u16(struct mg_connection *c, uint16_t value) {
mg_send(c, &value, sizeof(value));
}
static void mg_send_u32(struct mg_connection *c, uint32_t value) {
mg_send(c, &value, sizeof(value));
}
static uint8_t varint_size(size_t length) {
uint8_t bytes_needed = 0;
do {
bytes_needed++;
length /= 0x80;
} while (length > 0);
return bytes_needed;
}
static size_t encode_varint(uint8_t *buf, size_t value) {
size_t len = 0;
do {
uint8_t byte = (uint8_t) (value % 128);
value /= 128;
if (value > 0) byte |= 0x80;
buf[len++] = byte;
} while (value > 0);
return len;
}
static size_t decode_varint(const uint8_t *buf, size_t len, size_t *value) {
size_t multiplier = 1, offset;
*value = 0;
for (offset = 0; offset < 4 && offset < len; offset++) {
uint8_t encoded_byte = buf[offset];
*value += (encoded_byte & 0x7f) * multiplier;
multiplier *= 128;
if ((encoded_byte & 0x80) == 0) return offset + 1;
}
return 0;
}
static int mqtt_prop_type_by_id(uint8_t prop_id) {
size_t i, num_properties = sizeof(s_prop_map) / sizeof(s_prop_map[0]);
for (i = 0; i < num_properties; ++i) {
if (s_prop_map[i].id == prop_id) return s_prop_map[i].type;
}
return -1; // Property ID not found
}
// Returns the size of the properties section, without the
// size of the content's length
static size_t get_properties_length(struct mg_mqtt_prop *props, size_t count) {
size_t i, size = 0;
for (i = 0; i < count; i++) {
size++; // identifier
switch (mqtt_prop_type_by_id(props[i].id)) {
case MQTT_PROP_TYPE_STRING_PAIR:
size += (uint32_t) (props[i].val.len + props[i].key.len +
2 * sizeof(uint16_t));
break;
case MQTT_PROP_TYPE_STRING:
size += (uint32_t) (props[i].val.len + sizeof(uint16_t));
break;
case MQTT_PROP_TYPE_BINARY_DATA:
size += (uint32_t) (props[i].val.len + sizeof(uint16_t));
break;
case MQTT_PROP_TYPE_VARIABLE_INT:
size += varint_size((uint32_t) props[i].iv);
break;
case MQTT_PROP_TYPE_INT:
size += (uint32_t) sizeof(uint32_t);
break;
case MQTT_PROP_TYPE_SHORT:
size += (uint32_t) sizeof(uint16_t);
break;
case MQTT_PROP_TYPE_BYTE:
size += (uint32_t) sizeof(uint8_t);
break;
default:
return size; // cannot parse further down
}
}
return size;
}
// returns the entire size of the properties section, including the
// size of the variable length of the content
static size_t get_props_size(struct mg_mqtt_prop *props, size_t count) {
size_t size = get_properties_length(props, count);
size += varint_size(size);
return size;
}
static void mg_send_mqtt_properties(struct mg_connection *c,
struct mg_mqtt_prop *props, size_t nprops) {
size_t total_size = get_properties_length(props, nprops);
uint8_t buf_v[4] = {0, 0, 0, 0};
uint8_t buf[4] = {0, 0, 0, 0};
size_t i, len = encode_varint(buf, total_size);
mg_send(c, buf, (size_t) len);
for (i = 0; i < nprops; i++) {
mg_send(c, &props[i].id, sizeof(props[i].id));
switch (mqtt_prop_type_by_id(props[i].id)) {
case MQTT_PROP_TYPE_STRING_PAIR:
mg_send_u16(c, mg_htons((uint16_t) props[i].key.len));
mg_send(c, props[i].key.ptr, props[i].key.len);
mg_send_u16(c, mg_htons((uint16_t) props[i].val.len));
mg_send(c, props[i].val.ptr, props[i].val.len);
break;
case MQTT_PROP_TYPE_BYTE:
mg_send(c, &props[i].iv, sizeof(uint8_t));
break;
case MQTT_PROP_TYPE_SHORT:
mg_send_u16(c, mg_htons((uint16_t) props[i].iv));
break;
case MQTT_PROP_TYPE_INT:
mg_send_u32(c, mg_htonl((uint32_t) props[i].iv));
break;
case MQTT_PROP_TYPE_STRING:
mg_send_u16(c, mg_htons((uint16_t) props[i].val.len));
mg_send(c, props[i].val.ptr, props[i].val.len);
break;
case MQTT_PROP_TYPE_BINARY_DATA:
mg_send_u16(c, mg_htons((uint16_t) props[i].val.len));
mg_send(c, props[i].val.ptr, props[i].val.len);
break;
case MQTT_PROP_TYPE_VARIABLE_INT:
len = encode_varint(buf_v, props[i].iv);
mg_send(c, buf_v, (size_t) len);
break;
}
}
}
size_t mg_mqtt_next_prop(struct mg_mqtt_message *msg, struct mg_mqtt_prop *prop,
size_t ofs) {
uint8_t *i = (uint8_t *) msg->dgram.ptr + msg->props_start + ofs;
uint8_t *end = (uint8_t *) msg->dgram.ptr + msg->dgram.len;
size_t new_pos = ofs, len;
prop->id = i[0];
if (ofs >= msg->dgram.len || ofs >= msg->props_start + msg->props_size)
return 0;
i++, new_pos++;
switch (mqtt_prop_type_by_id(prop->id)) {
case MQTT_PROP_TYPE_STRING_PAIR:
prop->key.len = (uint16_t) ((((uint16_t) i[0]) << 8) | i[1]);
prop->key.ptr = (char *) i + 2;
i += 2 + prop->key.len;
prop->val.len = (uint16_t) ((((uint16_t) i[0]) << 8) | i[1]);
prop->val.ptr = (char *) i + 2;
new_pos += 2 * sizeof(uint16_t) + prop->val.len + prop->key.len;
break;
case MQTT_PROP_TYPE_BYTE:
prop->iv = (uint8_t) i[0];
new_pos++;
break;
case MQTT_PROP_TYPE_SHORT:
prop->iv = (uint16_t) ((((uint16_t) i[0]) << 8) | i[1]);
new_pos += sizeof(uint16_t);
break;
case MQTT_PROP_TYPE_INT:
prop->iv = ((uint32_t) i[0] << 24) | ((uint32_t) i[1] << 16) |
((uint32_t) i[2] << 8) | i[3];
new_pos += sizeof(uint32_t);
break;
case MQTT_PROP_TYPE_STRING:
prop->val.len = (uint16_t) ((((uint16_t) i[0]) << 8) | i[1]);
prop->val.ptr = (char *) i + 2;
new_pos += 2 + prop->val.len;
break;
case MQTT_PROP_TYPE_BINARY_DATA:
prop->val.len = (uint16_t) ((((uint16_t) i[0]) << 8) | i[1]);
prop->val.ptr = (char *) i + 2;
new_pos += 2 + prop->val.len;
break;
case MQTT_PROP_TYPE_VARIABLE_INT:
len = decode_varint(i, (size_t) (end - i), (size_t *) &prop->iv);
new_pos = (!len) ? 0 : new_pos + len;
break;
default:
new_pos = 0;
}
return new_pos;
}
void mg_mqtt_login(struct mg_connection *c, const struct mg_mqtt_opts *opts) {
char rnd[10], client_id[21];
struct mg_str cid = opts->client_id;
size_t total_len = 7 + 1 + 2 + 2;
uint8_t hdr[8] = {0, 4, 'M', 'Q', 'T', 'T', opts->version, 0};
if (cid.len == 0) {
mg_random(rnd, sizeof(rnd));
mg_hex(rnd, sizeof(rnd), client_id);
client_id[sizeof(client_id) - 1] = '\0';
cid = mg_str(client_id);
}
if (hdr[6] == 0) hdr[6] = 4; // If version is not set, use 4 (3.1.1)
c->is_mqtt5 = hdr[6] == 5; // Set version 5 flag
hdr[7] = (uint8_t) ((opts->qos & 3) << 3); // Connection flags
if (opts->user.len > 0) {
total_len += 2 + (uint32_t) opts->user.len;
hdr[7] |= MQTT_HAS_USER_NAME;
}
if (opts->pass.len > 0) {
total_len += 2 + (uint32_t) opts->pass.len;
hdr[7] |= MQTT_HAS_PASSWORD;
}
if (opts->topic.len > 0 && opts->message.len > 0) {
total_len += 4 + (uint32_t) opts->topic.len + (uint32_t) opts->message.len;
hdr[7] |= MQTT_HAS_WILL;
}
if (opts->clean || cid.len == 0) hdr[7] |= MQTT_CLEAN_SESSION;
if (opts->retain) hdr[7] |= MQTT_WILL_RETAIN;
total_len += (uint32_t) cid.len;
if (c->is_mqtt5) {
total_len += get_props_size(opts->props, opts->num_props);
if (hdr[7] & MQTT_HAS_WILL)
total_len += get_props_size(opts->will_props, opts->num_will_props);
}
mg_mqtt_send_header(c, MQTT_CMD_CONNECT, 0, (uint32_t) total_len);
mg_send(c, hdr, sizeof(hdr));
// keepalive == 0 means "do not disconnect us!"
mg_send_u16(c, mg_htons((uint16_t) opts->keepalive));
if (c->is_mqtt5) mg_send_mqtt_properties(c, opts->props, opts->num_props);
mg_send_u16(c, mg_htons((uint16_t) cid.len));
mg_send(c, cid.ptr, cid.len);
if (hdr[7] & MQTT_HAS_WILL) {
if (c->is_mqtt5)
mg_send_mqtt_properties(c, opts->will_props, opts->num_will_props);
mg_send_u16(c, mg_htons((uint16_t) opts->topic.len));
mg_send(c, opts->topic.ptr, opts->topic.len);
mg_send_u16(c, mg_htons((uint16_t) opts->message.len));
mg_send(c, opts->message.ptr, opts->message.len);
}
if (opts->user.len > 0) {
mg_send_u16(c, mg_htons((uint16_t) opts->user.len));
mg_send(c, opts->user.ptr, opts->user.len);
}
if (opts->pass.len > 0) {
mg_send_u16(c, mg_htons((uint16_t) opts->pass.len));
mg_send(c, opts->pass.ptr, opts->pass.len);
}
}
void mg_mqtt_pub(struct mg_connection *c, const struct mg_mqtt_opts *opts) {
uint8_t flags = (uint8_t) (((opts->qos & 3) << 1) | (opts->retain ? 1 : 0));
size_t len = 2 + opts->topic.len + opts->message.len;
MG_DEBUG(("%lu [%.*s] -> [%.*s]", c->id, (int) opts->topic.len,
(char *) opts->topic.ptr, (int) opts->message.len,
(char *) opts->message.ptr));
if (opts->qos > 0) len += 2;
if (c->is_mqtt5) len += get_props_size(opts->props, opts->num_props);
mg_mqtt_send_header(c, MQTT_CMD_PUBLISH, flags, (uint32_t) len);
mg_send_u16(c, mg_htons((uint16_t) opts->topic.len));
mg_send(c, opts->topic.ptr, opts->topic.len);
if (opts->qos > 0) {
if (++c->mgr->mqtt_id == 0) ++c->mgr->mqtt_id;
mg_send_u16(c, mg_htons(c->mgr->mqtt_id));
}
if (c->is_mqtt5) mg_send_mqtt_properties(c, opts->props, opts->num_props);
if (opts->message.len > 0) mg_send(c, opts->message.ptr, opts->message.len);
}
void mg_mqtt_sub(struct mg_connection *c, const struct mg_mqtt_opts *opts) {
uint8_t qos_ = opts->qos & 3;
size_t plen = c->is_mqtt5 ? get_props_size(opts->props, opts->num_props) : 0;
size_t len = 2 + opts->topic.len + 2 + 1 + plen;
mg_mqtt_send_header(c, MQTT_CMD_SUBSCRIBE, 2, (uint32_t) len);
if (++c->mgr->mqtt_id == 0) ++c->mgr->mqtt_id;
mg_send_u16(c, mg_htons(c->mgr->mqtt_id));
if (c->is_mqtt5) mg_send_mqtt_properties(c, opts->props, opts->num_props);
mg_send_u16(c, mg_htons((uint16_t) opts->topic.len));
mg_send(c, opts->topic.ptr, opts->topic.len);
mg_send(c, &qos_, sizeof(qos_));
}
int mg_mqtt_parse(const uint8_t *buf, size_t len, uint8_t version,
struct mg_mqtt_message *m) {
uint8_t lc = 0, *p, *end;
uint32_t n = 0, len_len = 0;
memset(m, 0, sizeof(*m));
m->dgram.ptr = (char *) buf;
if (len < 2) return MQTT_INCOMPLETE;
m->cmd = (uint8_t) (buf[0] >> 4);
m->qos = (buf[0] >> 1) & 3;
n = len_len = 0;
p = (uint8_t *) buf + 1;
while ((size_t) (p - buf) < len) {
lc = *((uint8_t *) p++);
n += (uint32_t) ((lc & 0x7f) << 7 * len_len);
len_len++;
if (!(lc & 0x80)) break;
if (len_len >= 4) return MQTT_MALFORMED;
}
end = p + n;
if ((lc & 0x80) || (end > buf + len)) return MQTT_INCOMPLETE;
m->dgram.len = (size_t) (end - buf);
switch (m->cmd) {
case MQTT_CMD_CONNACK:
if (end - p < 2) return MQTT_MALFORMED;
m->ack = p[1];
break;
case MQTT_CMD_PUBACK:
case MQTT_CMD_PUBREC:
case MQTT_CMD_PUBREL:
case MQTT_CMD_PUBCOMP:
case MQTT_CMD_SUBSCRIBE:
case MQTT_CMD_SUBACK:
case MQTT_CMD_UNSUBSCRIBE:
case MQTT_CMD_UNSUBACK:
if (p + 2 > end) return MQTT_MALFORMED;
m->id = (uint16_t) ((((uint16_t) p[0]) << 8) | p[1]);
p += 2;
break;
case MQTT_CMD_PUBLISH: {
if (p + 2 > end) return MQTT_MALFORMED;
m->topic.len = (uint16_t) ((((uint16_t) p[0]) << 8) | p[1]);
m->topic.ptr = (char *) p + 2;
p += 2 + m->topic.len;
if (p > end) return MQTT_MALFORMED;
if (m->qos > 0) {
if (p + 2 > end) return MQTT_MALFORMED;
m->id = (uint16_t) ((((uint16_t) p[0]) << 8) | p[1]);
p += 2;
}
if (p > end) return MQTT_MALFORMED;
if (version == 5 && p + 2 < end) {
len_len =
(uint32_t) decode_varint(p, (size_t) (end - p), &m->props_size);
if (!len_len) return MQTT_MALFORMED;
m->props_start = (size_t) (p + len_len - buf);
p += len_len + m->props_size;
}
if (p > end) return MQTT_MALFORMED;
m->data.ptr = (char *) p;
m->data.len = (size_t) (end - p);
break;
}
default:
break;
}
return MQTT_OK;
}
static void mqtt_cb(struct mg_connection *c, int ev, void *ev_data) {
if (ev == MG_EV_READ) {
for (;;) {
uint8_t version = c->is_mqtt5 ? 5 : 4;
struct mg_mqtt_message mm;
int rc = mg_mqtt_parse(c->recv.buf, c->recv.len, version, &mm);
if (rc == MQTT_MALFORMED) {
MG_ERROR(("%lu MQTT malformed message", c->id));
c->is_closing = 1;
break;
} else if (rc == MQTT_OK) {
MG_VERBOSE(("%lu MQTT CMD %d len %d [%.*s]", c->id, mm.cmd,
(int) mm.dgram.len, (int) mm.data.len, mm.data.ptr));
switch (mm.cmd) {
case MQTT_CMD_CONNACK:
mg_call(c, MG_EV_MQTT_OPEN, &mm.ack);
if (mm.ack == 0) {
MG_DEBUG(("%lu Connected", c->id));
} else {
MG_ERROR(("%lu MQTT auth failed, code %d", c->id, mm.ack));
c->is_closing = 1;
}
break;
case MQTT_CMD_PUBLISH: {
/*MG_DEBUG(("%lu [%.*s] -> [%.*s]", c->id, (int) mm.topic.len,
mm.topic.ptr, (int) mm.data.len, mm.data.ptr));*/
if (mm.qos > 0) {
uint16_t id = mg_ntohs(mm.id);
uint32_t remaining_len = sizeof(id);
if (c->is_mqtt5) remaining_len += 2; // 3.4.2
mg_mqtt_send_header(
c,
(uint8_t) (mm.qos == 2 ? MQTT_CMD_PUBREC : MQTT_CMD_PUBACK),
0, remaining_len);
mg_send(c, &id, sizeof(id));
if (c->is_mqtt5) {
uint16_t zero = 0;
mg_send(c, &zero, sizeof(zero));
}
}
mg_call(c, MG_EV_MQTT_MSG, &mm); // let the app handle qos stuff
break;
}
case MQTT_CMD_PUBREC: { // MQTT5: 3.5.2-1 TODO(): variable header rc
uint16_t id = mg_ntohs(mm.id);
uint32_t remaining_len = sizeof(id); // MQTT5 3.6.2-1
mg_mqtt_send_header(c, MQTT_CMD_PUBREL, 2, remaining_len);
mg_send(c, &id, sizeof(id)); // MQTT5 3.6.1-1, flags = 2
break;
}
case MQTT_CMD_PUBREL: { // MQTT5: 3.6.2-1 TODO(): variable header rc
uint16_t id = mg_ntohs(mm.id);
uint32_t remaining_len = sizeof(id); // MQTT5 3.7.2-1
mg_mqtt_send_header(c, MQTT_CMD_PUBCOMP, 0, remaining_len);
mg_send(c, &id, sizeof(id));
break;
}
}
mg_call(c, MG_EV_MQTT_CMD, &mm);
mg_iobuf_del(&c->recv, 0, mm.dgram.len);
} else {
break;
}
}
}
(void) ev_data;
}
void mg_mqtt_ping(struct mg_connection *nc) {
mg_mqtt_send_header(nc, MQTT_CMD_PINGREQ, 0, 0);
}
void mg_mqtt_pong(struct mg_connection *nc) {
mg_mqtt_send_header(nc, MQTT_CMD_PINGRESP, 0, 0);
}
void mg_mqtt_disconnect(struct mg_connection *c,
const struct mg_mqtt_opts *opts) {
size_t len = 0;
if (c->is_mqtt5) len = 1 + get_props_size(opts->props, opts->num_props);
mg_mqtt_send_header(c, MQTT_CMD_DISCONNECT, 0, (uint32_t) len);
if (c->is_mqtt5) {
uint8_t zero = 0;
mg_send(c, &zero, sizeof(zero)); // reason code
mg_send_mqtt_properties(c, opts->props, opts->num_props);
}
}
struct mg_connection *mg_mqtt_connect(struct mg_mgr *mgr, const char *url,
const struct mg_mqtt_opts *opts,
mg_event_handler_t fn, void *fn_data) {
struct mg_connection *c = mg_connect(mgr, url, fn, fn_data);
if (c != NULL) {
struct mg_mqtt_opts empty;
memset(&empty, 0, sizeof(empty));
mg_mqtt_login(c, opts == NULL ? &empty : opts);
c->pfn = mqtt_cb;
}
return c;
}
struct mg_connection *mg_mqtt_listen(struct mg_mgr *mgr, const char *url,
mg_event_handler_t fn, void *fn_data) {
struct mg_connection *c = mg_listen(mgr, url, fn, fn_data);
if (c != NULL) c->pfn = mqtt_cb, c->pfn_data = mgr;
return c;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/net_builtin.c"
#endif
#if defined(MG_ENABLE_TCPIP) && MG_ENABLE_TCPIP
#define MG_EPHEMERAL_PORT_BASE 32768
#define PDIFF(a, b) ((size_t) (((char *) (b)) - ((char *) (a))))
#ifndef MIP_TCP_KEEPALIVE_MS
#define MIP_TCP_KEEPALIVE_MS 45000 // TCP keep-alive period, ms
#endif
#define MIP_TCP_ACK_MS 150 // Timeout for ACKing
#define MIP_TCP_ARP_MS 100 // Timeout for ARP response
#define MIP_TCP_SYN_MS 15000 // Timeout for connection establishment
#define MIP_TCP_FIN_MS 1000 // Timeout for closing connection
struct connstate {
uint32_t seq, ack; // TCP seq/ack counters
uint64_t timer; // TCP keep-alive / ACK timer
uint8_t mac[6]; // Peer MAC address
uint8_t ttype; // Timer type. 0: ack, 1: keep-alive
#define MIP_TTYPE_KEEPALIVE 0 // Connection is idle for long, send keepalive
#define MIP_TTYPE_ACK 1 // Peer sent us data, we have to ack it soon
#define MIP_TTYPE_ARP 2 // ARP resolve sent, waiting for response
#define MIP_TTYPE_SYN 3 // SYN sent, waiting for response
#define MIP_TTYPE_FIN 4 // FIN sent, waiting until terminating the connection
uint8_t tmiss; // Number of keep-alive misses
struct mg_iobuf raw; // For TLS only. Incoming raw data
};
#pragma pack(push, 1)
struct lcp {
uint8_t addr, ctrl, proto[2], code, id, len[2];
};
struct eth {
uint8_t dst[6]; // Destination MAC address
uint8_t src[6]; // Source MAC address
uint16_t type; // Ethernet type
};
struct ip {
uint8_t ver; // Version
uint8_t tos; // Unused
uint16_t len; // Length
uint16_t id; // Unused
uint16_t frag; // Fragmentation
#define IP_FRAG_OFFSET_MSK 0xFF1F
#define IP_MORE_FRAGS_MSK 0x20
uint8_t ttl; // Time to live
uint8_t proto; // Upper level protocol
uint16_t csum; // Checksum
uint32_t src; // Source IP
uint32_t dst; // Destination IP
};
struct ip6 {
uint8_t ver; // Version
uint8_t opts[3]; // Options
uint16_t len; // Length
uint8_t proto; // Upper level protocol
uint8_t ttl; // Time to live
uint8_t src[16]; // Source IP
uint8_t dst[16]; // Destination IP
};
struct icmp {
uint8_t type;
uint8_t code;
uint16_t csum;
};
struct arp {
uint16_t fmt; // Format of hardware address
uint16_t pro; // Format of protocol address
uint8_t hlen; // Length of hardware address
uint8_t plen; // Length of protocol address
uint16_t op; // Operation
uint8_t sha[6]; // Sender hardware address
uint32_t spa; // Sender protocol address
uint8_t tha[6]; // Target hardware address
uint32_t tpa; // Target protocol address
};
struct tcp {
uint16_t sport; // Source port
uint16_t dport; // Destination port
uint32_t seq; // Sequence number
uint32_t ack; // Acknowledgement number
uint8_t off; // Data offset
uint8_t flags; // TCP flags
#define TH_FIN 0x01
#define TH_SYN 0x02
#define TH_RST 0x04
#define TH_PUSH 0x08
#define TH_ACK 0x10
#define TH_URG 0x20
#define TH_ECE 0x40
#define TH_CWR 0x80
uint16_t win; // Window
uint16_t csum; // Checksum
uint16_t urp; // Urgent pointer
};
struct udp {
uint16_t sport; // Source port
uint16_t dport; // Destination port
uint16_t len; // UDP length
uint16_t csum; // UDP checksum
};
struct dhcp {
uint8_t op, htype, hlen, hops;
uint32_t xid;
uint16_t secs, flags;
uint32_t ciaddr, yiaddr, siaddr, giaddr;
uint8_t hwaddr[208];
uint32_t magic;
uint8_t options[32];
};
#pragma pack(pop)
struct pkt {
struct mg_str raw; // Raw packet data
struct mg_str pay; // Payload data
struct eth *eth;
struct llc *llc;
struct arp *arp;
struct ip *ip;
struct ip6 *ip6;
struct icmp *icmp;
struct tcp *tcp;
struct udp *udp;
struct dhcp *dhcp;
};
static void send_syn(struct mg_connection *c);
static void mkpay(struct pkt *pkt, void *p) {
pkt->pay =
mg_str_n((char *) p, (size_t) (&pkt->raw.ptr[pkt->raw.len] - (char *) p));
}
static uint32_t csumup(uint32_t sum, const void *buf, size_t len) {
const uint8_t *p = (const uint8_t *) buf;
for (size_t i = 0; i < len; i++) sum += i & 1 ? p[i] : (uint32_t) (p[i] << 8);
return sum;
}
static uint16_t csumfin(uint32_t sum) {
while (sum >> 16) sum = (sum & 0xffff) + (sum >> 16);
return mg_htons(~sum & 0xffff);
}
static uint16_t ipcsum(const void *buf, size_t len) {
uint32_t sum = csumup(0, buf, len);
return csumfin(sum);
}
static void settmout(struct mg_connection *c, uint8_t type) {
struct mg_tcpip_if *ifp = (struct mg_tcpip_if *) c->mgr->priv;
struct connstate *s = (struct connstate *) (c + 1);
unsigned n = type == MIP_TTYPE_ACK ? MIP_TCP_ACK_MS
: type == MIP_TTYPE_ARP ? MIP_TCP_ARP_MS
: type == MIP_TTYPE_SYN ? MIP_TCP_SYN_MS
: type == MIP_TTYPE_FIN ? MIP_TCP_FIN_MS
: MIP_TCP_KEEPALIVE_MS;
s->timer = ifp->now + n;
s->ttype = type;
MG_VERBOSE(("%lu %d -> %llx", c->id, type, s->timer));
}
static size_t ether_output(struct mg_tcpip_if *ifp, size_t len) {
size_t n = ifp->driver->tx(ifp->tx.ptr, len, ifp);
if (n == len) ifp->nsent++;
return n;
}
static void arp_ask(struct mg_tcpip_if *ifp, uint32_t ip) {
struct eth *eth = (struct eth *) ifp->tx.ptr;
struct arp *arp = (struct arp *) (eth + 1);
memset(eth->dst, 255, sizeof(eth->dst));
memcpy(eth->src, ifp->mac, sizeof(eth->src));
eth->type = mg_htons(0x806);
memset(arp, 0, sizeof(*arp));
arp->fmt = mg_htons(1), arp->pro = mg_htons(0x800), arp->hlen = 6,
arp->plen = 4;
arp->op = mg_htons(1), arp->tpa = ip, arp->spa = ifp->ip;
memcpy(arp->sha, ifp->mac, sizeof(arp->sha));
ether_output(ifp, PDIFF(eth, arp + 1));
}
static void onstatechange(struct mg_tcpip_if *ifp) {
if (ifp->state == MG_TCPIP_STATE_READY) {
MG_INFO(("READY, IP: %M", mg_print_ip4, &ifp->ip));
MG_INFO((" GW: %M", mg_print_ip4, &ifp->gw));
MG_INFO((" MAC: %M", mg_print_mac, &ifp->mac));
arp_ask(ifp, ifp->gw);
} else if (ifp->state == MG_TCPIP_STATE_UP) {
MG_ERROR(("Link up"));
srand((unsigned int) mg_millis());
} else if (ifp->state == MG_TCPIP_STATE_DOWN) {
MG_ERROR(("Link down"));
}
}
static struct ip *tx_ip(struct mg_tcpip_if *ifp, uint8_t *mac_dst,
uint8_t proto, uint32_t ip_src, uint32_t ip_dst,
size_t plen) {
struct eth *eth = (struct eth *) ifp->tx.ptr;
struct ip *ip = (struct ip *) (eth + 1);
memcpy(eth->dst, mac_dst, sizeof(eth->dst));
memcpy(eth->src, ifp->mac, sizeof(eth->src)); // Use our MAC
eth->type = mg_htons(0x800);
memset(ip, 0, sizeof(*ip));
ip->ver = 0x45; // Version 4, header length 5 words
ip->frag = 0x40; // Don't fragment
ip->len = mg_htons((uint16_t) (sizeof(*ip) + plen));
ip->ttl = 64;
ip->proto = proto;
ip->src = ip_src;
ip->dst = ip_dst;
ip->csum = ipcsum(ip, sizeof(*ip));
return ip;
}
static void tx_udp(struct mg_tcpip_if *ifp, uint8_t *mac_dst, uint32_t ip_src,
uint16_t sport, uint32_t ip_dst, uint16_t dport,
const void *buf, size_t len) {
struct ip *ip =
tx_ip(ifp, mac_dst, 17, ip_src, ip_dst, len + sizeof(struct udp));
struct udp *udp = (struct udp *) (ip + 1);
// MG_DEBUG(("UDP XX LEN %d %d", (int) len, (int) ifp->tx.len));
udp->sport = sport;
udp->dport = dport;
udp->len = mg_htons((uint16_t) (sizeof(*udp) + len));
udp->csum = 0;
uint32_t cs = csumup(0, udp, sizeof(*udp));
cs = csumup(cs, buf, len);
cs = csumup(cs, &ip->src, sizeof(ip->src));
cs = csumup(cs, &ip->dst, sizeof(ip->dst));
cs += (uint32_t) (ip->proto + sizeof(*udp) + len);
udp->csum = csumfin(cs);
memmove(udp + 1, buf, len);
// MG_DEBUG(("UDP LEN %d %d", (int) len, (int) ifp->frame_len));
ether_output(ifp, sizeof(struct eth) + sizeof(*ip) + sizeof(*udp) + len);
}
static void tx_dhcp(struct mg_tcpip_if *ifp, uint8_t *mac_dst, uint32_t ip_src,
uint32_t ip_dst, uint8_t *opts, size_t optslen,
bool ciaddr) {
// https://datatracker.ietf.org/doc/html/rfc2132#section-9.6
struct dhcp dhcp = {1, 1, 6, 0, 0, 0, 0, 0, 0, 0, 0, {0}, 0, {0}};
dhcp.magic = mg_htonl(0x63825363);
memcpy(&dhcp.hwaddr, ifp->mac, sizeof(ifp->mac));
memcpy(&dhcp.xid, ifp->mac + 2, sizeof(dhcp.xid));
memcpy(&dhcp.options, opts, optslen);
if (ciaddr) dhcp.ciaddr = ip_src;
tx_udp(ifp, mac_dst, ip_src, mg_htons(68), ip_dst, mg_htons(67), &dhcp,
sizeof(dhcp));
}
static const uint8_t broadcast[] = {255, 255, 255, 255, 255, 255};
// RFC-2131 #4.3.6, #4.4.1
static void tx_dhcp_request_sel(struct mg_tcpip_if *ifp, uint32_t ip_req,
uint32_t ip_srv) {
uint8_t opts[] = {
53, 1, 3, // Type: DHCP request
55, 2, 1, 3, // GW and mask
12, 3, 'm', 'i', 'p', // Host name: "mip"
54, 4, 0, 0, 0, 0, // DHCP server ID
50, 4, 0, 0, 0, 0, // Requested IP
255 // End of options
};
memcpy(opts + 14, &ip_srv, sizeof(ip_srv));
memcpy(opts + 20, &ip_req, sizeof(ip_req));
tx_dhcp(ifp, (uint8_t *) broadcast, 0, 0xffffffff, opts, sizeof(opts), false);
MG_DEBUG(("DHCP req sent"));
}
// RFC-2131 #4.3.6, #4.4.5 (renewing: unicast, rebinding: bcast)
static void tx_dhcp_request_re(struct mg_tcpip_if *ifp, uint8_t *mac_dst,
uint32_t ip_src, uint32_t ip_dst) {
uint8_t opts[] = {
53, 1, 3, // Type: DHCP request
255 // End of options
};
tx_dhcp(ifp, mac_dst, ip_src, ip_dst, opts, sizeof(opts), true);
MG_DEBUG(("DHCP req sent"));
}
static void tx_dhcp_discover(struct mg_tcpip_if *ifp) {
uint8_t opts[] = {
53, 1, 1, // Type: DHCP discover
55, 2, 1, 3, // Parameters: ip, mask
255 // End of options
};
tx_dhcp(ifp, (uint8_t *) broadcast, 0, 0xffffffff, opts, sizeof(opts), false);
MG_DEBUG(("DHCP discover sent. Our MAC: %M", mg_print_mac, ifp->mac));
}
static struct mg_connection *getpeer(struct mg_mgr *mgr, struct pkt *pkt,
bool lsn) {
struct mg_connection *c = NULL;
for (c = mgr->conns; c != NULL; c = c->next) {
if (c->is_arplooking && pkt->arp &&
memcmp(&pkt->arp->spa, c->rem.ip, sizeof(pkt->arp->spa)) == 0)
break;
if (c->is_udp && pkt->udp && c->loc.port == pkt->udp->dport) break;
if (!c->is_udp && pkt->tcp && c->loc.port == pkt->tcp->dport &&
lsn == c->is_listening && (lsn || c->rem.port == pkt->tcp->sport))
break;
}
return c;
}
static void rx_arp(struct mg_tcpip_if *ifp, struct pkt *pkt) {
if (pkt->arp->op == mg_htons(1) && pkt->arp->tpa == ifp->ip) {
// ARP request. Make a response, then send
// MG_DEBUG(("ARP op %d %M: %M", mg_ntohs(pkt->arp->op), mg_print_ip4,
// &pkt->arp->spa, mg_print_ip4, &pkt->arp->tpa));
struct eth *eth = (struct eth *) ifp->tx.ptr;
struct arp *arp = (struct arp *) (eth + 1);
memcpy(eth->dst, pkt->eth->src, sizeof(eth->dst));
memcpy(eth->src, ifp->mac, sizeof(eth->src));
eth->type = mg_htons(0x806);
*arp = *pkt->arp;
arp->op = mg_htons(2);
memcpy(arp->tha, pkt->arp->sha, sizeof(pkt->arp->tha));
memcpy(arp->sha, ifp->mac, sizeof(pkt->arp->sha));
arp->tpa = pkt->arp->spa;
arp->spa = ifp->ip;
MG_DEBUG(("ARP: tell %M we're %M", mg_print_ip4, &arp->tpa, mg_print_mac,
&ifp->mac));
ether_output(ifp, PDIFF(eth, arp + 1));
} else if (pkt->arp->op == mg_htons(2)) {
if (memcmp(pkt->arp->tha, ifp->mac, sizeof(pkt->arp->tha)) != 0) return;
if (pkt->arp->spa == ifp->gw) {
// Got response for the GW ARP request. Set ifp->gwmac
memcpy(ifp->gwmac, pkt->arp->sha, sizeof(ifp->gwmac));
} else {
struct mg_connection *c = getpeer(ifp->mgr, pkt, false);
if (c != NULL && c->is_arplooking) {
struct connstate *s = (struct connstate *) (c + 1);
memcpy(s->mac, pkt->arp->sha, sizeof(s->mac));
MG_DEBUG(("%lu ARP resolved %M -> %M", c->id, mg_print_ip4, c->rem.ip,
mg_print_mac, s->mac));
c->is_arplooking = 0;
send_syn(c);
settmout(c, MIP_TTYPE_SYN);
}
}
}
}
static void rx_icmp(struct mg_tcpip_if *ifp, struct pkt *pkt) {
// MG_DEBUG(("ICMP %d", (int) len));
if (pkt->icmp->type == 8 && pkt->ip != NULL && pkt->ip->dst == ifp->ip) {
size_t hlen = sizeof(struct eth) + sizeof(struct ip) + sizeof(struct icmp);
size_t space = ifp->tx.len - hlen, plen = pkt->pay.len;
if (plen > space) plen = space;
struct ip *ip = tx_ip(ifp, pkt->eth->src, 1, ifp->ip, pkt->ip->src,
sizeof(struct icmp) + plen);
struct icmp *icmp = (struct icmp *) (ip + 1);
memset(icmp, 0, sizeof(*icmp)); // Set csum to 0
memcpy(icmp + 1, pkt->pay.ptr, plen); // Copy RX payload to TX
icmp->csum = ipcsum(icmp, sizeof(*icmp) + plen);
ether_output(ifp, hlen + plen);
}
}
static void rx_dhcp_client(struct mg_tcpip_if *ifp, struct pkt *pkt) {
uint32_t ip = 0, gw = 0, mask = 0, lease = 0;
uint8_t msgtype = 0, state = ifp->state;
// perform size check first, then access fields
uint8_t *p = pkt->dhcp->options,
*end = (uint8_t *) &pkt->raw.ptr[pkt->raw.len];
if (end < (uint8_t *) (pkt->dhcp + 1)) return;
if (memcmp(&pkt->dhcp->xid, ifp->mac + 2, sizeof(pkt->dhcp->xid))) return;
while (p + 1 < end && p[0] != 255) { // Parse options RFC-1533 #9
if (p[0] == 1 && p[1] == sizeof(ifp->mask) && p + 6 < end) { // Mask
memcpy(&mask, p + 2, sizeof(mask));
} else if (p[0] == 3 && p[1] == sizeof(ifp->gw) && p + 6 < end) { // GW
memcpy(&gw, p + 2, sizeof(gw));
ip = pkt->dhcp->yiaddr;
} else if (p[0] == 51 && p[1] == 4 && p + 6 < end) { // Lease
memcpy(&lease, p + 2, sizeof(lease));
lease = mg_ntohl(lease);
} else if (p[0] == 53 && p[1] == 1 && p + 6 < end) { // Msg Type
msgtype = p[2];
}
p += p[1] + 2;
}
// Process message type, RFC-1533 (9.4); RFC-2131 (3.1, 4)
if (msgtype == 6 && ifp->ip == ip) { // DHCPNACK, release IP
ifp->state = MG_TCPIP_STATE_UP, ifp->ip = 0;
} else if (msgtype == 2 && ifp->state == MG_TCPIP_STATE_UP && ip && gw &&
lease) { // DHCPOFFER
// select IP, (4.4.1) (fallback to IP source addr on foul play)
tx_dhcp_request_sel(ifp, ip, pkt->dhcp->siaddr ? pkt->dhcp->siaddr : pkt->ip->src);
ifp->state = MG_TCPIP_STATE_REQ; // REQUESTING state
} else if (msgtype == 5) { // DHCPACK
if (ifp->state == MG_TCPIP_STATE_REQ && ip && gw && lease) { // got an IP
ifp->lease_expire = ifp->now + lease * 1000;
MG_INFO(("Lease: %u sec (%lld)", lease, ifp->lease_expire / 1000));
// assume DHCP server = router until ARP resolves
memcpy(ifp->gwmac, pkt->eth->src, sizeof(ifp->gwmac));
ifp->ip = ip, ifp->gw = gw, ifp->mask = mask;
ifp->state = MG_TCPIP_STATE_READY; // BOUND state
uint64_t rand;
mg_random(&rand, sizeof(rand));
srand((unsigned int) (rand + mg_millis()));
} else if (ifp->state == MG_TCPIP_STATE_READY && ifp->ip == ip) { // renew
ifp->lease_expire = ifp->now + lease * 1000;
MG_INFO(("Lease: %u sec (%lld)", lease, ifp->lease_expire / 1000));
} // TODO(): accept provided T1/T2 and store server IP for renewal (4.4)
}
if (ifp->state != state) onstatechange(ifp);
}
// Simple DHCP server that assigns a next IP address: ifp->ip + 1
static void rx_dhcp_server(struct mg_tcpip_if *ifp, struct pkt *pkt) {
uint8_t op = 0, *p = pkt->dhcp->options,
*end = (uint8_t *) &pkt->raw.ptr[pkt->raw.len];
if (end < (uint8_t *) (pkt->dhcp + 1)) return;
// struct dhcp *req = pkt->dhcp;
struct dhcp res = {2, 1, 6, 0, 0, 0, 0, 0, 0, 0, 0, {0}, 0, {0}};
res.yiaddr = ifp->ip;
((uint8_t *) (&res.yiaddr))[3]++; // Offer our IP + 1
while (p + 1 < end && p[0] != 255) { // Parse options
if (p[0] == 53 && p[1] == 1 && p + 2 < end) { // Message type
op = p[2];
}
p += p[1] + 2;
}
if (op == 1 || op == 3) { // DHCP Discover or DHCP Request
uint8_t msg = op == 1 ? 2 : 5; // Message type: DHCP OFFER or DHCP ACK
uint8_t opts[] = {
53, 1, msg, // Message type
1, 4, 0, 0, 0, 0, // Subnet mask
54, 4, 0, 0, 0, 0, // Server ID
12, 3, 'm', 'i', 'p', // Host name: "mip"
51, 4, 255, 255, 255, 255, // Lease time
255 // End of options
};
memcpy(&res.hwaddr, pkt->dhcp->hwaddr, 6);
memcpy(opts + 5, &ifp->mask, sizeof(ifp->mask));
memcpy(opts + 11, &ifp->ip, sizeof(ifp->ip));
memcpy(&res.options, opts, sizeof(opts));
res.magic = pkt->dhcp->magic;
res.xid = pkt->dhcp->xid;
if (ifp->enable_get_gateway) {
ifp->gw = res.yiaddr;
memcpy(ifp->gwmac, pkt->eth->src, sizeof(ifp->gwmac));
}
tx_udp(ifp, pkt->eth->src, ifp->ip, mg_htons(67),
op == 1 ? ~0U : res.yiaddr, mg_htons(68), &res, sizeof(res));
}
}
static void rx_udp(struct mg_tcpip_if *ifp, struct pkt *pkt) {
struct mg_connection *c = getpeer(ifp->mgr, pkt, true);
if (c == NULL) {
// No UDP listener on this port. Should send ICMP, but keep silent.
} else {
c->rem.port = pkt->udp->sport;
memcpy(c->rem.ip, &pkt->ip->src, sizeof(uint32_t));
struct connstate *s = (struct connstate *) (c + 1);
memcpy(s->mac, pkt->eth->src, sizeof(s->mac));
if (c->recv.len >= MG_MAX_RECV_SIZE) {
mg_error(c, "max_recv_buf_size reached");
} else if (c->recv.size - c->recv.len < pkt->pay.len &&
!mg_iobuf_resize(&c->recv, c->recv.len + pkt->pay.len)) {
mg_error(c, "oom");
} else {
memcpy(&c->recv.buf[c->recv.len], pkt->pay.ptr, pkt->pay.len);
c->recv.len += pkt->pay.len;
mg_call(c, MG_EV_READ, &pkt->pay.len);
}
}
}
static size_t tx_tcp(struct mg_tcpip_if *ifp, uint8_t *dst_mac, uint32_t dst_ip,
uint8_t flags, uint16_t sport, uint16_t dport,
uint32_t seq, uint32_t ack, const void *buf, size_t len) {
struct ip *ip =
tx_ip(ifp, dst_mac, 6, ifp->ip, dst_ip, sizeof(struct tcp) + len);
struct tcp *tcp = (struct tcp *) (ip + 1);
memset(tcp, 0, sizeof(*tcp));
if (buf != NULL && len) memmove(tcp + 1, buf, len);
tcp->sport = sport;
tcp->dport = dport;
tcp->seq = seq;
tcp->ack = ack;
tcp->flags = flags;
tcp->win = mg_htons(8192);
tcp->off = (uint8_t) (sizeof(*tcp) / 4 << 4);
uint32_t cs = 0;
uint16_t n = (uint16_t) (sizeof(*tcp) + len);
uint8_t pseudo[] = {0, ip->proto, (uint8_t) (n >> 8), (uint8_t) (n & 255)};
cs = csumup(cs, tcp, n);
cs = csumup(cs, &ip->src, sizeof(ip->src));
cs = csumup(cs, &ip->dst, sizeof(ip->dst));
cs = csumup(cs, pseudo, sizeof(pseudo));
tcp->csum = csumfin(cs);
MG_VERBOSE(("TCP %M:%hu -> %M:%hu fl %x len %u", mg_print_ip4, &ip->src,
mg_ntohs(tcp->sport), mg_print_ip4, &ip->dst,
mg_ntohs(tcp->dport), tcp->flags, (int) len));
// mg_hexdump(ifp->tx.ptr, PDIFF(ifp->tx.ptr, tcp + 1) + len);
return ether_output(ifp, PDIFF(ifp->tx.ptr, tcp + 1) + len);
}
static size_t tx_tcp_pkt(struct mg_tcpip_if *ifp, struct pkt *pkt,
uint8_t flags, uint32_t seq, const void *buf,
size_t len) {
uint32_t delta = (pkt->tcp->flags & (TH_SYN | TH_FIN)) ? 1 : 0;
return tx_tcp(ifp, pkt->eth->src, pkt->ip->src, flags, pkt->tcp->dport,
pkt->tcp->sport, seq, mg_htonl(mg_ntohl(pkt->tcp->seq) + delta),
buf, len);
}
static struct mg_connection *accept_conn(struct mg_connection *lsn,
struct pkt *pkt) {
struct mg_connection *c = mg_alloc_conn(lsn->mgr);
if (c == NULL) {
MG_ERROR(("OOM"));
return NULL;
}
struct connstate *s = (struct connstate *) (c + 1);
s->seq = mg_ntohl(pkt->tcp->ack), s->ack = mg_ntohl(pkt->tcp->seq);
memcpy(s->mac, pkt->eth->src, sizeof(s->mac));
settmout(c, MIP_TTYPE_KEEPALIVE);
memcpy(c->rem.ip, &pkt->ip->src, sizeof(uint32_t));
c->rem.port = pkt->tcp->sport;
MG_DEBUG(("%lu accepted %M", c->id, mg_print_ip_port, &c->rem));
LIST_ADD_HEAD(struct mg_connection, &lsn->mgr->conns, c);
c->is_accepted = 1;
c->is_hexdumping = lsn->is_hexdumping;
c->pfn = lsn->pfn;
c->loc = lsn->loc;
c->pfn_data = lsn->pfn_data;
c->fn = lsn->fn;
c->fn_data = lsn->fn_data;
mg_call(c, MG_EV_OPEN, NULL);
mg_call(c, MG_EV_ACCEPT, NULL);
return c;
}
static size_t trim_len(struct mg_connection *c, size_t len) {
struct mg_tcpip_if *ifp = (struct mg_tcpip_if *) c->mgr->priv;
size_t eth_h_len = 14, ip_max_h_len = 24, tcp_max_h_len = 60, udp_h_len = 8;
size_t max_headers_len =
eth_h_len + ip_max_h_len + (c->is_udp ? udp_h_len : tcp_max_h_len);
size_t min_mtu = c->is_udp ? 68 /* RFC-791 */ : max_headers_len - eth_h_len;
// If the frame exceeds the available buffer, trim the length
if (len + max_headers_len > ifp->tx.len) {
len = ifp->tx.len - max_headers_len;
}
// Ensure the MTU isn't lower than the minimum allowed value
if (ifp->mtu < min_mtu) {
MG_ERROR(("MTU is lower than minimum, capping to %lu", min_mtu));
ifp->mtu = (uint16_t) min_mtu;
}
// If the total packet size exceeds the MTU, trim the length
if (len + max_headers_len - eth_h_len > ifp->mtu) {
len = ifp->mtu - max_headers_len + eth_h_len;
if (c->is_udp) {
MG_ERROR(("UDP datagram exceeds MTU. Truncating it."));
}
}
return len;
}
long mg_io_send(struct mg_connection *c, const void *buf, size_t len) {
struct mg_tcpip_if *ifp = (struct mg_tcpip_if *) c->mgr->priv;
struct connstate *s = (struct connstate *) (c + 1);
uint32_t dst_ip = *(uint32_t *) c->rem.ip;
len = trim_len(c, len);
if (c->is_udp) {
tx_udp(ifp, s->mac, ifp->ip, c->loc.port, dst_ip, c->rem.port, buf, len);
} else {
size_t sent =
tx_tcp(ifp, s->mac, dst_ip, TH_PUSH | TH_ACK, c->loc.port, c->rem.port,
mg_htonl(s->seq), mg_htonl(s->ack), buf, len);
if (sent == 0) {
return MG_IO_WAIT;
} else if (sent == (size_t) -1) {
return MG_IO_ERR;
} else {
s->seq += (uint32_t) len;
if (s->ttype == MIP_TTYPE_ACK) settmout(c, MIP_TTYPE_KEEPALIVE);
}
}
return (long) len;
}
static void read_conn(struct mg_connection *c, struct pkt *pkt) {
struct connstate *s = (struct connstate *) (c + 1);
struct mg_iobuf *io = c->is_tls ? &c->rtls : &c->recv;
uint32_t seq = mg_ntohl(pkt->tcp->seq);
uint32_t rem_ip;
memcpy(&rem_ip, c->rem.ip, sizeof(uint32_t));
if (pkt->tcp->flags & TH_FIN) {
// If we initiated the closure, we reply with ACK upon receiving FIN
// If we didn't initiate it, we reply with FIN as part of the normal TCP
// closure process
uint8_t flags = TH_ACK;
s->ack = (uint32_t) (mg_htonl(pkt->tcp->seq) + pkt->pay.len + 1);
if (c->is_draining && s->ttype == MIP_TTYPE_FIN) {
if (s->seq == mg_htonl(pkt->tcp->ack)) { // Simultaneous closure ?
s->seq++; // Yes. Increment our SEQ
} else { // Otherwise,
s->seq = mg_htonl(pkt->tcp->ack); // Set to peer's ACK
}
} else {
flags |= TH_FIN;
c->is_draining = 1;
settmout(c, MIP_TTYPE_FIN);
}
tx_tcp((struct mg_tcpip_if *) c->mgr->priv, s->mac, rem_ip, flags,
c->loc.port, c->rem.port, mg_htonl(s->seq), mg_htonl(s->ack), "", 0);
} else if (pkt->pay.len == 0) {
// TODO(cpq): handle this peer's ACK
} else if (seq != s->ack) {
uint32_t ack = (uint32_t) (mg_htonl(pkt->tcp->seq) + pkt->pay.len);
if (s->ack == ack) {
MG_VERBOSE(("ignoring duplicate pkt"));
} else {
MG_VERBOSE(("SEQ != ACK: %x %x %x", seq, s->ack, ack));
tx_tcp((struct mg_tcpip_if *) c->mgr->priv, s->mac, rem_ip, TH_ACK,
c->loc.port, c->rem.port, mg_htonl(s->seq), mg_htonl(s->ack), "",
0);
}
} else if (io->size - io->len < pkt->pay.len &&
!mg_iobuf_resize(io, io->len + pkt->pay.len)) {
mg_error(c, "oom");
} else {
// Copy TCP payload into the IO buffer. If the connection is plain text,
// we copy to c->recv. If the connection is TLS, this data is encrypted,
// therefore we copy that encrypted data to the c->rtls iobuffer instead,
// and then call mg_tls_recv() to decrypt it. NOTE: mg_tls_recv() will
// call back mg_io_recv() which grabs raw data from c->rtls
memcpy(&io->buf[io->len], pkt->pay.ptr, pkt->pay.len);
io->len += pkt->pay.len;
MG_VERBOSE(("%lu SEQ %x -> %x", c->id, mg_htonl(pkt->tcp->seq), s->ack));
// Advance ACK counter
s->ack = (uint32_t) (mg_htonl(pkt->tcp->seq) + pkt->pay.len);
#if 0
// Send ACK immediately
uint32_t rem_ip;
memcpy(&rem_ip, c->rem.ip, sizeof(uint32_t));
MG_DEBUG((" imm ACK", c->id, mg_htonl(pkt->tcp->seq), s->ack));
tx_tcp((struct mg_tcpip_if *) c->mgr->priv, s->mac, rem_ip, TH_ACK, c->loc.port,
c->rem.port, mg_htonl(s->seq), mg_htonl(s->ack), "", 0);
#else
// if not already running, setup a timer to send an ACK later
if (s->ttype != MIP_TTYPE_ACK) settmout(c, MIP_TTYPE_ACK);
#endif
if (c->is_tls && c->is_tls_hs) {
mg_tls_handshake(c);
} else if (c->is_tls) {
// TLS connection. Make room for decrypted data in c->recv
io = &c->recv;
if (io->size - io->len < pkt->pay.len &&
!mg_iobuf_resize(io, io->len + pkt->pay.len)) {
mg_error(c, "oom");
} else {
// Decrypt data directly into c->recv
long n = mg_tls_recv(c, &io->buf[io->len], io->size - io->len);
if (n == MG_IO_ERR) {
mg_error(c, "TLS recv error");
} else if (n > 0) {
// Decrypted successfully - trigger MG_EV_READ
io->len += (size_t) n;
mg_call(c, MG_EV_READ, &n);
}
}
} else {
// Plain text connection, data is already in c->recv, trigger
// MG_EV_READ
mg_call(c, MG_EV_READ, &pkt->pay.len);
}
}
}
static void rx_tcp(struct mg_tcpip_if *ifp, struct pkt *pkt) {
struct mg_connection *c = getpeer(ifp->mgr, pkt, false);
struct connstate *s = c == NULL ? NULL : (struct connstate *) (c + 1);
#if 0
MG_INFO(("%lu %hhu %d", c ? c->id : 0, pkt->tcp->flags, (int) pkt->pay.len));
#endif
if (c != NULL && c->is_connecting && pkt->tcp->flags == (TH_SYN | TH_ACK)) {
s->seq = mg_ntohl(pkt->tcp->ack), s->ack = mg_ntohl(pkt->tcp->seq) + 1;
tx_tcp_pkt(ifp, pkt, TH_ACK, pkt->tcp->ack, NULL, 0);
c->is_connecting = 0; // Client connected
settmout(c, MIP_TTYPE_KEEPALIVE);
mg_call(c, MG_EV_CONNECT, NULL); // Let user know
} else if (c != NULL && c->is_connecting && pkt->tcp->flags != TH_ACK) {
// mg_hexdump(pkt->raw.ptr, pkt->raw.len);
tx_tcp_pkt(ifp, pkt, TH_RST | TH_ACK, pkt->tcp->ack, NULL, 0);
} else if (c != NULL && pkt->tcp->flags & TH_RST) {
mg_error(c, "peer RST"); // RFC-1122 4.2.2.13
} else if (c != NULL) {
#if 0
MG_DEBUG(("%lu %d %M:%hu -> %M:%hu", c->id, (int) pkt->raw.len,
mg_print_ip4, &pkt->ip->src, mg_ntohs(pkt->tcp->sport),
mg_print_ip4, &pkt->ip->dst, mg_ntohs(pkt->tcp->dport)));
mg_hexdump(pkt->pay.ptr, pkt->pay.len);
#endif
s->tmiss = 0; // Reset missed keep-alive counter
if (s->ttype == MIP_TTYPE_KEEPALIVE) // Advance keep-alive timer
settmout(c,
MIP_TTYPE_KEEPALIVE); // unless a former ACK timeout is pending
read_conn(c, pkt); // Override timer with ACK timeout if needed
} else if ((c = getpeer(ifp->mgr, pkt, true)) == NULL) {
tx_tcp_pkt(ifp, pkt, TH_RST | TH_ACK, pkt->tcp->ack, NULL, 0);
} else if (pkt->tcp->flags & TH_RST) {
if (c->is_accepted) mg_error(c, "peer RST"); // RFC-1122 4.2.2.13
// ignore RST if not connected
} else if (pkt->tcp->flags & TH_SYN) {
// Use peer's source port as ISN, in order to recognise the handshake
uint32_t isn = mg_htonl((uint32_t) mg_ntohs(pkt->tcp->sport));
tx_tcp_pkt(ifp, pkt, TH_SYN | TH_ACK, isn, NULL, 0);
} else if (pkt->tcp->flags & TH_FIN) {
tx_tcp_pkt(ifp, pkt, TH_FIN | TH_ACK, pkt->tcp->ack, NULL, 0);
} else if (mg_htonl(pkt->tcp->ack) == mg_htons(pkt->tcp->sport) + 1U) {
accept_conn(c, pkt);
} else if (!c->is_accepted) { // no peer
tx_tcp_pkt(ifp, pkt, TH_RST | TH_ACK, pkt->tcp->ack, NULL, 0);
} else {
// MG_VERBOSE(("dropped silently.."));
}
}
static void rx_ip(struct mg_tcpip_if *ifp, struct pkt *pkt) {
if (pkt->ip->frag & IP_MORE_FRAGS_MSK || pkt->ip->frag & IP_FRAG_OFFSET_MSK) {
if (pkt->ip->proto == 17) pkt->udp = (struct udp *) (pkt->ip + 1);
if (pkt->ip->proto == 6) pkt->tcp = (struct tcp *) (pkt->ip + 1);
struct mg_connection *c = getpeer(ifp->mgr, pkt, false);
if (c) mg_error(c, "Received fragmented packet");
} else if (pkt->ip->proto == 1) {
pkt->icmp = (struct icmp *) (pkt->ip + 1);
if (pkt->pay.len < sizeof(*pkt->icmp)) return;
mkpay(pkt, pkt->icmp + 1);
rx_icmp(ifp, pkt);
} else if (pkt->ip->proto == 17) {
pkt->udp = (struct udp *) (pkt->ip + 1);
if (pkt->pay.len < sizeof(*pkt->udp)) return;
mkpay(pkt, pkt->udp + 1);
MG_VERBOSE(("UDP %M:%hu -> %M:%hu len %u", mg_print_ip4, &pkt->ip->src,
mg_ntohs(pkt->udp->sport), mg_print_ip4, &pkt->ip->dst,
mg_ntohs(pkt->udp->dport), (int) pkt->pay.len));
if (ifp->enable_dhcp_client && pkt->udp->dport == mg_htons(68)) {
pkt->dhcp = (struct dhcp *) (pkt->udp + 1);
mkpay(pkt, pkt->dhcp + 1);
rx_dhcp_client(ifp, pkt);
} else if (ifp->enable_dhcp_server && pkt->udp->dport == mg_htons(67)) {
pkt->dhcp = (struct dhcp *) (pkt->udp + 1);
mkpay(pkt, pkt->dhcp + 1);
rx_dhcp_server(ifp, pkt);
} else {
rx_udp(ifp, pkt);
}
} else if (pkt->ip->proto == 6) {
pkt->tcp = (struct tcp *) (pkt->ip + 1);
if (pkt->pay.len < sizeof(*pkt->tcp)) return;
mkpay(pkt, pkt->tcp + 1);
uint16_t iplen = mg_ntohs(pkt->ip->len);
uint16_t off = (uint16_t) (sizeof(*pkt->ip) + ((pkt->tcp->off >> 4) * 4U));
if (iplen >= off) pkt->pay.len = (size_t) (iplen - off);
MG_VERBOSE(("TCP %M:%hu -> %M:%hu len %u", mg_print_ip4, &pkt->ip->src,
mg_ntohs(pkt->tcp->sport), mg_print_ip4, &pkt->ip->dst,
mg_ntohs(pkt->tcp->dport), (int) pkt->pay.len));
rx_tcp(ifp, pkt);
}
}
static void rx_ip6(struct mg_tcpip_if *ifp, struct pkt *pkt) {
// MG_DEBUG(("IP %d", (int) len));
if (pkt->ip6->proto == 1 || pkt->ip6->proto == 58) {
pkt->icmp = (struct icmp *) (pkt->ip6 + 1);
if (pkt->pay.len < sizeof(*pkt->icmp)) return;
mkpay(pkt, pkt->icmp + 1);
rx_icmp(ifp, pkt);
} else if (pkt->ip6->proto == 17) {
pkt->udp = (struct udp *) (pkt->ip6 + 1);
if (pkt->pay.len < sizeof(*pkt->udp)) return;
// MG_DEBUG((" UDP %u %u -> %u", len, mg_htons(udp->sport),
// mg_htons(udp->dport)));
mkpay(pkt, pkt->udp + 1);
}
}
static void mg_tcpip_rx(struct mg_tcpip_if *ifp, void *buf, size_t len) {
struct pkt pkt;
memset(&pkt, 0, sizeof(pkt));
pkt.raw.ptr = (char *) buf;
pkt.raw.len = len;
pkt.eth = (struct eth *) buf;
// mg_hexdump(buf, len > 16 ? 16: len);
if (pkt.raw.len < sizeof(*pkt.eth)) return; // Truncated - runt?
if (ifp->enable_mac_check &&
memcmp(pkt.eth->dst, ifp->mac, sizeof(pkt.eth->dst)) != 0 &&
memcmp(pkt.eth->dst, broadcast, sizeof(pkt.eth->dst)) != 0)
return;
if (ifp->enable_crc32_check && len > 4) {
len -= 4; // TODO(scaprile): check on bigendian
uint32_t crc = mg_crc32(0, (const char *) buf, len);
if (memcmp((void *) ((size_t) buf + len), &crc, sizeof(crc))) return;
}
if (pkt.eth->type == mg_htons(0x806)) {
pkt.arp = (struct arp *) (pkt.eth + 1);
if (sizeof(*pkt.eth) + sizeof(*pkt.arp) > pkt.raw.len) return; // Truncated
rx_arp(ifp, &pkt);
} else if (pkt.eth->type == mg_htons(0x86dd)) {
pkt.ip6 = (struct ip6 *) (pkt.eth + 1);
if (pkt.raw.len < sizeof(*pkt.eth) + sizeof(*pkt.ip6)) return; // Truncated
if ((pkt.ip6->ver >> 4) != 0x6) return; // Not IP
mkpay(&pkt, pkt.ip6 + 1);
rx_ip6(ifp, &pkt);
} else if (pkt.eth->type == mg_htons(0x800)) {
pkt.ip = (struct ip *) (pkt.eth + 1);
if (pkt.raw.len < sizeof(*pkt.eth) + sizeof(*pkt.ip)) return; // Truncated
// Truncate frame to what IP header tells us
if ((size_t) mg_ntohs(pkt.ip->len) + sizeof(struct eth) < pkt.raw.len) {
pkt.raw.len = (size_t) mg_ntohs(pkt.ip->len) + sizeof(struct eth);
}
if (pkt.raw.len < sizeof(*pkt.eth) + sizeof(*pkt.ip)) return; // Truncated
if ((pkt.ip->ver >> 4) != 4) return; // Not IP
mkpay(&pkt, pkt.ip + 1);
rx_ip(ifp, &pkt);
} else {
MG_DEBUG(("Unknown eth type %x", mg_htons(pkt.eth->type)));
if (mg_log_level >= MG_LL_VERBOSE) mg_hexdump(buf, len >= 32 ? 32 : len);
}
}
static void mg_tcpip_poll(struct mg_tcpip_if *ifp, uint64_t uptime_ms) {
if (ifp == NULL || ifp->driver == NULL) return;
bool expired_1000ms = mg_timer_expired(&ifp->timer_1000ms, 1000, uptime_ms);
ifp->now = uptime_ms;
// Handle physical interface up/down status
if (expired_1000ms && ifp->driver->up) {
bool up = ifp->driver->up(ifp);
bool current = ifp->state != MG_TCPIP_STATE_DOWN;
if (up != current) {
ifp->state = up == false ? MG_TCPIP_STATE_DOWN
: ifp->enable_dhcp_client ? MG_TCPIP_STATE_UP
: MG_TCPIP_STATE_READY;
if (!up && ifp->enable_dhcp_client) ifp->ip = 0;
onstatechange(ifp);
}
}
if (ifp->state == MG_TCPIP_STATE_DOWN) return;
// DHCP RFC-2131 (4.4)
if (ifp->state == MG_TCPIP_STATE_UP && expired_1000ms) {
tx_dhcp_discover(ifp); // INIT (4.4.1)
} else if (expired_1000ms && ifp->state == MG_TCPIP_STATE_READY &&
ifp->lease_expire > 0) { // BOUND / RENEWING / REBINDING
if (ifp->now >= ifp->lease_expire) {
ifp->state = MG_TCPIP_STATE_UP, ifp->ip = 0; // expired, release IP
onstatechange(ifp);
} else if (ifp->now + 30UL * 60UL * 1000UL > ifp->lease_expire &&
((ifp->now / 1000) % 60) == 0) {
// hack: 30 min before deadline, try to rebind (4.3.6) every min
tx_dhcp_request_re(ifp, (uint8_t *) broadcast, ifp->ip, 0xffffffff);
} // TODO(): Handle T1 (RENEWING) and T2 (REBINDING) (4.4.5)
}
// Read data from the network
if (ifp->driver->rx != NULL) { // Polling driver. We must call it
size_t len =
ifp->driver->rx(ifp->recv_queue.buf, ifp->recv_queue.size, ifp);
if (len > 0) {
ifp->nrecv++;
mg_tcpip_rx(ifp, ifp->recv_queue.buf, len);
}
} else { // Interrupt-based driver. Fills recv queue itself
char *buf;
size_t len = mg_queue_next(&ifp->recv_queue, &buf);
if (len > 0) {
mg_tcpip_rx(ifp, buf, len);
mg_queue_del(&ifp->recv_queue, len);
}
}
// Process timeouts
for (struct mg_connection *c = ifp->mgr->conns; c != NULL; c = c->next) {
if (c->is_udp || c->is_listening || c->is_resolving) continue;
struct connstate *s = (struct connstate *) (c + 1);
uint32_t rem_ip;
memcpy(&rem_ip, c->rem.ip, sizeof(uint32_t));
if (uptime_ms > s->timer) {
if (s->ttype == MIP_TTYPE_ACK) {
MG_VERBOSE(("%lu ack %x %x", c->id, s->seq, s->ack));
tx_tcp(ifp, s->mac, rem_ip, TH_ACK, c->loc.port, c->rem.port,
mg_htonl(s->seq), mg_htonl(s->ack), "", 0);
} else if (s->ttype == MIP_TTYPE_ARP) {
mg_error(c, "ARP timeout");
} else if (s->ttype == MIP_TTYPE_SYN) {
mg_error(c, "Connection timeout");
} else if (s->ttype == MIP_TTYPE_FIN) {
c->is_closing = 1;
continue;
} else {
if (s->tmiss++ > 2) {
mg_error(c, "keepalive");
} else {
MG_VERBOSE(("%lu keepalive", c->id));
tx_tcp(ifp, s->mac, rem_ip, TH_ACK, c->loc.port, c->rem.port,
mg_htonl(s->seq - 1), mg_htonl(s->ack), "", 0);
}
}
settmout(c, MIP_TTYPE_KEEPALIVE);
}
}
}
// This function executes in interrupt context, thus it should copy data
// somewhere fast. Note that newlib's malloc is not thread safe, thus use
// our lock-free queue with preallocated buffer to copy data and return asap
void mg_tcpip_qwrite(void *buf, size_t len, struct mg_tcpip_if *ifp) {
char *p;
if (mg_queue_book(&ifp->recv_queue, &p, len) >= len) {
memcpy(p, buf, len);
mg_queue_add(&ifp->recv_queue, len);
ifp->nrecv++;
} else {
ifp->ndrop++;
}
}
void mg_tcpip_init(struct mg_mgr *mgr, struct mg_tcpip_if *ifp) {
// If MAC address is not set, make a random one
if (ifp->mac[0] == 0 && ifp->mac[1] == 0 && ifp->mac[2] == 0 &&
ifp->mac[3] == 0 && ifp->mac[4] == 0 && ifp->mac[5] == 0) {
ifp->mac[0] = 0x02; // Locally administered, unicast
mg_random(&ifp->mac[1], sizeof(ifp->mac) - 1);
MG_INFO(("MAC not set. Generated random: %M", mg_print_mac, ifp->mac));
}
if (ifp->driver->init && !ifp->driver->init(ifp)) {
MG_ERROR(("driver init failed"));
} else {
size_t framesize = 1540;
ifp->tx.ptr = (char *) calloc(1, framesize), ifp->tx.len = framesize;
if (ifp->recv_queue.size == 0)
ifp->recv_queue.size = ifp->driver->rx ? framesize : 8192;
ifp->recv_queue.buf = (char *) calloc(1, ifp->recv_queue.size);
ifp->timer_1000ms = mg_millis();
mgr->priv = ifp;
ifp->mgr = mgr;
ifp->mtu = MG_TCPIP_MTU_DEFAULT;
mgr->extraconnsize = sizeof(struct connstate);
if (ifp->ip == 0) ifp->enable_dhcp_client = true;
memset(ifp->gwmac, 255, sizeof(ifp->gwmac)); // Set to broadcast
mg_random(&ifp->eport, sizeof(ifp->eport)); // Random from 0 to 65535
ifp->eport |= MG_EPHEMERAL_PORT_BASE; // Random from
// MG_EPHEMERAL_PORT_BASE to 65535
if (ifp->tx.ptr == NULL || ifp->recv_queue.buf == NULL) MG_ERROR(("OOM"));
}
}
void mg_tcpip_free(struct mg_tcpip_if *ifp) {
free(ifp->recv_queue.buf);
free((char *) ifp->tx.ptr);
}
static void send_syn(struct mg_connection *c) {
struct connstate *s = (struct connstate *) (c + 1);
uint32_t isn = mg_htonl((uint32_t) mg_ntohs(c->loc.port));
struct mg_tcpip_if *ifp = (struct mg_tcpip_if *) c->mgr->priv;
uint32_t rem_ip;
memcpy(&rem_ip, c->rem.ip, sizeof(uint32_t));
tx_tcp(ifp, s->mac, rem_ip, TH_SYN, c->loc.port, c->rem.port, isn, 0, NULL,
0);
}
void mg_connect_resolved(struct mg_connection *c) {
struct mg_tcpip_if *ifp = (struct mg_tcpip_if *) c->mgr->priv;
uint32_t rem_ip;
memcpy(&rem_ip, c->rem.ip, sizeof(uint32_t));
c->is_resolving = 0;
if (ifp->eport < MG_EPHEMERAL_PORT_BASE) ifp->eport = MG_EPHEMERAL_PORT_BASE;
memcpy(c->loc.ip, &ifp->ip, sizeof(uint32_t));
c->loc.port = mg_htons(ifp->eport++);
MG_DEBUG(("%lu %M -> %M", c->id, mg_print_ip_port, &c->loc, mg_print_ip_port,
&c->rem));
mg_call(c, MG_EV_RESOLVE, NULL);
if (c->is_udp && (rem_ip == 0xffffffff || rem_ip == (ifp->ip | ~ifp->mask))) {
struct connstate *s = (struct connstate *) (c + 1);
memset(s->mac, 0xFF, sizeof(s->mac)); // global or local broadcast
} else if (((rem_ip & ifp->mask) == (ifp->ip & ifp->mask))) {
// If we're in the same LAN, fire an ARP lookup.
MG_DEBUG(("%lu ARP lookup...", c->id));
arp_ask(ifp, rem_ip);
settmout(c, MIP_TTYPE_ARP);
c->is_arplooking = 1;
c->is_connecting = 1;
} else if ((*((uint8_t *) &rem_ip) & 0xE0) == 0xE0) {
struct connstate *s = (struct connstate *) (c + 1); // 224 to 239, E0 to EF
uint8_t mcastp[3] = {0x01, 0x00, 0x5E}; // multicast group
memcpy(s->mac, mcastp, 3);
memcpy(s->mac + 3, ((uint8_t *) &rem_ip) + 1, 3); // 23 LSb
s->mac[3] &= 0x7F;
} else {
struct connstate *s = (struct connstate *) (c + 1);
memcpy(s->mac, ifp->gwmac, sizeof(ifp->gwmac));
if (c->is_udp) {
mg_call(c, MG_EV_CONNECT, NULL);
} else {
send_syn(c);
settmout(c, MIP_TTYPE_SYN);
c->is_connecting = 1;
}
}
}
bool mg_open_listener(struct mg_connection *c, const char *url) {
c->loc.port = mg_htons(mg_url_port(url));
return true;
}
static void write_conn(struct mg_connection *c) {
long len = c->is_tls ? mg_tls_send(c, c->send.buf, c->send.len)
: mg_io_send(c, c->send.buf, c->send.len);
if (len == MG_IO_ERR) {
mg_error(c, "tx err");
} else if (len > 0) {
mg_iobuf_del(&c->send, 0, (size_t) len);
mg_call(c, MG_EV_WRITE, &len);
}
}
static void init_closure(struct mg_connection *c) {
struct connstate *s = (struct connstate *) (c + 1);
if (c->is_udp == false && c->is_listening == false &&
c->is_connecting == false) { // For TCP conns,
struct mg_tcpip_if *ifp =
(struct mg_tcpip_if *) c->mgr->priv; // send TCP FIN
uint32_t rem_ip;
memcpy(&rem_ip, c->rem.ip, sizeof(uint32_t));
tx_tcp(ifp, s->mac, rem_ip, TH_FIN | TH_ACK, c->loc.port, c->rem.port,
mg_htonl(s->seq), mg_htonl(s->ack), NULL, 0);
settmout(c, MIP_TTYPE_FIN);
}
}
static void close_conn(struct mg_connection *c) {
struct connstate *s = (struct connstate *) (c + 1);
mg_iobuf_free(&s->raw); // For TLS connections, release raw data
mg_close_conn(c);
}
static bool can_write(struct mg_connection *c) {
return c->is_connecting == 0 && c->is_resolving == 0 && c->send.len > 0 &&
c->is_tls_hs == 0 && c->is_arplooking == 0;
}
void mg_mgr_poll(struct mg_mgr *mgr, int ms) {
struct mg_connection *c, *tmp;
uint64_t now = mg_millis();
mg_tcpip_poll((struct mg_tcpip_if *) mgr->priv, now);
mg_timer_poll(&mgr->timers, now);
for (c = mgr->conns; c != NULL; c = tmp) {
tmp = c->next;
struct connstate *s = (struct connstate *) (c + 1);
mg_call(c, MG_EV_POLL, &now);
MG_VERBOSE(("%lu .. %c%c%c%c%c", c->id, c->is_tls ? 'T' : 't',
c->is_connecting ? 'C' : 'c', c->is_tls_hs ? 'H' : 'h',
c->is_resolving ? 'R' : 'r', c->is_closing ? 'C' : 'c'));
if (can_write(c)) write_conn(c);
if (c->is_draining && c->send.len == 0 && s->ttype != MIP_TTYPE_FIN)
init_closure(c);
if (c->is_closing) close_conn(c);
}
(void) ms;
}
bool mg_send(struct mg_connection *c, const void *buf, size_t len) {
struct mg_tcpip_if *ifp = (struct mg_tcpip_if *) c->mgr->priv;
bool res = false;
uint32_t rem_ip;
memcpy(&rem_ip, c->rem.ip, sizeof(uint32_t));
if (ifp->ip == 0 || ifp->state != MG_TCPIP_STATE_READY) {
mg_error(c, "net down");
} else if (c->is_udp) {
struct connstate *s = (struct connstate *) (c + 1);
len = trim_len(c, len); // Trimming length if necessary
tx_udp(ifp, s->mac, ifp->ip, c->loc.port, rem_ip, c->rem.port, buf, len);
res = true;
} else {
res = mg_iobuf_add(&c->send, c->send.len, buf, len);
}
return res;
}
#endif // MG_ENABLE_TCPIP
#ifdef MG_ENABLE_LINES
#line 1 "src/net.c"
#endif
size_t mg_vprintf(struct mg_connection *c, const char *fmt, va_list *ap) {
size_t old = c->send.len;
mg_vxprintf(mg_pfn_iobuf, &c->send, fmt, ap);
return c->send.len - old;
}
size_t mg_printf(struct mg_connection *c, const char *fmt, ...) {
size_t len = 0;
va_list ap;
va_start(ap, fmt);
len = mg_vprintf(c, fmt, &ap);
va_end(ap);
return len;
}
static bool mg_atonl(struct mg_str str, struct mg_addr *addr) {
uint32_t localhost = mg_htonl(0x7f000001);
if (mg_vcasecmp(&str, "localhost") != 0) return false;
memcpy(addr->ip, &localhost, sizeof(uint32_t));
addr->is_ip6 = false;
return true;
}
static bool mg_atone(struct mg_str str, struct mg_addr *addr) {
if (str.len > 0) return false;
memset(addr->ip, 0, sizeof(addr->ip));
addr->is_ip6 = false;
return true;
}
static bool mg_aton4(struct mg_str str, struct mg_addr *addr) {
uint8_t data[4] = {0, 0, 0, 0};
size_t i, num_dots = 0;
for (i = 0; i < str.len; i++) {
if (str.ptr[i] >= '0' && str.ptr[i] <= '9') {
int octet = data[num_dots] * 10 + (str.ptr[i] - '0');
if (octet > 255) return false;
data[num_dots] = (uint8_t) octet;
} else if (str.ptr[i] == '.') {
if (num_dots >= 3 || i == 0 || str.ptr[i - 1] == '.') return false;
num_dots++;
} else {
return false;
}
}
if (num_dots != 3 || str.ptr[i - 1] == '.') return false;
memcpy(&addr->ip, data, sizeof(data));
addr->is_ip6 = false;
return true;
}
static bool mg_v4mapped(struct mg_str str, struct mg_addr *addr) {
int i;
uint32_t ipv4;
if (str.len < 14) return false;
if (str.ptr[0] != ':' || str.ptr[1] != ':' || str.ptr[6] != ':') return false;
for (i = 2; i < 6; i++) {
if (str.ptr[i] != 'f' && str.ptr[i] != 'F') return false;
}
// struct mg_str s = mg_str_n(&str.ptr[7], str.len - 7);
if (!mg_aton4(mg_str_n(&str.ptr[7], str.len - 7), addr)) return false;
memcpy(&ipv4, addr->ip, sizeof(ipv4));
memset(addr->ip, 0, sizeof(addr->ip));
addr->ip[10] = addr->ip[11] = 255;
memcpy(&addr->ip[12], &ipv4, 4);
addr->is_ip6 = true;
return true;
}
static bool mg_aton6(struct mg_str str, struct mg_addr *addr) {
size_t i, j = 0, n = 0, dc = 42;
addr->scope_id = 0;
if (str.len > 2 && str.ptr[0] == '[') str.ptr++, str.len -= 2;
if (mg_v4mapped(str, addr)) return true;
for (i = 0; i < str.len; i++) {
if ((str.ptr[i] >= '0' && str.ptr[i] <= '9') ||
(str.ptr[i] >= 'a' && str.ptr[i] <= 'f') ||
(str.ptr[i] >= 'A' && str.ptr[i] <= 'F')) {
unsigned long val;
if (i > j + 3) return false;
// MG_DEBUG(("%lu %lu [%.*s]", i, j, (int) (i - j + 1), &str.ptr[j]));
val = mg_unhexn(&str.ptr[j], i - j + 1);
addr->ip[n] = (uint8_t) ((val >> 8) & 255);
addr->ip[n + 1] = (uint8_t) (val & 255);
} else if (str.ptr[i] == ':') {
j = i + 1;
if (i > 0 && str.ptr[i - 1] == ':') {
dc = n; // Double colon
if (i > 1 && str.ptr[i - 2] == ':') return false;
} else if (i > 0) {
n += 2;
}
if (n > 14) return false;
addr->ip[n] = addr->ip[n + 1] = 0; // For trailing ::
} else if (str.ptr[i] == '%') { // Scope ID
for (i = i + 1; i < str.len; i++) {
if (str.ptr[i] < '0' || str.ptr[i] > '9') return false;
addr->scope_id = (uint8_t) (addr->scope_id * 10);
addr->scope_id = (uint8_t) (addr->scope_id + (str.ptr[i] - '0'));
}
} else {
return false;
}
}
if (n < 14 && dc == 42) return false;
if (n < 14) {
memmove(&addr->ip[dc + (14 - n)], &addr->ip[dc], n - dc + 2);
memset(&addr->ip[dc], 0, 14 - n);
}
addr->is_ip6 = true;
return true;
}
bool mg_aton(struct mg_str str, struct mg_addr *addr) {
// MG_INFO(("[%.*s]", (int) str.len, str.ptr));
return mg_atone(str, addr) || mg_atonl(str, addr) || mg_aton4(str, addr) ||
mg_aton6(str, addr);
}
struct mg_connection *mg_alloc_conn(struct mg_mgr *mgr) {
struct mg_connection *c =
(struct mg_connection *) calloc(1, sizeof(*c) + mgr->extraconnsize);
if (c != NULL) {
c->mgr = mgr;
c->send.align = c->recv.align = c->rtls.align = MG_IO_SIZE;
c->id = ++mgr->nextid;
MG_PROF_INIT(c);
}
return c;
}
void mg_close_conn(struct mg_connection *c) {
mg_resolve_cancel(c); // Close any pending DNS query
LIST_DELETE(struct mg_connection, &c->mgr->conns, c);
if (c == c->mgr->dns4.c) c->mgr->dns4.c = NULL;
if (c == c->mgr->dns6.c) c->mgr->dns6.c = NULL;
// Order of operations is important. `MG_EV_CLOSE` event must be fired
// before we deallocate received data, see #1331
mg_call(c, MG_EV_CLOSE, NULL);
MG_DEBUG(("%lu %ld closed", c->id, c->fd));
MG_PROF_DUMP(c);
MG_PROF_FREE(c);
mg_tls_free(c);
mg_iobuf_free(&c->recv);
mg_iobuf_free(&c->send);
mg_iobuf_free(&c->rtls);
mg_bzero((unsigned char *) c, sizeof(*c));
free(c);
}
struct mg_connection *mg_connect(struct mg_mgr *mgr, const char *url,
mg_event_handler_t fn, void *fn_data) {
struct mg_connection *c = NULL;
if (url == NULL || url[0] == '\0') {
MG_ERROR(("null url"));
} else if ((c = mg_alloc_conn(mgr)) == NULL) {
MG_ERROR(("OOM"));
} else {
LIST_ADD_HEAD(struct mg_connection, &mgr->conns, c);
c->is_udp = (strncmp(url, "udp:", 4) == 0);
c->fd = (void *) (size_t) MG_INVALID_SOCKET;
c->fn = fn;
c->is_client = true;
c->fn_data = fn_data;
MG_DEBUG(("%lu %ld %s", c->id, c->fd, url));
mg_call(c, MG_EV_OPEN, (void *) url);
mg_resolve(c, url);
}
return c;
}
struct mg_connection *mg_listen(struct mg_mgr *mgr, const char *url,
mg_event_handler_t fn, void *fn_data) {
struct mg_connection *c = NULL;
if ((c = mg_alloc_conn(mgr)) == NULL) {
MG_ERROR(("OOM %s", url));
} else if (!mg_open_listener(c, url)) {
MG_ERROR(("Failed: %s, errno %d", url, errno));
MG_PROF_FREE(c);
free(c);
c = NULL;
} else {
c->is_listening = 1;
c->is_udp = strncmp(url, "udp:", 4) == 0;
LIST_ADD_HEAD(struct mg_connection, &mgr->conns, c);
c->fn = fn;
c->fn_data = fn_data;
mg_call(c, MG_EV_OPEN, NULL);
if (mg_url_is_ssl(url)) c->is_tls = 1; // Accepted connection must
MG_DEBUG(("%lu %ld %s", c->id, c->fd, url));
}
return c;
}
struct mg_connection *mg_wrapfd(struct mg_mgr *mgr, int fd,
mg_event_handler_t fn, void *fn_data) {
struct mg_connection *c = mg_alloc_conn(mgr);
if (c != NULL) {
c->fd = (void *) (size_t) fd;
c->fn = fn;
c->fn_data = fn_data;
MG_EPOLL_ADD(c);
mg_call(c, MG_EV_OPEN, NULL);
LIST_ADD_HEAD(struct mg_connection, &mgr->conns, c);
}
return c;
}
struct mg_timer *mg_timer_add(struct mg_mgr *mgr, uint64_t milliseconds,
unsigned flags, void (*fn)(void *), void *arg) {
struct mg_timer *t = (struct mg_timer *) calloc(1, sizeof(*t));
if (t != NULL) {
mg_timer_init(&mgr->timers, t, milliseconds, flags, fn, arg);
t->id = mgr->timerid++;
}
return t;
}
long mg_io_recv(struct mg_connection *c, void *buf, size_t len) {
if (c->rtls.len == 0) return MG_IO_WAIT;
if (len > c->rtls.len) len = c->rtls.len;
memcpy(buf, c->rtls.buf, len);
mg_iobuf_del(&c->rtls, 0, len);
return (long) len;
}
void mg_mgr_free(struct mg_mgr *mgr) {
struct mg_connection *c;
struct mg_timer *tmp, *t = mgr->timers;
while (t != NULL) tmp = t->next, free(t), t = tmp;
mgr->timers = NULL; // Important. Next call to poll won't touch timers
for (c = mgr->conns; c != NULL; c = c->next) c->is_closing = 1;
mg_mgr_poll(mgr, 0);
#if MG_ENABLE_FREERTOS_TCP
FreeRTOS_DeleteSocketSet(mgr->ss);
#endif
MG_DEBUG(("All connections closed"));
#if MG_ENABLE_EPOLL
if (mgr->epoll_fd >= 0) close(mgr->epoll_fd), mgr->epoll_fd = -1;
#endif
mg_tls_ctx_free(mgr);
}
void mg_mgr_init(struct mg_mgr *mgr) {
memset(mgr, 0, sizeof(*mgr));
#if MG_ENABLE_EPOLL
if ((mgr->epoll_fd = epoll_create1(EPOLL_CLOEXEC)) < 0)
MG_ERROR(("epoll_create1 errno %d", errno));
#else
mgr->epoll_fd = -1;
#endif
#if MG_ARCH == MG_ARCH_WIN32 && MG_ENABLE_WINSOCK
// clang-format off
{ WSADATA data; WSAStartup(MAKEWORD(2, 2), &data); }
// clang-format on
#elif MG_ENABLE_FREERTOS_TCP
mgr->ss = FreeRTOS_CreateSocketSet();
#elif defined(__unix) || defined(__unix__) || defined(__APPLE__)
// Ignore SIGPIPE signal, so if client cancels the request, it
// won't kill the whole process.
signal(SIGPIPE, SIG_IGN);
#endif
mgr->pipe = MG_INVALID_SOCKET;
mgr->dnstimeout = 3000;
mgr->dns4.url = "udp://8.8.8.8:53";
mgr->dns6.url = "udp://[2001:4860:4860::8888]:53";
mg_tls_ctx_init(mgr);
}
#ifdef MG_ENABLE_LINES
#line 1 "src/ota_dummy.c"
#endif
#if MG_OTA == MG_OTA_NONE
bool mg_ota_begin(size_t new_firmware_size) {
(void) new_firmware_size;
return true;
}
bool mg_ota_write(const void *buf, size_t len) {
(void) buf, (void) len;
return true;
}
bool mg_ota_end(void) {
return true;
}
bool mg_ota_commit(void) {
return true;
}
bool mg_ota_rollback(void) {
return true;
}
int mg_ota_status(int fw) {
(void) fw;
return 0;
}
uint32_t mg_ota_crc32(int fw) {
(void) fw;
return 0;
}
uint32_t mg_ota_timestamp(int fw) {
(void) fw;
return 0;
}
size_t mg_ota_size(int fw) {
(void) fw;
return 0;
}
MG_IRAM void mg_ota_boot(void) {
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/ota_flash.c"
#endif
// This OTA implementation uses the internal flash API outlined in device.h
// It splits flash into 2 equal partitions, and stores OTA status in the
// last sector of the partition.
#if MG_OTA == MG_OTA_FLASH
#define MG_OTADATA_KEY 0xb07afed0
static char *s_addr; // Current address to write to
static size_t s_size; // Firmware size to flash. In-progress indicator
static uint32_t s_crc32; // Firmware checksum
struct mg_otadata {
uint32_t crc32, size, timestamp, status;
};
bool mg_ota_begin(size_t new_firmware_size) {
bool ok = false;
if (s_size) {
MG_ERROR(("OTA already in progress. Call mg_ota_end()"));
} else {
size_t half = mg_flash_size() / 2, max = half - mg_flash_sector_size();
s_crc32 = 0;
s_addr = (char *) mg_flash_start() + half;
MG_DEBUG(("Firmware %lu bytes, max %lu", new_firmware_size, max));
if (new_firmware_size < max) {
ok = true;
s_size = new_firmware_size;
MG_INFO(("Starting OTA, firmware size %lu", s_size));
} else {
MG_ERROR(("Firmware %lu is too big to fit %lu", new_firmware_size, max));
}
}
return ok;
}
bool mg_ota_write(const void *buf, size_t len) {
bool ok = false;
if (s_size == 0) {
MG_ERROR(("OTA is not started, call mg_ota_begin()"));
} else {
size_t align = mg_flash_write_align();
size_t len_aligned_down = MG_ROUND_DOWN(len, align);
if (len_aligned_down) ok = mg_flash_write(s_addr, buf, len_aligned_down);
if (len_aligned_down < len) {
size_t left = len - len_aligned_down;
char tmp[align];
memset(tmp, 0xff, sizeof(tmp));
memcpy(tmp, (char *) buf + len_aligned_down, left);
ok = mg_flash_write(s_addr + len_aligned_down, tmp, sizeof(tmp));
}
s_crc32 = mg_crc32(s_crc32, (char *) buf, len); // Update CRC
MG_DEBUG(("%#x %p %lu -> %d", s_addr - len, buf, len, ok));
s_addr += len;
}
return ok;
}
MG_IRAM static uint32_t mg_fwkey(int fw) {
uint32_t key = MG_OTADATA_KEY + fw;
int bank = mg_flash_bank();
if (bank == 2 && fw == MG_FIRMWARE_PREVIOUS) key--;
if (bank == 2 && fw == MG_FIRMWARE_CURRENT) key++;
return key;
}
bool mg_ota_end(void) {
char *base = (char *) mg_flash_start() + mg_flash_size() / 2;
bool ok = false;
if (s_size) {
size_t size = s_addr - base;
uint32_t crc32 = mg_crc32(0, base, s_size);
if (size == s_size && crc32 == s_crc32) {
uint32_t now = (uint32_t) (mg_now() / 1000);
struct mg_otadata od = {crc32, size, now, MG_OTA_FIRST_BOOT};
uint32_t key = mg_fwkey(MG_FIRMWARE_PREVIOUS);
ok = mg_flash_save(NULL, key, &od, sizeof(od));
}
MG_DEBUG(("CRC: %x/%x, size: %lu/%lu, status: %s", s_crc32, crc32, s_size,
size, ok ? "ok" : "fail"));
s_size = 0;
if (ok) ok = mg_flash_swap_bank();
}
MG_INFO(("Finishing OTA: %s", ok ? "ok" : "fail"));
return ok;
}
MG_IRAM static struct mg_otadata mg_otadata(int fw) {
uint32_t key = mg_fwkey(fw);
struct mg_otadata od = {};
MG_INFO(("Loading %s OTA data", fw == MG_FIRMWARE_CURRENT ? "curr" : "prev"));
mg_flash_load(NULL, key, &od, sizeof(od));
// MG_DEBUG(("Loaded OTA data. fw %d, bank %d, key %p", fw, bank, key));
// mg_hexdump(&od, sizeof(od));
return od;
}
int mg_ota_status(int fw) {
struct mg_otadata od = mg_otadata(fw);
return od.status;
}
uint32_t mg_ota_crc32(int fw) {
struct mg_otadata od = mg_otadata(fw);
return od.crc32;
}
uint32_t mg_ota_timestamp(int fw) {
struct mg_otadata od = mg_otadata(fw);
return od.timestamp;
}
size_t mg_ota_size(int fw) {
struct mg_otadata od = mg_otadata(fw);
return od.size;
}
MG_IRAM bool mg_ota_commit(void) {
bool ok = true;
struct mg_otadata od = mg_otadata(MG_FIRMWARE_CURRENT);
if (od.status != MG_OTA_COMMITTED) {
od.status = MG_OTA_COMMITTED;
MG_INFO(("Committing current firmware, OD size %lu", sizeof(od)));
ok = mg_flash_save(NULL, mg_fwkey(MG_FIRMWARE_CURRENT), &od, sizeof(od));
}
return ok;
}
bool mg_ota_rollback(void) {
MG_DEBUG(("Rolling firmware back"));
if (mg_flash_bank() == 0) {
// No dual bank support. Mark previous firmware as FIRST_BOOT
struct mg_otadata prev = mg_otadata(MG_FIRMWARE_PREVIOUS);
prev.status = MG_OTA_FIRST_BOOT;
return mg_flash_save(NULL, MG_OTADATA_KEY + MG_FIRMWARE_PREVIOUS, &prev,
sizeof(prev));
} else {
return mg_flash_swap_bank();
}
}
MG_IRAM void mg_ota_boot(void) {
MG_INFO(("Booting. Flash bank: %d", mg_flash_bank()));
struct mg_otadata curr = mg_otadata(MG_FIRMWARE_CURRENT);
struct mg_otadata prev = mg_otadata(MG_FIRMWARE_PREVIOUS);
if (curr.status == MG_OTA_FIRST_BOOT) {
if (prev.status == MG_OTA_UNAVAILABLE) {
MG_INFO(("Setting previous firmware state to committed"));
prev.status = MG_OTA_COMMITTED;
mg_flash_save(NULL, mg_fwkey(MG_FIRMWARE_PREVIOUS), &prev, sizeof(prev));
}
curr.status = MG_OTA_UNCOMMITTED;
MG_INFO(("First boot, setting status to UNCOMMITTED"));
mg_flash_save(NULL, mg_fwkey(MG_FIRMWARE_CURRENT), &curr, sizeof(curr));
} else if (prev.status == MG_OTA_FIRST_BOOT && mg_flash_bank() == 0) {
// Swap paritions. Pray power does not disappear
size_t fs = mg_flash_size(), ss = mg_flash_sector_size();
char *partition1 = mg_flash_start();
char *partition2 = mg_flash_start() + fs / 2;
size_t ofs, max = fs / 2 - ss; // Set swap size to the whole partition
if (curr.status != MG_OTA_UNAVAILABLE &&
prev.status != MG_OTA_UNAVAILABLE) {
// We know exact sizes of both firmwares.
// Shrink swap size to the MAX(firmware1, firmware2)
size_t sz = curr.size > prev.size ? curr.size : prev.size;
if (sz > 0 && sz < max) max = sz;
}
// MG_OTA_FIRST_BOOT -> MG_OTA_UNCOMMITTED
prev.status = MG_OTA_UNCOMMITTED;
mg_flash_save(NULL, MG_OTADATA_KEY + MG_FIRMWARE_CURRENT, &prev,
sizeof(prev));
mg_flash_save(NULL, MG_OTADATA_KEY + MG_FIRMWARE_PREVIOUS, &curr,
sizeof(curr));
MG_INFO(("Swapping partitions, size %u (%u sectors)", max, max / ss));
MG_INFO(("Do NOT power off..."));
mg_log_level = MG_LL_NONE;
// We use the last sector of partition2 for OTA data/config storage
// Therefore we can use last sector of partition1 for swapping
char *tmpsector = partition1 + fs / 2 - ss; // Last sector of partition1
(void) tmpsector;
for (ofs = 0; ofs < max; ofs += ss) {
// mg_flash_erase(tmpsector);
mg_flash_write(tmpsector, partition1 + ofs, ss);
// mg_flash_erase(partition1 + ofs);
mg_flash_write(partition1 + ofs, partition2 + ofs, ss);
// mg_flash_erase(partition2 + ofs);
mg_flash_write(partition2 + ofs, tmpsector, ss);
}
mg_device_reset();
}
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/printf.c"
#endif
size_t mg_queue_vprintf(struct mg_queue *q, const char *fmt, va_list *ap) {
size_t len = mg_snprintf(NULL, 0, fmt, ap);
char *buf;
if (len == 0 || mg_queue_book(q, &buf, len + 1) < len + 1) {
len = 0; // Nah. Not enough space
} else {
len = mg_vsnprintf((char *) buf, len + 1, fmt, ap);
mg_queue_add(q, len);
}
return len;
}
size_t mg_queue_printf(struct mg_queue *q, const char *fmt, ...) {
va_list ap;
size_t len;
va_start(ap, fmt);
len = mg_queue_vprintf(q, fmt, &ap);
va_end(ap);
return len;
}
static void mg_pfn_iobuf_private(char ch, void *param, bool expand) {
struct mg_iobuf *io = (struct mg_iobuf *) param;
if (expand && io->len + 2 > io->size) mg_iobuf_resize(io, io->len + 2);
if (io->len + 2 <= io->size) {
io->buf[io->len++] = (uint8_t) ch;
io->buf[io->len] = 0;
} else if (io->len < io->size) {
io->buf[io->len++] = 0; // Guarantee to 0-terminate
}
}
static void mg_putchar_iobuf_static(char ch, void *param) {
mg_pfn_iobuf_private(ch, param, false);
}
void mg_pfn_iobuf(char ch, void *param) {
mg_pfn_iobuf_private(ch, param, true);
}
size_t mg_vsnprintf(char *buf, size_t len, const char *fmt, va_list *ap) {
struct mg_iobuf io = {(uint8_t *) buf, len, 0, 0};
size_t n = mg_vxprintf(mg_putchar_iobuf_static, &io, fmt, ap);
if (n < len) buf[n] = '\0';
return n;
}
size_t mg_snprintf(char *buf, size_t len, const char *fmt, ...) {
va_list ap;
size_t n;
va_start(ap, fmt);
n = mg_vsnprintf(buf, len, fmt, &ap);
va_end(ap);
return n;
}
char *mg_vmprintf(const char *fmt, va_list *ap) {
struct mg_iobuf io = {0, 0, 0, 256};
mg_vxprintf(mg_pfn_iobuf, &io, fmt, ap);
return (char *) io.buf;
}
char *mg_mprintf(const char *fmt, ...) {
char *s;
va_list ap;
va_start(ap, fmt);
s = mg_vmprintf(fmt, &ap);
va_end(ap);
return s;
}
void mg_pfn_stdout(char c, void *param) {
putchar(c);
(void) param;
}
static size_t print_ip4(void (*out)(char, void *), void *arg, uint8_t *p) {
return mg_xprintf(out, arg, "%d.%d.%d.%d", p[0], p[1], p[2], p[3]);
}
static size_t print_ip6(void (*out)(char, void *), void *arg, uint16_t *p) {
return mg_xprintf(out, arg, "[%x:%x:%x:%x:%x:%x:%x:%x]", mg_ntohs(p[0]),
mg_ntohs(p[1]), mg_ntohs(p[2]), mg_ntohs(p[3]),
mg_ntohs(p[4]), mg_ntohs(p[5]), mg_ntohs(p[6]),
mg_ntohs(p[7]));
}
size_t mg_print_ip4(void (*out)(char, void *), void *arg, va_list *ap) {
uint8_t *p = va_arg(*ap, uint8_t *);
return print_ip4(out, arg, p);
}
size_t mg_print_ip6(void (*out)(char, void *), void *arg, va_list *ap) {
uint16_t *p = va_arg(*ap, uint16_t *);
return print_ip6(out, arg, p);
}
size_t mg_print_ip(void (*out)(char, void *), void *arg, va_list *ap) {
struct mg_addr *addr = va_arg(*ap, struct mg_addr *);
if (addr->is_ip6) return print_ip6(out, arg, (uint16_t *) addr->ip);
return print_ip4(out, arg, (uint8_t *) &addr->ip);
}
size_t mg_print_ip_port(void (*out)(char, void *), void *arg, va_list *ap) {
struct mg_addr *a = va_arg(*ap, struct mg_addr *);
return mg_xprintf(out, arg, "%M:%hu", mg_print_ip, a, mg_ntohs(a->port));
}
size_t mg_print_mac(void (*out)(char, void *), void *arg, va_list *ap) {
uint8_t *p = va_arg(*ap, uint8_t *);
return mg_xprintf(out, arg, "%02x:%02x:%02x:%02x:%02x:%02x", p[0], p[1], p[2],
p[3], p[4], p[5]);
}
static char mg_esc(int c, bool esc) {
const char *p, *esc1 = "\b\f\n\r\t\\\"", *esc2 = "bfnrt\\\"";
for (p = esc ? esc1 : esc2; *p != '\0'; p++) {
if (*p == c) return esc ? esc2[p - esc1] : esc1[p - esc2];
}
return 0;
}
static char mg_escape(int c) {
return mg_esc(c, true);
}
static size_t qcpy(void (*out)(char, void *), void *ptr, char *buf,
size_t len) {
size_t i = 0, extra = 0;
for (i = 0; i < len && buf[i] != '\0'; i++) {
char c = mg_escape(buf[i]);
if (c) {
out('\\', ptr), out(c, ptr), extra++;
} else {
out(buf[i], ptr);
}
}
return i + extra;
}
static size_t bcpy(void (*out)(char, void *), void *arg, uint8_t *buf,
size_t len) {
size_t i, j, n = 0;
const char *t =
"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
for (i = 0; i < len; i += 3) {
uint8_t c1 = buf[i], c2 = i + 1 < len ? buf[i + 1] : 0,
c3 = i + 2 < len ? buf[i + 2] : 0;
char tmp[4] = {t[c1 >> 2], t[(c1 & 3) << 4 | (c2 >> 4)], '=', '='};
if (i + 1 < len) tmp[2] = t[(c2 & 15) << 2 | (c3 >> 6)];
if (i + 2 < len) tmp[3] = t[c3 & 63];
for (j = 0; j < sizeof(tmp) && tmp[j] != '\0'; j++) out(tmp[j], arg);
n += j;
}
return n;
}
size_t mg_print_hex(void (*out)(char, void *), void *arg, va_list *ap) {
size_t bl = (size_t) va_arg(*ap, int);
uint8_t *p = va_arg(*ap, uint8_t *);
const char *hex = "0123456789abcdef";
size_t j;
for (j = 0; j < bl; j++) {
out(hex[(p[j] >> 4) & 0x0F], arg);
out(hex[p[j] & 0x0F], arg);
}
return 2 * bl;
}
size_t mg_print_base64(void (*out)(char, void *), void *arg, va_list *ap) {
size_t len = (size_t) va_arg(*ap, int);
uint8_t *buf = va_arg(*ap, uint8_t *);
return bcpy(out, arg, buf, len);
}
size_t mg_print_esc(void (*out)(char, void *), void *arg, va_list *ap) {
size_t len = (size_t) va_arg(*ap, int);
char *p = va_arg(*ap, char *);
if (len == 0) len = p == NULL ? 0 : strlen(p);
return qcpy(out, arg, p, len);
}
#ifdef MG_ENABLE_LINES
#line 1 "src/queue.c"
#endif
#if (defined(__GNUC__) && (__GNUC__ > 4) || \
(defined(__GNUC_MINOR__) && __GNUC__ == 4 && __GNUC_MINOR__ >= 1)) || \
defined(__clang__)
#define MG_MEMORY_BARRIER() __sync_synchronize()
#elif defined(_MSC_VER) && _MSC_VER >= 1700
#define MG_MEMORY_BARRIER() MemoryBarrier()
#elif !defined(MG_MEMORY_BARRIER)
#define MG_MEMORY_BARRIER()
#endif
// Every message in a queue is prepended by a 32-bit message length (ML).
// If ML is 0, then it is the end, and reader must wrap to the beginning.
//
// Queue when q->tail <= q->head:
// |----- free -----| ML | message1 | ML | message2 | ----- free ------|
// ^ ^ ^ ^
// buf tail head len
//
// Queue when q->tail > q->head:
// | ML | message2 |----- free ------| ML | message1 | 0 |---- free ----|
// ^ ^ ^ ^
// buf head tail len
void mg_queue_init(struct mg_queue *q, char *buf, size_t size) {
q->size = size;
q->buf = buf;
q->head = q->tail = 0;
}
static size_t mg_queue_read_len(struct mg_queue *q) {
uint32_t n = 0;
MG_MEMORY_BARRIER();
memcpy(&n, q->buf + q->tail, sizeof(n));
assert(q->tail + n + sizeof(n) <= q->size);
return n;
}
static void mg_queue_write_len(struct mg_queue *q, size_t len) {
uint32_t n = (uint32_t) len;
memcpy(q->buf + q->head, &n, sizeof(n));
MG_MEMORY_BARRIER();
}
size_t mg_queue_book(struct mg_queue *q, char **buf, size_t len) {
size_t space = 0, hs = sizeof(uint32_t) * 2; // *2 is for the 0 marker
if (q->head >= q->tail && q->head + len + hs <= q->size) {
space = q->size - q->head - hs; // There is enough space
} else if (q->head >= q->tail && q->tail > hs) {
mg_queue_write_len(q, 0); // Not enough space ahead
q->head = 0; // Wrap head to the beginning
}
if (q->head + hs + len < q->tail) space = q->tail - q->head - hs;
if (buf != NULL) *buf = q->buf + q->head + sizeof(uint32_t);
return space;
}
size_t mg_queue_next(struct mg_queue *q, char **buf) {
size_t len = 0;
if (q->tail != q->head) {
len = mg_queue_read_len(q);
if (len == 0) { // Zero (head wrapped) ?
q->tail = 0; // Reset tail to the start
if (q->head > q->tail) len = mg_queue_read_len(q); // Read again
}
}
if (buf != NULL) *buf = q->buf + q->tail + sizeof(uint32_t);
assert(q->tail + len <= q->size);
return len;
}
void mg_queue_add(struct mg_queue *q, size_t len) {
assert(len > 0);
mg_queue_write_len(q, len);
assert(q->head + sizeof(uint32_t) * 2 + len <= q->size);
q->head += len + sizeof(uint32_t);
}
void mg_queue_del(struct mg_queue *q, size_t len) {
q->tail += len + sizeof(uint32_t);
assert(q->tail + sizeof(uint32_t) <= q->size);
}
#ifdef MG_ENABLE_LINES
#line 1 "src/rpc.c"
#endif
void mg_rpc_add(struct mg_rpc **head, struct mg_str method,
void (*fn)(struct mg_rpc_req *), void *fn_data) {
struct mg_rpc *rpc = (struct mg_rpc *) calloc(1, sizeof(*rpc));
if (rpc != NULL) {
rpc->method = mg_strdup(method), rpc->fn = fn, rpc->fn_data = fn_data;
rpc->next = *head, *head = rpc;
}
}
void mg_rpc_del(struct mg_rpc **head, void (*fn)(struct mg_rpc_req *)) {
struct mg_rpc *r;
while ((r = *head) != NULL) {
if (r->fn == fn || fn == NULL) {
*head = r->next;
free((void *) r->method.ptr);
free(r);
} else {
head = &(*head)->next;
}
}
}
static void mg_rpc_call(struct mg_rpc_req *r, struct mg_str method) {
struct mg_rpc *h = r->head == NULL ? NULL : *r->head;
while (h != NULL && !mg_match(method, h->method, NULL)) h = h->next;
if (h != NULL) {
r->rpc = h;
h->fn(r);
} else {
mg_rpc_err(r, -32601, "\"%.*s not found\"", (int) method.len, method.ptr);
}
}
void mg_rpc_process(struct mg_rpc_req *r) {
int len, off = mg_json_get(r->frame, "$.method", &len);
if (off > 0 && r->frame.ptr[off] == '"') {
struct mg_str method = mg_str_n(&r->frame.ptr[off + 1], (size_t) len - 2);
mg_rpc_call(r, method);
} else if ((off = mg_json_get(r->frame, "$.result", &len)) > 0 ||
(off = mg_json_get(r->frame, "$.error", &len)) > 0) {
mg_rpc_call(r, mg_str("")); // JSON response! call "" method handler
} else {
mg_rpc_err(r, -32700, "%m", mg_print_esc, (int) r->frame.len,
r->frame.ptr); // Invalid
}
}
void mg_rpc_vok(struct mg_rpc_req *r, const char *fmt, va_list *ap) {
int len, off = mg_json_get(r->frame, "$.id", &len);
if (off > 0) {
mg_xprintf(r->pfn, r->pfn_data, "{%m:%.*s,%m:", mg_print_esc, 0, "id", len,
&r->frame.ptr[off], mg_print_esc, 0, "result");
mg_vxprintf(r->pfn, r->pfn_data, fmt == NULL ? "null" : fmt, ap);
mg_xprintf(r->pfn, r->pfn_data, "}");
}
}
void mg_rpc_ok(struct mg_rpc_req *r, const char *fmt, ...) {
va_list ap;
va_start(ap, fmt);
mg_rpc_vok(r, fmt, &ap);
va_end(ap);
}
void mg_rpc_verr(struct mg_rpc_req *r, int code, const char *fmt, va_list *ap) {
int len, off = mg_json_get(r->frame, "$.id", &len);
mg_xprintf(r->pfn, r->pfn_data, "{");
if (off > 0) {
mg_xprintf(r->pfn, r->pfn_data, "%m:%.*s,", mg_print_esc, 0, "id", len,
&r->frame.ptr[off]);
}
mg_xprintf(r->pfn, r->pfn_data, "%m:{%m:%d,%m:", mg_print_esc, 0, "error",
mg_print_esc, 0, "code", code, mg_print_esc, 0, "message");
mg_vxprintf(r->pfn, r->pfn_data, fmt == NULL ? "null" : fmt, ap);
mg_xprintf(r->pfn, r->pfn_data, "}}");
}
void mg_rpc_err(struct mg_rpc_req *r, int code, const char *fmt, ...) {
va_list ap;
va_start(ap, fmt);
mg_rpc_verr(r, code, fmt, &ap);
va_end(ap);
}
static size_t print_methods(mg_pfn_t pfn, void *pfn_data, va_list *ap) {
struct mg_rpc *h, **head = (struct mg_rpc **) va_arg(*ap, void **);
size_t len = 0;
for (h = *head; h != NULL; h = h->next) {
if (h->method.len == 0) continue; // Ignore response handler
len += mg_xprintf(pfn, pfn_data, "%s%m", h == *head ? "" : ",",
mg_print_esc, (int) h->method.len, h->method.ptr);
}
return len;
}
void mg_rpc_list(struct mg_rpc_req *r) {
mg_rpc_ok(r, "[%M]", print_methods, r->head);
}
#ifdef MG_ENABLE_LINES
#line 1 "src/sha1.c"
#endif
/* Copyright(c) By Steve Reid <steve@edmweb.com> */
/* 100% Public Domain */
union char64long16 {
unsigned char c[64];
uint32_t l[16];
};
#define rol(value, bits) (((value) << (bits)) | ((value) >> (32 - (bits))))
static uint32_t blk0(union char64long16 *block, int i) {
if (MG_BIG_ENDIAN) {
} else {
block->l[i] = (rol(block->l[i], 24) & 0xFF00FF00) |
(rol(block->l[i], 8) & 0x00FF00FF);
}
return block->l[i];
}
/* Avoid redefine warning (ARM /usr/include/sys/ucontext.h define R0~R4) */
#undef blk
#undef R0
#undef R1
#undef R2
#undef R3
#undef R4
#define blk(i) \
(block->l[i & 15] = rol(block->l[(i + 13) & 15] ^ block->l[(i + 8) & 15] ^ \
block->l[(i + 2) & 15] ^ block->l[i & 15], \
1))
#define R0(v, w, x, y, z, i) \
z += ((w & (x ^ y)) ^ y) + blk0(block, i) + 0x5A827999 + rol(v, 5); \
w = rol(w, 30);
#define R1(v, w, x, y, z, i) \
z += ((w & (x ^ y)) ^ y) + blk(i) + 0x5A827999 + rol(v, 5); \
w = rol(w, 30);
#define R2(v, w, x, y, z, i) \
z += (w ^ x ^ y) + blk(i) + 0x6ED9EBA1 + rol(v, 5); \
w = rol(w, 30);
#define R3(v, w, x, y, z, i) \
z += (((w | x) & y) | (w & x)) + blk(i) + 0x8F1BBCDC + rol(v, 5); \
w = rol(w, 30);
#define R4(v, w, x, y, z, i) \
z += (w ^ x ^ y) + blk(i) + 0xCA62C1D6 + rol(v, 5); \
w = rol(w, 30);
static void mg_sha1_transform(uint32_t state[5],
const unsigned char *buffer) {
uint32_t a, b, c, d, e;
union char64long16 block[1];
memcpy(block, buffer, 64);
a = state[0];
b = state[1];
c = state[2];
d = state[3];
e = state[4];
R0(a, b, c, d, e, 0);
R0(e, a, b, c, d, 1);
R0(d, e, a, b, c, 2);
R0(c, d, e, a, b, 3);
R0(b, c, d, e, a, 4);
R0(a, b, c, d, e, 5);
R0(e, a, b, c, d, 6);
R0(d, e, a, b, c, 7);
R0(c, d, e, a, b, 8);
R0(b, c, d, e, a, 9);
R0(a, b, c, d, e, 10);
R0(e, a, b, c, d, 11);
R0(d, e, a, b, c, 12);
R0(c, d, e, a, b, 13);
R0(b, c, d, e, a, 14);
R0(a, b, c, d, e, 15);
R1(e, a, b, c, d, 16);
R1(d, e, a, b, c, 17);
R1(c, d, e, a, b, 18);
R1(b, c, d, e, a, 19);
R2(a, b, c, d, e, 20);
R2(e, a, b, c, d, 21);
R2(d, e, a, b, c, 22);
R2(c, d, e, a, b, 23);
R2(b, c, d, e, a, 24);
R2(a, b, c, d, e, 25);
R2(e, a, b, c, d, 26);
R2(d, e, a, b, c, 27);
R2(c, d, e, a, b, 28);
R2(b, c, d, e, a, 29);
R2(a, b, c, d, e, 30);
R2(e, a, b, c, d, 31);
R2(d, e, a, b, c, 32);
R2(c, d, e, a, b, 33);
R2(b, c, d, e, a, 34);
R2(a, b, c, d, e, 35);
R2(e, a, b, c, d, 36);
R2(d, e, a, b, c, 37);
R2(c, d, e, a, b, 38);
R2(b, c, d, e, a, 39);
R3(a, b, c, d, e, 40);
R3(e, a, b, c, d, 41);
R3(d, e, a, b, c, 42);
R3(c, d, e, a, b, 43);
R3(b, c, d, e, a, 44);
R3(a, b, c, d, e, 45);
R3(e, a, b, c, d, 46);
R3(d, e, a, b, c, 47);
R3(c, d, e, a, b, 48);
R3(b, c, d, e, a, 49);
R3(a, b, c, d, e, 50);
R3(e, a, b, c, d, 51);
R3(d, e, a, b, c, 52);
R3(c, d, e, a, b, 53);
R3(b, c, d, e, a, 54);
R3(a, b, c, d, e, 55);
R3(e, a, b, c, d, 56);
R3(d, e, a, b, c, 57);
R3(c, d, e, a, b, 58);
R3(b, c, d, e, a, 59);
R4(a, b, c, d, e, 60);
R4(e, a, b, c, d, 61);
R4(d, e, a, b, c, 62);
R4(c, d, e, a, b, 63);
R4(b, c, d, e, a, 64);
R4(a, b, c, d, e, 65);
R4(e, a, b, c, d, 66);
R4(d, e, a, b, c, 67);
R4(c, d, e, a, b, 68);
R4(b, c, d, e, a, 69);
R4(a, b, c, d, e, 70);
R4(e, a, b, c, d, 71);
R4(d, e, a, b, c, 72);
R4(c, d, e, a, b, 73);
R4(b, c, d, e, a, 74);
R4(a, b, c, d, e, 75);
R4(e, a, b, c, d, 76);
R4(d, e, a, b, c, 77);
R4(c, d, e, a, b, 78);
R4(b, c, d, e, a, 79);
state[0] += a;
state[1] += b;
state[2] += c;
state[3] += d;
state[4] += e;
/* Erase working structures. The order of operations is important,
* used to ensure that compiler doesn't optimize those out. */
memset(block, 0, sizeof(block));
a = b = c = d = e = 0;
(void) a;
(void) b;
(void) c;
(void) d;
(void) e;
}
void mg_sha1_init(mg_sha1_ctx *context) {
context->state[0] = 0x67452301;
context->state[1] = 0xEFCDAB89;
context->state[2] = 0x98BADCFE;
context->state[3] = 0x10325476;
context->state[4] = 0xC3D2E1F0;
context->count[0] = context->count[1] = 0;
}
void mg_sha1_update(mg_sha1_ctx *context, const unsigned char *data,
size_t len) {
size_t i, j;
j = context->count[0];
if ((context->count[0] += (uint32_t) len << 3) < j) context->count[1]++;
context->count[1] += (uint32_t) (len >> 29);
j = (j >> 3) & 63;
if ((j + len) > 63) {
memcpy(&context->buffer[j], data, (i = 64 - j));
mg_sha1_transform(context->state, context->buffer);
for (; i + 63 < len; i += 64) {
mg_sha1_transform(context->state, &data[i]);
}
j = 0;
} else
i = 0;
memcpy(&context->buffer[j], &data[i], len - i);
}
void mg_sha1_final(unsigned char digest[20], mg_sha1_ctx *context) {
unsigned i;
unsigned char finalcount[8], c;
for (i = 0; i < 8; i++) {
finalcount[i] = (unsigned char) ((context->count[(i >= 4 ? 0 : 1)] >>
((3 - (i & 3)) * 8)) &
255);
}
c = 0200;
mg_sha1_update(context, &c, 1);
while ((context->count[0] & 504) != 448) {
c = 0000;
mg_sha1_update(context, &c, 1);
}
mg_sha1_update(context, finalcount, 8);
for (i = 0; i < 20; i++) {
digest[i] =
(unsigned char) ((context->state[i >> 2] >> ((3 - (i & 3)) * 8)) & 255);
}
memset(context, '\0', sizeof(*context));
memset(&finalcount, '\0', sizeof(finalcount));
}
#ifdef MG_ENABLE_LINES
#line 1 "src/sha256.c"
#endif
#define ror(x, n) (((x) >> (n)) | ((x) << (32 - (n))))
#define ch(x, y, z) (((x) & (y)) ^ (~(x) & (z)))
#define maj(x, y, z) (((x) & (y)) ^ ((x) & (z)) ^ ((y) & (z)))
#define ep0(x) (ror(x, 2) ^ ror(x, 13) ^ ror(x, 22))
#define ep1(x) (ror(x, 6) ^ ror(x, 11) ^ ror(x, 25))
#define sig0(x) (ror(x, 7) ^ ror(x, 18) ^ ((x) >> 3))
#define sig1(x) (ror(x, 17) ^ ror(x, 19) ^ ((x) >> 10))
static const uint32_t mg_sha256_k[64] = {
0x428a2f98, 0x71374491, 0xb5c0fbcf, 0xe9b5dba5, 0x3956c25b, 0x59f111f1,
0x923f82a4, 0xab1c5ed5, 0xd807aa98, 0x12835b01, 0x243185be, 0x550c7dc3,
0x72be5d74, 0x80deb1fe, 0x9bdc06a7, 0xc19bf174, 0xe49b69c1, 0xefbe4786,
0x0fc19dc6, 0x240ca1cc, 0x2de92c6f, 0x4a7484aa, 0x5cb0a9dc, 0x76f988da,
0x983e5152, 0xa831c66d, 0xb00327c8, 0xbf597fc7, 0xc6e00bf3, 0xd5a79147,
0x06ca6351, 0x14292967, 0x27b70a85, 0x2e1b2138, 0x4d2c6dfc, 0x53380d13,
0x650a7354, 0x766a0abb, 0x81c2c92e, 0x92722c85, 0xa2bfe8a1, 0xa81a664b,
0xc24b8b70, 0xc76c51a3, 0xd192e819, 0xd6990624, 0xf40e3585, 0x106aa070,
0x19a4c116, 0x1e376c08, 0x2748774c, 0x34b0bcb5, 0x391c0cb3, 0x4ed8aa4a,
0x5b9cca4f, 0x682e6ff3, 0x748f82ee, 0x78a5636f, 0x84c87814, 0x8cc70208,
0x90befffa, 0xa4506ceb, 0xbef9a3f7, 0xc67178f2};
void mg_sha256_init(mg_sha256_ctx *ctx) {
ctx->len = 0;
ctx->bits = 0;
ctx->state[0] = 0x6a09e667;
ctx->state[1] = 0xbb67ae85;
ctx->state[2] = 0x3c6ef372;
ctx->state[3] = 0xa54ff53a;
ctx->state[4] = 0x510e527f;
ctx->state[5] = 0x9b05688c;
ctx->state[6] = 0x1f83d9ab;
ctx->state[7] = 0x5be0cd19;
}
static void mg_sha256_chunk(mg_sha256_ctx *ctx) {
int i, j;
uint32_t a, b, c, d, e, f, g, h;
uint32_t m[64];
for (i = 0, j = 0; i < 16; ++i, j += 4)
m[i] = (uint32_t) ((ctx->buffer[j] << 24) | (ctx->buffer[j + 1] << 16) |
(ctx->buffer[j + 2] << 8) | (ctx->buffer[j + 3]));
for (; i < 64; ++i)
m[i] = sig1(m[i - 2]) + m[i - 7] + sig0(m[i - 15]) + m[i - 16];
a = ctx->state[0];
b = ctx->state[1];
c = ctx->state[2];
d = ctx->state[3];
e = ctx->state[4];
f = ctx->state[5];
g = ctx->state[6];
h = ctx->state[7];
for (i = 0; i < 64; ++i) {
uint32_t t1 = h + ep1(e) + ch(e, f, g) + mg_sha256_k[i] + m[i];
uint32_t t2 = ep0(a) + maj(a, b, c);
h = g;
g = f;
f = e;
e = d + t1;
d = c;
c = b;
b = a;
a = t1 + t2;
}
ctx->state[0] += a;
ctx->state[1] += b;
ctx->state[2] += c;
ctx->state[3] += d;
ctx->state[4] += e;
ctx->state[5] += f;
ctx->state[6] += g;
ctx->state[7] += h;
}
void mg_sha256_update(mg_sha256_ctx *ctx, const unsigned char *data,
size_t len) {
size_t i;
for (i = 0; i < len; i++) {
ctx->buffer[ctx->len] = data[i];
if ((++ctx->len) == 64) {
mg_sha256_chunk(ctx);
ctx->bits += 512;
ctx->len = 0;
}
}
}
// TODO: make final reusable (remove side effects)
void mg_sha256_final(unsigned char digest[32], mg_sha256_ctx *ctx) {
uint32_t i = ctx->len;
if (i < 56) {
ctx->buffer[i++] = 0x80;
while (i < 56) {
ctx->buffer[i++] = 0x00;
}
} else {
ctx->buffer[i++] = 0x80;
while (i < 64) {
ctx->buffer[i++] = 0x00;
}
mg_sha256_chunk(ctx);
memset(ctx->buffer, 0, 56);
}
ctx->bits += ctx->len * 8;
ctx->buffer[63] = (uint8_t) ((ctx->bits) & 0xff);
ctx->buffer[62] = (uint8_t) ((ctx->bits >> 8) & 0xff);
ctx->buffer[61] = (uint8_t) ((ctx->bits >> 16) & 0xff);
ctx->buffer[60] = (uint8_t) ((ctx->bits >> 24) & 0xff);
ctx->buffer[59] = (uint8_t) ((ctx->bits >> 32) & 0xff);
ctx->buffer[58] = (uint8_t) ((ctx->bits >> 40) & 0xff);
ctx->buffer[57] = (uint8_t) ((ctx->bits >> 48) & 0xff);
ctx->buffer[56] = (uint8_t) ((ctx->bits >> 56) & 0xff);
mg_sha256_chunk(ctx);
for (i = 0; i < 4; ++i) {
digest[i] = (ctx->state[0] >> (24 - i * 8)) & 0xff;
digest[i + 4] = (ctx->state[1] >> (24 - i * 8)) & 0xff;
digest[i + 8] = (ctx->state[2] >> (24 - i * 8)) & 0xff;
digest[i + 12] = (ctx->state[3] >> (24 - i * 8)) & 0xff;
digest[i + 16] = (ctx->state[4] >> (24 - i * 8)) & 0xff;
digest[i + 20] = (ctx->state[5] >> (24 - i * 8)) & 0xff;
digest[i + 24] = (ctx->state[6] >> (24 - i * 8)) & 0xff;
digest[i + 28] = (ctx->state[7] >> (24 - i * 8)) & 0xff;
}
}
void mg_hmac_sha256(uint8_t dst[32], uint8_t *key, size_t keysz, uint8_t *data,
size_t datasz) {
mg_sha256_ctx ctx;
uint8_t k[64] = {0};
uint8_t o_pad[64], i_pad[64];
unsigned int i;
memset(i_pad, 0x36, sizeof(i_pad));
memset(o_pad, 0x5c, sizeof(o_pad));
if (keysz < 64) {
memmove(k, key, keysz);
} else {
mg_sha256_init(&ctx);
mg_sha256_update(&ctx, key, keysz);
mg_sha256_final(k, &ctx);
}
for (i = 0; i < sizeof(k); i++) {
i_pad[i] ^= k[i];
o_pad[i] ^= k[i];
}
mg_sha256_init(&ctx);
mg_sha256_update(&ctx, i_pad, sizeof(i_pad));
mg_sha256_update(&ctx, data, datasz);
mg_sha256_final(dst, &ctx);
mg_sha256_init(&ctx);
mg_sha256_update(&ctx, o_pad, sizeof(o_pad));
mg_sha256_update(&ctx, dst, 32);
mg_sha256_final(dst, &ctx);
}
#ifdef MG_ENABLE_LINES
#line 1 "src/sntp.c"
#endif
#define SNTP_TIME_OFFSET 2208988800U // (1970 - 1900) in seconds
#define SNTP_MAX_FRAC 4294967295.0 // 2 ** 32 - 1
static int64_t gettimestamp(const uint32_t *data) {
uint32_t sec = mg_ntohl(data[0]), frac = mg_ntohl(data[1]);
if (sec) sec -= SNTP_TIME_OFFSET;
return ((int64_t) sec) * 1000 + (int64_t) (frac / SNTP_MAX_FRAC * 1000.0);
}
int64_t mg_sntp_parse(const unsigned char *buf, size_t len) {
int64_t res = -1;
int mode = len > 0 ? buf[0] & 7 : 0;
int version = len > 0 ? (buf[0] >> 3) & 7 : 0;
if (len < 48) {
MG_ERROR(("%s", "corrupt packet"));
} else if (mode != 4 && mode != 5) {
MG_ERROR(("%s", "not a server reply"));
} else if (buf[1] == 0) {
MG_ERROR(("%s", "server sent a kiss of death"));
} else if (version == 4 || version == 3) {
// int64_t ref = gettimestamp((uint32_t *) &buf[16]);
int64_t t0 = gettimestamp((uint32_t *) &buf[24]);
int64_t t1 = gettimestamp((uint32_t *) &buf[32]);
int64_t t2 = gettimestamp((uint32_t *) &buf[40]);
int64_t t3 = (int64_t) mg_millis();
int64_t delta = (t3 - t0) - (t2 - t1);
MG_VERBOSE(("%lld %lld %lld %lld delta:%lld", t0, t1, t2, t3, delta));
res = t2 + delta / 2;
} else {
MG_ERROR(("unexpected version: %d", version));
}
return res;
}
static void sntp_cb(struct mg_connection *c, int ev, void *ev_data) {
if (ev == MG_EV_READ) {
int64_t milliseconds = mg_sntp_parse(c->recv.buf, c->recv.len);
if (milliseconds > 0) {
MG_INFO(("%lu got time: %lld ms from epoch", c->id, milliseconds));
mg_call(c, MG_EV_SNTP_TIME, (uint64_t *) &milliseconds);
MG_VERBOSE(("%u.%u", (unsigned) (milliseconds / 1000),
(unsigned) (milliseconds % 1000)));
}
mg_iobuf_del(&c->recv, 0, c->recv.len); // Free receive buffer
} else if (ev == MG_EV_CONNECT) {
mg_sntp_request(c);
} else if (ev == MG_EV_CLOSE) {
}
(void) ev_data;
}
void mg_sntp_request(struct mg_connection *c) {
if (c->is_resolving) {
MG_ERROR(("%lu wait until resolved", c->id));
} else {
int64_t now = (int64_t) mg_millis(); // Use int64_t, for vc98
uint8_t buf[48] = {0};
uint32_t *t = (uint32_t *) &buf[40];
double frac = ((double) (now % 1000)) / 1000.0 * SNTP_MAX_FRAC;
buf[0] = (0 << 6) | (4 << 3) | 3;
t[0] = mg_htonl((uint32_t) (now / 1000) + SNTP_TIME_OFFSET);
t[1] = mg_htonl((uint32_t) frac);
mg_send(c, buf, sizeof(buf));
}
}
struct mg_connection *mg_sntp_connect(struct mg_mgr *mgr, const char *url,
mg_event_handler_t fn, void *fnd) {
struct mg_connection *c = NULL;
if (url == NULL) url = "udp://time.google.com:123";
if ((c = mg_connect(mgr, url, fn, fnd)) != NULL) c->pfn = sntp_cb;
return c;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/sock.c"
#endif
#if MG_ENABLE_SOCKET
#ifndef closesocket
#define closesocket(x) close(x)
#endif
#define FD(c_) ((MG_SOCKET_TYPE) (size_t) (c_)->fd)
#define S2PTR(s_) ((void *) (size_t) (s_))
#ifndef MSG_NONBLOCKING
#define MSG_NONBLOCKING 0
#endif
#ifndef AF_INET6
#define AF_INET6 10
#endif
#ifndef MG_SOCK_ERR
#define MG_SOCK_ERR(errcode) ((errcode) < 0 ? errno : 0)
#endif
#ifndef MG_SOCK_INTR
#define MG_SOCK_INTR(fd) (fd == MG_INVALID_SOCKET && MG_SOCK_ERR(-1) == EINTR)
#endif
#ifndef MG_SOCK_PENDING
#define MG_SOCK_PENDING(errcode) \
(((errcode) < 0) && (errno == EINPROGRESS || errno == EWOULDBLOCK))
#endif
#ifndef MG_SOCK_RESET
#define MG_SOCK_RESET(errcode) \
(((errcode) < 0) && (errno == EPIPE || errno == ECONNRESET))
#endif
union usa {
struct sockaddr sa;
struct sockaddr_in sin;
#if MG_ENABLE_IPV6
struct sockaddr_in6 sin6;
#endif
};
static socklen_t tousa(struct mg_addr *a, union usa *usa) {
socklen_t len = sizeof(usa->sin);
memset(usa, 0, sizeof(*usa));
usa->sin.sin_family = AF_INET;
usa->sin.sin_port = a->port;
memcpy(&usa->sin.sin_addr, a->ip, sizeof(uint32_t));
#if MG_ENABLE_IPV6
if (a->is_ip6) {
usa->sin.sin_family = AF_INET6;
usa->sin6.sin6_port = a->port;
usa->sin6.sin6_scope_id = a->scope_id;
memcpy(&usa->sin6.sin6_addr, a->ip, sizeof(a->ip));
len = sizeof(usa->sin6);
}
#endif
return len;
}
static void tomgaddr(union usa *usa, struct mg_addr *a, bool is_ip6) {
a->is_ip6 = is_ip6;
a->port = usa->sin.sin_port;
memcpy(&a->ip, &usa->sin.sin_addr, sizeof(uint32_t));
#if MG_ENABLE_IPV6
if (is_ip6) {
memcpy(a->ip, &usa->sin6.sin6_addr, sizeof(a->ip));
a->port = usa->sin6.sin6_port;
a->scope_id = (uint8_t) usa->sin6.sin6_scope_id;
}
#endif
}
static void setlocaddr(MG_SOCKET_TYPE fd, struct mg_addr *addr) {
union usa usa;
socklen_t n = sizeof(usa);
if (getsockname(fd, &usa.sa, &n) == 0) {
tomgaddr(&usa, addr, n != sizeof(usa.sin));
}
}
static void iolog(struct mg_connection *c, char *buf, long n, bool r) {
if (n == MG_IO_WAIT) {
// Do nothing
} else if (n <= 0) {
c->is_closing = 1; // Termination. Don't call mg_error(): #1529
} else if (n > 0) {
if (c->is_hexdumping) {
union usa usa;
socklen_t slen = sizeof(usa.sin);
if (getsockname(FD(c), &usa.sa, &slen) < 0) (void) 0; // Ignore result
MG_INFO(("\n-- %lu %M %s %M %ld", c->id, mg_print_ip_port, &c->loc,
r ? "<-" : "->", mg_print_ip_port, &c->rem, n));
mg_hexdump(buf, (size_t) n);
}
if (r) {
c->recv.len += (size_t) n;
mg_call(c, MG_EV_READ, &n);
} else {
mg_iobuf_del(&c->send, 0, (size_t) n);
// if (c->send.len == 0) mg_iobuf_resize(&c->send, 0);
if (c->send.len == 0) {
MG_EPOLL_MOD(c, 0);
}
mg_call(c, MG_EV_WRITE, &n);
}
}
}
long mg_io_send(struct mg_connection *c, const void *buf, size_t len) {
long n;
if (c->is_udp) {
union usa usa;
socklen_t slen = tousa(&c->rem, &usa);
n = sendto(FD(c), (char *) buf, len, 0, &usa.sa, slen);
if (n > 0) setlocaddr(FD(c), &c->loc);
} else {
n = send(FD(c), (char *) buf, len, MSG_NONBLOCKING);
}
if (MG_SOCK_PENDING(n)) return MG_IO_WAIT;
if (MG_SOCK_RESET(n)) return MG_IO_RESET;
if (n <= 0) return MG_IO_ERR;
return n;
}
bool mg_send(struct mg_connection *c, const void *buf, size_t len) {
if (c->is_udp) {
long n = mg_io_send(c, buf, len);
MG_DEBUG(("%lu %ld %d:%d %ld err %d", c->id, c->fd, (int) c->send.len,
(int) c->recv.len, n, MG_SOCK_ERR(n)));
iolog(c, (char *) buf, n, false);
return n > 0;
} else {
return mg_iobuf_add(&c->send, c->send.len, buf, len);
}
}
static void mg_set_non_blocking_mode(MG_SOCKET_TYPE fd) {
#if defined(MG_CUSTOM_NONBLOCK)
MG_CUSTOM_NONBLOCK(fd);
#elif MG_ARCH == MG_ARCH_WIN32 && MG_ENABLE_WINSOCK
unsigned long on = 1;
ioctlsocket(fd, FIONBIO, &on);
#elif MG_ENABLE_RL
unsigned long on = 1;
ioctlsocket(fd, FIONBIO, &on);
#elif MG_ENABLE_FREERTOS_TCP
const BaseType_t off = 0;
if (setsockopt(fd, 0, FREERTOS_SO_RCVTIMEO, &off, sizeof(off)) != 0) (void) 0;
if (setsockopt(fd, 0, FREERTOS_SO_SNDTIMEO, &off, sizeof(off)) != 0) (void) 0;
#elif MG_ENABLE_LWIP
lwip_fcntl(fd, F_SETFL, O_NONBLOCK);
#elif MG_ARCH == MG_ARCH_AZURERTOS
fcntl(fd, F_SETFL, O_NONBLOCK);
#elif MG_ARCH == MG_ARCH_TIRTOS
int val = 0;
setsockopt(fd, SOL_SOCKET, SO_BLOCKING, &val, sizeof(val));
// SPRU524J section 3.3.3 page 63, SO_SNDLOWAT
int sz = sizeof(val);
getsockopt(fd, SOL_SOCKET, SO_SNDBUF, &val, &sz);
val /= 2; // set send low-water mark at half send buffer size
setsockopt(fd, SOL_SOCKET, SO_SNDLOWAT, &val, sizeof(val));
#else
fcntl(fd, F_SETFL, fcntl(fd, F_GETFL, 0) | O_NONBLOCK); // Non-blocking mode
fcntl(fd, F_SETFD, FD_CLOEXEC); // Set close-on-exec
#endif
}
bool mg_open_listener(struct mg_connection *c, const char *url) {
MG_SOCKET_TYPE fd = MG_INVALID_SOCKET;
bool success = false;
c->loc.port = mg_htons(mg_url_port(url));
if (!mg_aton(mg_url_host(url), &c->loc)) {
MG_ERROR(("invalid listening URL: %s", url));
} else {
union usa usa;
socklen_t slen = tousa(&c->loc, &usa);
int rc, on = 1, af = c->loc.is_ip6 ? AF_INET6 : AF_INET;
int type = strncmp(url, "udp:", 4) == 0 ? SOCK_DGRAM : SOCK_STREAM;
int proto = type == SOCK_DGRAM ? IPPROTO_UDP : IPPROTO_TCP;
(void) on;
if ((fd = socket(af, type, proto)) == MG_INVALID_SOCKET) {
MG_ERROR(("socket: %d", MG_SOCK_ERR(-1)));
#if defined(SO_EXCLUSIVEADDRUSE)
} else if ((rc = setsockopt(fd, SOL_SOCKET, SO_EXCLUSIVEADDRUSE,
(char *) &on, sizeof(on))) != 0) {
// "Using SO_REUSEADDR and SO_EXCLUSIVEADDRUSE"
MG_ERROR(("setsockopt(SO_EXCLUSIVEADDRUSE): %d %d", on, MG_SOCK_ERR(rc)));
#elif defined(SO_REUSEADDR) && (!defined(LWIP_SOCKET) || SO_REUSE)
} else if ((rc = setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, (char *) &on,
sizeof(on))) != 0) {
// 1. SO_REUSEADDR semantics on UNIX and Windows is different. On
// Windows, SO_REUSEADDR allows to bind a socket to a port without error
// even if the port is already open by another program. This is not the
// behavior SO_REUSEADDR was designed for, and leads to hard-to-track
// failure scenarios.
//
// 2. For LWIP, SO_REUSEADDR should be explicitly enabled by defining
// SO_REUSE = 1 in lwipopts.h, otherwise the code below will compile but
// won't work! (setsockopt will return EINVAL)
MG_ERROR(("setsockopt(SO_REUSEADDR): %d", MG_SOCK_ERR(rc)));
#endif
#if MG_IPV6_V6ONLY
// Bind only to the V6 address, not V4 address on this port
} else if (c->loc.is_ip6 &&
(rc = setsockopt(fd, IPPROTO_IPV6, IPV6_V6ONLY, (char *) &on,
sizeof(on))) != 0) {
// See #2089. Allow to bind v4 and v6 sockets on the same port
MG_ERROR(("setsockopt(IPV6_V6ONLY): %d", MG_SOCK_ERR(rc)));
#endif
} else if ((rc = bind(fd, &usa.sa, slen)) != 0) {
MG_ERROR(("bind: %d", MG_SOCK_ERR(rc)));
} else if ((type == SOCK_STREAM &&
(rc = listen(fd, MG_SOCK_LISTEN_BACKLOG_SIZE)) != 0)) {
// NOTE(lsm): FreeRTOS uses backlog value as a connection limit
// In case port was set to 0, get the real port number
MG_ERROR(("listen: %d", MG_SOCK_ERR(rc)));
} else {
setlocaddr(fd, &c->loc);
mg_set_non_blocking_mode(fd);
c->fd = S2PTR(fd);
MG_EPOLL_ADD(c);
success = true;
}
}
if (success == false && fd != MG_INVALID_SOCKET) closesocket(fd);
return success;
}
static long recv_raw(struct mg_connection *c, void *buf, size_t len) {
long n = 0;
if (c->is_udp) {
union usa usa;
socklen_t slen = tousa(&c->rem, &usa);
n = recvfrom(FD(c), (char *) buf, len, 0, &usa.sa, &slen);
if (n > 0) tomgaddr(&usa, &c->rem, slen != sizeof(usa.sin));
} else {
n = recv(FD(c), (char *) buf, len, MSG_NONBLOCKING);
}
if (MG_SOCK_PENDING(n)) return MG_IO_WAIT;
if (MG_SOCK_RESET(n)) return MG_IO_RESET;
if (n <= 0) return MG_IO_ERR;
return n;
}
static bool ioalloc(struct mg_connection *c, struct mg_iobuf *io) {
bool res = false;
if (io->len >= MG_MAX_RECV_SIZE) {
mg_error(c, "MG_MAX_RECV_SIZE");
} else if (io->size <= io->len &&
!mg_iobuf_resize(io, io->size + MG_IO_SIZE)) {
mg_error(c, "OOM");
} else {
res = true;
}
return res;
}
// NOTE(lsm): do only one iteration of reads, cause some systems
// (e.g. FreeRTOS stack) return 0 instead of -1/EWOULDBLOCK when no data
static void read_conn(struct mg_connection *c) {
if (ioalloc(c, &c->recv)) {
char *buf = (char *) &c->recv.buf[c->recv.len];
size_t len = c->recv.size - c->recv.len;
long n = -1;
if (c->is_tls) {
if (!ioalloc(c, &c->rtls)) return;
n = recv_raw(c, (char *) &c->rtls.buf[c->rtls.len],
c->rtls.size - c->rtls.len);
// MG_DEBUG(("%lu %ld", c->id, n));
if (n == MG_IO_ERR && mg_tls_pending(c) == 0 && c->rtls.len == 0) {
c->is_closing = 1;
} else {
if (n > 0) c->rtls.len += (size_t) n;
if (c->is_tls_hs) mg_tls_handshake(c);
if (c->is_tls_hs) return;
n = mg_tls_recv(c, buf, len);
}
} else {
n = recv_raw(c, buf, len);
}
MG_DEBUG(("%lu %p snd %ld/%ld rcv %ld/%ld n=%ld err=%d", c->id, c->fd,
(long) c->send.len, (long) c->send.size, (long) c->recv.len,
(long) c->recv.size, n, MG_SOCK_ERR(n)));
iolog(c, buf, n, true);
}
}
static void write_conn(struct mg_connection *c) {
char *buf = (char *) c->send.buf;
size_t len = c->send.len;
long n = c->is_tls ? mg_tls_send(c, buf, len) : mg_io_send(c, buf, len);
MG_DEBUG(("%lu %ld snd %ld/%ld rcv %ld/%ld n=%ld err=%d", c->id, c->fd,
(long) c->send.len, (long) c->send.size, (long) c->recv.len,
(long) c->recv.size, n, MG_SOCK_ERR(n)));
iolog(c, buf, n, false);
}
static void close_conn(struct mg_connection *c) {
if (FD(c) != MG_INVALID_SOCKET) {
#if MG_ENABLE_EPOLL
epoll_ctl(c->mgr->epoll_fd, EPOLL_CTL_DEL, FD(c), NULL);
#endif
closesocket(FD(c));
#if MG_ENABLE_FREERTOS_TCP
FreeRTOS_FD_CLR(c->fd, c->mgr->ss, eSELECT_ALL);
#endif
}
mg_close_conn(c);
}
static void connect_conn(struct mg_connection *c) {
union usa usa;
socklen_t n = sizeof(usa);
// Use getpeername() to test whether we have connected
if (getpeername(FD(c), &usa.sa, &n) == 0) {
c->is_connecting = 0;
mg_call(c, MG_EV_CONNECT, NULL);
MG_EPOLL_MOD(c, 0);
if (c->is_tls_hs) mg_tls_handshake(c);
} else {
mg_error(c, "socket error");
}
}
static void setsockopts(struct mg_connection *c) {
#if MG_ENABLE_FREERTOS_TCP || MG_ARCH == MG_ARCH_AZURERTOS || \
MG_ARCH == MG_ARCH_TIRTOS
(void) c;
#else
int on = 1;
#if !defined(SOL_TCP)
#define SOL_TCP IPPROTO_TCP
#endif
if (setsockopt(FD(c), SOL_TCP, TCP_NODELAY, (char *) &on, sizeof(on)) != 0)
(void) 0;
if (setsockopt(FD(c), SOL_SOCKET, SO_KEEPALIVE, (char *) &on, sizeof(on)) !=
0)
(void) 0;
#endif
}
void mg_connect_resolved(struct mg_connection *c) {
int type = c->is_udp ? SOCK_DGRAM : SOCK_STREAM;
int rc, af = c->rem.is_ip6 ? AF_INET6 : AF_INET; // c->rem has resolved IP
c->fd = S2PTR(socket(af, type, 0)); // Create outbound socket
c->is_resolving = 0; // Clear resolving flag
if (FD(c) == MG_INVALID_SOCKET) {
mg_error(c, "socket(): %d", MG_SOCK_ERR(-1));
} else if (c->is_udp) {
MG_EPOLL_ADD(c);
#if MG_ARCH == MG_ARCH_TIRTOS
union usa usa; // TI-RTOS NDK requires binding to receive on UDP sockets
socklen_t slen = tousa(&c->loc, &usa);
if ((rc = bind(c->fd, &usa.sa, slen)) != 0)
MG_ERROR(("bind: %d", MG_SOCK_ERR(rc)));
#endif
mg_call(c, MG_EV_RESOLVE, NULL);
mg_call(c, MG_EV_CONNECT, NULL);
} else {
union usa usa;
socklen_t slen = tousa(&c->rem, &usa);
mg_set_non_blocking_mode(FD(c));
setsockopts(c);
MG_EPOLL_ADD(c);
mg_call(c, MG_EV_RESOLVE, NULL);
rc = connect(FD(c), &usa.sa, slen); // Attempt to connect
if (rc == 0) { // Success
mg_call(c, MG_EV_CONNECT, NULL); // Send MG_EV_CONNECT to the user
} else if (MG_SOCK_PENDING(rc)) { // Need to wait for TCP handshake
MG_DEBUG(("%lu %ld -> %M pend", c->id, c->fd, mg_print_ip_port, &c->rem));
c->is_connecting = 1;
} else {
mg_error(c, "connect: %d", MG_SOCK_ERR(rc));
}
}
}
static MG_SOCKET_TYPE raccept(MG_SOCKET_TYPE sock, union usa *usa,
socklen_t *len) {
MG_SOCKET_TYPE fd = MG_INVALID_SOCKET;
do {
memset(usa, 0, sizeof(*usa));
fd = accept(sock, &usa->sa, len);
} while (MG_SOCK_INTR(fd));
return fd;
}
static void accept_conn(struct mg_mgr *mgr, struct mg_connection *lsn) {
struct mg_connection *c = NULL;
union usa usa;
socklen_t sa_len = sizeof(usa);
MG_SOCKET_TYPE fd = raccept(FD(lsn), &usa, &sa_len);
if (fd == MG_INVALID_SOCKET) {
#if MG_ARCH == MG_ARCH_AZURERTOS || defined(__ECOS)
// AzureRTOS, in non-block socket mode can mark listening socket readable
// even it is not. See comment for 'select' func implementation in
// nx_bsd.c That's not an error, just should try later
if (errno != EAGAIN)
#endif
MG_ERROR(("%lu accept failed, errno %d", lsn->id, MG_SOCK_ERR(-1)));
#if (MG_ARCH != MG_ARCH_WIN32) && !MG_ENABLE_FREERTOS_TCP && \
(MG_ARCH != MG_ARCH_TIRTOS) && !MG_ENABLE_POLL && !MG_ENABLE_EPOLL
} else if ((long) fd >= FD_SETSIZE) {
MG_ERROR(("%ld > %ld", (long) fd, (long) FD_SETSIZE));
closesocket(fd);
#endif
} else if ((c = mg_alloc_conn(mgr)) == NULL) {
MG_ERROR(("%lu OOM", lsn->id));
closesocket(fd);
} else {
tomgaddr(&usa, &c->rem, sa_len != sizeof(usa.sin));
LIST_ADD_HEAD(struct mg_connection, &mgr->conns, c);
c->fd = S2PTR(fd);
MG_EPOLL_ADD(c);
mg_set_non_blocking_mode(FD(c));
setsockopts(c);
c->is_accepted = 1;
c->is_hexdumping = lsn->is_hexdumping;
c->loc = lsn->loc;
c->pfn = lsn->pfn;
c->pfn_data = lsn->pfn_data;
c->fn = lsn->fn;
c->fn_data = lsn->fn_data;
MG_DEBUG(("%lu %ld accepted %M -> %M", c->id, c->fd, mg_print_ip_port,
&c->rem, mg_print_ip_port, &c->loc));
mg_call(c, MG_EV_OPEN, NULL);
mg_call(c, MG_EV_ACCEPT, NULL);
}
}
static bool can_read(const struct mg_connection *c) {
return c->is_full == false;
}
static bool can_write(const struct mg_connection *c) {
return c->is_connecting || (c->send.len > 0 && c->is_tls_hs == 0);
}
static bool skip_iotest(const struct mg_connection *c) {
return (c->is_closing || c->is_resolving || FD(c) == MG_INVALID_SOCKET) ||
(can_read(c) == false && can_write(c) == false);
}
static void mg_iotest(struct mg_mgr *mgr, int ms) {
#if MG_ENABLE_FREERTOS_TCP
struct mg_connection *c;
for (c = mgr->conns; c != NULL; c = c->next) {
c->is_readable = c->is_writable = 0;
if (skip_iotest(c)) continue;
if (can_read(c))
FreeRTOS_FD_SET(c->fd, mgr->ss, eSELECT_READ | eSELECT_EXCEPT);
if (can_write(c)) FreeRTOS_FD_SET(c->fd, mgr->ss, eSELECT_WRITE);
if (c->is_closing) ms = 1;
}
FreeRTOS_select(mgr->ss, pdMS_TO_TICKS(ms));
for (c = mgr->conns; c != NULL; c = c->next) {
EventBits_t bits = FreeRTOS_FD_ISSET(c->fd, mgr->ss);
c->is_readable = bits & (eSELECT_READ | eSELECT_EXCEPT) ? 1U : 0;
c->is_writable = bits & eSELECT_WRITE ? 1U : 0;
if (c->fd != MG_INVALID_SOCKET)
FreeRTOS_FD_CLR(c->fd, mgr->ss,
eSELECT_READ | eSELECT_EXCEPT | eSELECT_WRITE);
}
#elif MG_ENABLE_EPOLL
size_t max = 1;
for (struct mg_connection *c = mgr->conns; c != NULL; c = c->next) {
c->is_readable = c->is_writable = 0;
if (mg_tls_pending(c) > 0) ms = 1, c->is_readable = 1;
if (can_write(c)) MG_EPOLL_MOD(c, 1);
if (c->is_closing) ms = 1;
max++;
}
struct epoll_event *evs = (struct epoll_event *) alloca(max * sizeof(evs[0]));
int n = epoll_wait(mgr->epoll_fd, evs, (int) max, ms);
for (int i = 0; i < n; i++) {
struct mg_connection *c = (struct mg_connection *) evs[i].data.ptr;
if (evs[i].events & EPOLLERR) {
mg_error(c, "socket error");
} else if (c->is_readable == 0) {
bool rd = evs[i].events & (EPOLLIN | EPOLLHUP);
bool wr = evs[i].events & EPOLLOUT;
c->is_readable = can_read(c) && rd ? 1U : 0;
c->is_writable = can_write(c) && wr ? 1U : 0;
}
}
(void) skip_iotest;
#elif MG_ENABLE_POLL
nfds_t n = 0;
for (struct mg_connection *c = mgr->conns; c != NULL; c = c->next) n++;
struct pollfd *fds = (struct pollfd *) alloca(n * sizeof(fds[0]));
memset(fds, 0, n * sizeof(fds[0]));
n = 0;
for (struct mg_connection *c = mgr->conns; c != NULL; c = c->next) {
c->is_readable = c->is_writable = 0;
if (skip_iotest(c)) {
// Socket not valid, ignore
} else if (mg_tls_pending(c) > 0) {
ms = 1; // Don't wait if TLS is ready
} else {
fds[n].fd = FD(c);
if (can_read(c)) fds[n].events |= POLLIN;
if (can_write(c)) fds[n].events |= POLLOUT;
if (c->is_closing) ms = 1;
n++;
}
}
// MG_INFO(("poll n=%d ms=%d", (int) n, ms));
if (poll(fds, n, ms) < 0) {
#if MG_ARCH == MG_ARCH_WIN32
if (n == 0) Sleep(ms); // On Windows, poll fails if no sockets
#endif
memset(fds, 0, n * sizeof(fds[0]));
}
n = 0;
for (struct mg_connection *c = mgr->conns; c != NULL; c = c->next) {
if (skip_iotest(c)) {
// Socket not valid, ignore
} else if (mg_tls_pending(c) > 0) {
c->is_readable = 1;
} else {
if (fds[n].revents & POLLERR) {
mg_error(c, "socket error");
} else {
c->is_readable =
(unsigned) (fds[n].revents & (POLLIN | POLLHUP) ? 1 : 0);
c->is_writable = (unsigned) (fds[n].revents & POLLOUT ? 1 : 0);
}
n++;
}
}
#else
struct timeval tv = {ms / 1000, (ms % 1000) * 1000}, tv_zero = {0, 0}, *tvp;
struct mg_connection *c;
fd_set rset, wset, eset;
MG_SOCKET_TYPE maxfd = 0;
int rc;
FD_ZERO(&rset);
FD_ZERO(&wset);
FD_ZERO(&eset);
tvp = ms < 0 ? NULL : &tv;
for (c = mgr->conns; c != NULL; c = c->next) {
c->is_readable = c->is_writable = 0;
if (skip_iotest(c)) continue;
FD_SET(FD(c), &eset);
if (can_read(c)) FD_SET(FD(c), &rset);
if (can_write(c)) FD_SET(FD(c), &wset);
if (mg_tls_pending(c) > 0) tvp = &tv_zero;
if (FD(c) > maxfd) maxfd = FD(c);
if (c->is_closing) ms = 1;
}
if ((rc = select((int) maxfd + 1, &rset, &wset, &eset, tvp)) < 0) {
#if MG_ARCH == MG_ARCH_WIN32
if (maxfd == 0) Sleep(ms); // On Windows, select fails if no sockets
#else
MG_ERROR(("select: %d %d", rc, MG_SOCK_ERR(rc)));
#endif
FD_ZERO(&rset);
FD_ZERO(&wset);
FD_ZERO(&eset);
}
for (c = mgr->conns; c != NULL; c = c->next) {
if (FD(c) != MG_INVALID_SOCKET && FD_ISSET(FD(c), &eset)) {
mg_error(c, "socket error");
} else {
c->is_readable = FD(c) != MG_INVALID_SOCKET && FD_ISSET(FD(c), &rset);
c->is_writable = FD(c) != MG_INVALID_SOCKET && FD_ISSET(FD(c), &wset);
if (mg_tls_pending(c) > 0) c->is_readable = 1;
}
}
#endif
}
static bool mg_socketpair(MG_SOCKET_TYPE sp[2], union usa usa[2]) {
socklen_t n = sizeof(usa[0].sin);
bool success = false;
sp[0] = sp[1] = MG_INVALID_SOCKET;
(void) memset(&usa[0], 0, sizeof(usa[0]));
usa[0].sin.sin_family = AF_INET;
*(uint32_t *) &usa->sin.sin_addr = mg_htonl(0x7f000001U); // 127.0.0.1
usa[1] = usa[0];
if ((sp[0] = socket(AF_INET, SOCK_DGRAM, 0)) != MG_INVALID_SOCKET &&
(sp[1] = socket(AF_INET, SOCK_DGRAM, 0)) != MG_INVALID_SOCKET &&
bind(sp[0], &usa[0].sa, n) == 0 && //
bind(sp[1], &usa[1].sa, n) == 0 && //
getsockname(sp[0], &usa[0].sa, &n) == 0 && //
getsockname(sp[1], &usa[1].sa, &n) == 0 && //
connect(sp[0], &usa[1].sa, n) == 0 && //
connect(sp[1], &usa[0].sa, n) == 0) { //
success = true;
}
if (!success) {
if (sp[0] != MG_INVALID_SOCKET) closesocket(sp[0]);
if (sp[1] != MG_INVALID_SOCKET) closesocket(sp[1]);
sp[0] = sp[1] = MG_INVALID_SOCKET;
}
return success;
}
// mg_wakeup() event handler
static void wufn(struct mg_connection *c, int ev, void *ev_data) {
if (ev == MG_EV_READ) {
unsigned long *id = (unsigned long *) c->recv.buf;
// MG_INFO(("Got data"));
// mg_hexdump(c->recv.buf, c->recv.len);
if (c->recv.len >= sizeof(*id)) {
struct mg_connection *t;
for (t = c->mgr->conns; t != NULL; t = t->next) {
if (t->id == *id) {
struct mg_str data = mg_str_n((char *) c->recv.buf + sizeof(*id),
c->recv.len - sizeof(*id));
mg_call(t, MG_EV_WAKEUP, &data);
}
}
}
c->recv.len = 0; // Consume received data
} else if (ev == MG_EV_CLOSE) {
closesocket(c->mgr->pipe); // When we're closing, close the other
c->mgr->pipe = MG_INVALID_SOCKET; // side of the socketpair, too
}
(void) ev_data;
}
bool mg_wakeup_init(struct mg_mgr *mgr) {
bool ok = false;
if (mgr->pipe == MG_INVALID_SOCKET) {
union usa usa[2];
MG_SOCKET_TYPE sp[2] = {MG_INVALID_SOCKET, MG_INVALID_SOCKET};
struct mg_connection *c = NULL;
if (!mg_socketpair(sp, usa)) {
MG_ERROR(("Cannot create socket pair"));
} else if ((c = mg_wrapfd(mgr, (int) sp[1], wufn, NULL)) == NULL) {
closesocket(sp[0]);
closesocket(sp[1]);
sp[0] = sp[1] = MG_INVALID_SOCKET;
} else {
tomgaddr(&usa[0], &c->rem, false);
MG_DEBUG(("%lu %p pipe %lu", c->id, c->fd, (unsigned long) sp[0]));
mgr->pipe = sp[0];
ok = true;
}
}
return ok;
}
bool mg_wakeup(struct mg_mgr *mgr, unsigned long conn_id, const void *buf,
size_t len) {
if (mgr->pipe != MG_INVALID_SOCKET && conn_id > 0) {
char *extended_buf = (char *) alloca(len + sizeof(conn_id));
memcpy(extended_buf, &conn_id, sizeof(conn_id));
memcpy(extended_buf + sizeof(conn_id), buf, len);
send(mgr->pipe, extended_buf, len + sizeof(conn_id), MSG_NONBLOCKING);
return true;
}
return false;
}
void mg_mgr_poll(struct mg_mgr *mgr, int ms) {
struct mg_connection *c, *tmp;
uint64_t now;
mg_iotest(mgr, ms);
now = mg_millis();
mg_timer_poll(&mgr->timers, now);
for (c = mgr->conns; c != NULL; c = tmp) {
bool is_resp = c->is_resp;
tmp = c->next;
mg_call(c, MG_EV_POLL, &now);
if (is_resp && !c->is_resp) {
long n = 0;
mg_call(c, MG_EV_READ, &n);
}
MG_VERBOSE(("%lu %c%c %c%c%c%c%c", c->id, c->is_readable ? 'r' : '-',
c->is_writable ? 'w' : '-', c->is_tls ? 'T' : 't',
c->is_connecting ? 'C' : 'c', c->is_tls_hs ? 'H' : 'h',
c->is_resolving ? 'R' : 'r', c->is_closing ? 'C' : 'c'));
if (c->is_resolving || c->is_closing) {
// Do nothing
} else if (c->is_listening && c->is_udp == 0) {
if (c->is_readable) accept_conn(mgr, c);
} else if (c->is_connecting) {
if (c->is_readable || c->is_writable) connect_conn(c);
//} else if (c->is_tls_hs) {
// if ((c->is_readable || c->is_writable)) mg_tls_handshake(c);
} else {
if (c->is_readable) read_conn(c);
if (c->is_writable) write_conn(c);
}
if (c->is_draining && c->send.len == 0) c->is_closing = 1;
if (c->is_closing) close_conn(c);
}
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/ssi.c"
#endif
#ifndef MG_MAX_SSI_DEPTH
#define MG_MAX_SSI_DEPTH 5
#endif
#ifndef MG_SSI_BUFSIZ
#define MG_SSI_BUFSIZ 1024
#endif
#if MG_ENABLE_SSI
static char *mg_ssi(const char *path, const char *root, int depth) {
struct mg_iobuf b = {NULL, 0, 0, MG_IO_SIZE};
FILE *fp = fopen(path, "rb");
if (fp != NULL) {
char buf[MG_SSI_BUFSIZ], arg[sizeof(buf)];
int ch, intag = 0;
size_t len = 0;
buf[0] = arg[0] = '\0';
while ((ch = fgetc(fp)) != EOF) {
if (intag && ch == '>' && buf[len - 1] == '-' && buf[len - 2] == '-') {
buf[len++] = (char) (ch & 0xff);
buf[len] = '\0';
if (sscanf(buf, "<!--#include file=\"%[^\"]", arg)) {
char tmp[MG_PATH_MAX + MG_SSI_BUFSIZ + 10],
*p = (char *) path + strlen(path), *data;
while (p > path && p[-1] != MG_DIRSEP && p[-1] != '/') p--;
mg_snprintf(tmp, sizeof(tmp), "%.*s%s", (int) (p - path), path, arg);
if (depth < MG_MAX_SSI_DEPTH &&
(data = mg_ssi(tmp, root, depth + 1)) != NULL) {
mg_iobuf_add(&b, b.len, data, strlen(data));
free(data);
} else {
MG_ERROR(("%s: file=%s error or too deep", path, arg));
}
} else if (sscanf(buf, "<!--#include virtual=\"%[^\"]", arg)) {
char tmp[MG_PATH_MAX + MG_SSI_BUFSIZ + 10], *data;
mg_snprintf(tmp, sizeof(tmp), "%s%s", root, arg);
if (depth < MG_MAX_SSI_DEPTH &&
(data = mg_ssi(tmp, root, depth + 1)) != NULL) {
mg_iobuf_add(&b, b.len, data, strlen(data));
free(data);
} else {
MG_ERROR(("%s: virtual=%s error or too deep", path, arg));
}
} else {
// Unknown SSI tag
MG_ERROR(("Unknown SSI tag: %.*s", (int) len, buf));
mg_iobuf_add(&b, b.len, buf, len);
}
intag = 0;
len = 0;
} else if (ch == '<') {
intag = 1;
if (len > 0) mg_iobuf_add(&b, b.len, buf, len);
len = 0;
buf[len++] = (char) (ch & 0xff);
} else if (intag) {
if (len == 5 && strncmp(buf, "<!--#", 5) != 0) {
intag = 0;
} else if (len >= sizeof(buf) - 2) {
MG_ERROR(("%s: SSI tag is too large", path));
len = 0;
}
buf[len++] = (char) (ch & 0xff);
} else {
buf[len++] = (char) (ch & 0xff);
if (len >= sizeof(buf)) {
mg_iobuf_add(&b, b.len, buf, len);
len = 0;
}
}
}
if (len > 0) mg_iobuf_add(&b, b.len, buf, len);
if (b.len > 0) mg_iobuf_add(&b, b.len, "", 1); // nul-terminate
fclose(fp);
}
(void) depth;
(void) root;
return (char *) b.buf;
}
void mg_http_serve_ssi(struct mg_connection *c, const char *root,
const char *fullpath) {
const char *headers = "Content-Type: text/html; charset=utf-8\r\n";
char *data = mg_ssi(fullpath, root, 0);
mg_http_reply(c, 200, headers, "%s", data == NULL ? "" : data);
free(data);
}
#else
void mg_http_serve_ssi(struct mg_connection *c, const char *root,
const char *fullpath) {
mg_http_reply(c, 501, NULL, "SSI not enabled");
(void) root, (void) fullpath;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/str.c"
#endif
struct mg_str mg_str_s(const char *s) {
struct mg_str str = {s, s == NULL ? 0 : strlen(s)};
return str;
}
struct mg_str mg_str_n(const char *s, size_t n) {
struct mg_str str = {s, n};
return str;
}
int mg_lower(const char *s) {
int c = *s;
if (c >= 'A' && c <= 'Z') c += 'a' - 'A';
return c;
}
int mg_ncasecmp(const char *s1, const char *s2, size_t len) {
int diff = 0;
if (len > 0) do {
diff = mg_lower(s1++) - mg_lower(s2++);
} while (diff == 0 && s1[-1] != '\0' && --len > 0);
return diff;
}
int mg_casecmp(const char *s1, const char *s2) {
return mg_ncasecmp(s1, s2, (size_t) ~0);
}
int mg_vcmp(const struct mg_str *s1, const char *s2) {
size_t n2 = strlen(s2), n1 = s1->len;
int r = strncmp(s1->ptr, s2, (n1 < n2) ? n1 : n2);
if (r == 0) return (int) (n1 - n2);
return r;
}
int mg_vcasecmp(const struct mg_str *str1, const char *str2) {
size_t n2 = strlen(str2), n1 = str1->len;
int r = mg_ncasecmp(str1->ptr, str2, (n1 < n2) ? n1 : n2);
if (r == 0) return (int) (n1 - n2);
return r;
}
struct mg_str mg_strdup(const struct mg_str s) {
struct mg_str r = {NULL, 0};
if (s.len > 0 && s.ptr != NULL) {
char *sc = (char *) calloc(1, s.len + 1);
if (sc != NULL) {
memcpy(sc, s.ptr, s.len);
sc[s.len] = '\0';
r.ptr = sc;
r.len = s.len;
}
}
return r;
}
int mg_strcmp(const struct mg_str str1, const struct mg_str str2) {
size_t i = 0;
while (i < str1.len && i < str2.len) {
int c1 = str1.ptr[i];
int c2 = str2.ptr[i];
if (c1 < c2) return -1;
if (c1 > c2) return 1;
i++;
}
if (i < str1.len) return 1;
if (i < str2.len) return -1;
return 0;
}
const char *mg_strstr(const struct mg_str haystack,
const struct mg_str needle) {
size_t i;
if (needle.len > haystack.len) return NULL;
if (needle.len == 0) return haystack.ptr;
for (i = 0; i <= haystack.len - needle.len; i++) {
if (memcmp(haystack.ptr + i, needle.ptr, needle.len) == 0) {
return haystack.ptr + i;
}
}
return NULL;
}
static bool is_space(int c) {
return c == ' ' || c == '\r' || c == '\n' || c == '\t';
}
struct mg_str mg_strstrip(struct mg_str s) {
while (s.len > 0 && is_space((int) *s.ptr)) s.ptr++, s.len--;
while (s.len > 0 && is_space((int) *(s.ptr + s.len - 1))) s.len--;
return s;
}
bool mg_match(struct mg_str s, struct mg_str p, struct mg_str *caps) {
size_t i = 0, j = 0, ni = 0, nj = 0;
if (caps) caps->ptr = NULL, caps->len = 0;
while (i < p.len || j < s.len) {
if (i < p.len && j < s.len && (p.ptr[i] == '?' || s.ptr[j] == p.ptr[i])) {
if (caps == NULL) {
} else if (p.ptr[i] == '?') {
caps->ptr = &s.ptr[j], caps->len = 1; // Finalize `?` cap
caps++, caps->ptr = NULL, caps->len = 0; // Init next cap
} else if (caps->ptr != NULL && caps->len == 0) {
caps->len = (size_t) (&s.ptr[j] - caps->ptr); // Finalize current cap
caps++, caps->len = 0, caps->ptr = NULL; // Init next cap
}
i++, j++;
} else if (i < p.len && (p.ptr[i] == '*' || p.ptr[i] == '#')) {
if (caps && !caps->ptr) caps->len = 0, caps->ptr = &s.ptr[j]; // Init cap
ni = i++, nj = j + 1;
} else if (nj > 0 && nj <= s.len && (p.ptr[ni] == '#' || s.ptr[j] != '/')) {
i = ni, j = nj;
if (caps && caps->ptr == NULL && caps->len == 0) {
caps--, caps->len = 0; // Restart previous cap
}
} else {
return false;
}
}
if (caps && caps->ptr && caps->len == 0) {
caps->len = (size_t) (&s.ptr[j] - caps->ptr);
}
return true;
}
bool mg_globmatch(const char *s1, size_t n1, const char *s2, size_t n2) {
return mg_match(mg_str_n(s2, n2), mg_str_n(s1, n1), NULL);
}
static size_t mg_nce(const char *s, size_t n, size_t ofs, size_t *koff,
size_t *klen, size_t *voff, size_t *vlen, char delim) {
size_t kvlen, kl;
for (kvlen = 0; ofs + kvlen < n && s[ofs + kvlen] != delim;) kvlen++;
for (kl = 0; kl < kvlen && s[ofs + kl] != '=';) kl++;
if (koff != NULL) *koff = ofs;
if (klen != NULL) *klen = kl;
if (voff != NULL) *voff = kl < kvlen ? ofs + kl + 1 : 0;
if (vlen != NULL) *vlen = kl < kvlen ? kvlen - kl - 1 : 0;
ofs += kvlen + 1;
return ofs > n ? n : ofs;
}
bool mg_split(struct mg_str *s, struct mg_str *k, struct mg_str *v, char sep) {
size_t koff = 0, klen = 0, voff = 0, vlen = 0, off = 0;
if (s->ptr == NULL || s->len == 0) return 0;
off = mg_nce(s->ptr, s->len, 0, &koff, &klen, &voff, &vlen, sep);
if (k != NULL) *k = mg_str_n(s->ptr + koff, klen);
if (v != NULL) *v = mg_str_n(s->ptr + voff, vlen);
*s = mg_str_n(s->ptr + off, s->len - off);
return off > 0;
}
bool mg_commalist(struct mg_str *s, struct mg_str *k, struct mg_str *v) {
return mg_split(s, k, v, ',');
}
char *mg_hex(const void *buf, size_t len, char *to) {
const unsigned char *p = (const unsigned char *) buf;
const char *hex = "0123456789abcdef";
size_t i = 0;
for (; len--; p++) {
to[i++] = hex[p[0] >> 4];
to[i++] = hex[p[0] & 0x0f];
}
to[i] = '\0';
return to;
}
static unsigned char mg_unhex_nimble(unsigned char c) {
return (c >= '0' && c <= '9') ? (unsigned char) (c - '0')
: (c >= 'A' && c <= 'F') ? (unsigned char) (c - '7')
: (unsigned char) (c - 'W');
}
unsigned long mg_unhexn(const char *s, size_t len) {
unsigned long i = 0, v = 0;
for (i = 0; i < len; i++) v <<= 4, v |= mg_unhex_nimble(((uint8_t *) s)[i]);
return v;
}
void mg_unhex(const char *buf, size_t len, unsigned char *to) {
size_t i;
for (i = 0; i < len; i += 2) {
to[i >> 1] = (unsigned char) mg_unhexn(&buf[i], 2);
}
}
bool mg_path_is_sane(const char *path) {
const char *s = path;
for (; s[0] != '\0'; s++) {
if (s == path || s[0] == '/' || s[0] == '\\') { // Subdir?
if (s[1] == '.' && s[2] == '.') return false; // Starts with ..
}
}
return true;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/timer.c"
#endif
#define MG_TIMER_CALLED 4
void mg_timer_init(struct mg_timer **head, struct mg_timer *t, uint64_t ms,
unsigned flags, void (*fn)(void *), void *arg) {
t->id = 0, t->period_ms = ms, t->expire = 0;
t->flags = flags, t->fn = fn, t->arg = arg, t->next = *head;
*head = t;
}
void mg_timer_free(struct mg_timer **head, struct mg_timer *t) {
while (*head && *head != t) head = &(*head)->next;
if (*head) *head = t->next;
}
// t: expiration time, prd: period, now: current time. Return true if expired
bool mg_timer_expired(uint64_t *t, uint64_t prd, uint64_t now) {
if (now + prd < *t) *t = 0; // Time wrapped? Reset timer
if (*t == 0) *t = now + prd; // Firt poll? Set expiration
if (*t > now) return false; // Not expired yet, return
*t = (now - *t) > prd ? now + prd : *t + prd; // Next expiration time
return true; // Expired, return true
}
void mg_timer_poll(struct mg_timer **head, uint64_t now_ms) {
struct mg_timer *t, *tmp;
for (t = *head; t != NULL; t = tmp) {
bool once = t->expire == 0 && (t->flags & MG_TIMER_RUN_NOW) &&
!(t->flags & MG_TIMER_CALLED); // Handle MG_TIMER_NOW only once
bool expired = mg_timer_expired(&t->expire, t->period_ms, now_ms);
tmp = t->next;
if (!once && !expired) continue;
if ((t->flags & MG_TIMER_REPEAT) || !(t->flags & MG_TIMER_CALLED)) {
t->fn(t->arg);
}
t->flags |= MG_TIMER_CALLED;
}
}
#ifdef MG_ENABLE_LINES
#line 1 "src/tls_aes128.c"
#endif
/******************************************************************************
*
* THIS SOURCE CODE IS HEREBY PLACED INTO THE PUBLIC DOMAIN FOR THE GOOD OF ALL
*
* This is a simple and straightforward implementation of the AES Rijndael
* 128-bit block cipher designed by Vincent Rijmen and Joan Daemen. The focus
* of this work was correctness & accuracy. It is written in 'C' without any
* particular focus upon optimization or speed. It should be endian (memory
* byte order) neutral since the few places that care are handled explicitly.
*
* This implementation of Rijndael was created by Steven M. Gibson of GRC.com.
*
* It is intended for general purpose use, but was written in support of GRC's
* reference implementation of the SQRL (Secure Quick Reliable Login) client.
*
* See: http://csrc.nist.gov/archive/aes/rijndael/wsdindex.html
*
* NO COPYRIGHT IS CLAIMED IN THIS WORK, HOWEVER, NEITHER IS ANY WARRANTY MADE
* REGARDING ITS FITNESS FOR ANY PARTICULAR PURPOSE. USE IT AT YOUR OWN RISK.
*
*******************************************************************************/
#if MG_TLS == MG_TLS_BUILTIN
static int aes_tables_inited = 0; // run-once flag for performing key
// expasion table generation (see below)
/*
* The following static local tables must be filled-in before the first use of
* the GCM or AES ciphers. They are used for the AES key expansion/scheduling
* and once built are read-only and thread safe. The "gcm_initialize" function
* must be called once during system initialization to populate these arrays
* for subsequent use by the AES key scheduler. If they have not been built
* before attempted use, an error will be returned to the caller.
*
* NOTE: GCM Encryption/Decryption does NOT REQUIRE AES decryption. Since
* GCM uses AES in counter-mode, where the AES cipher output is XORed with
* the GCM input, we ONLY NEED AES encryption. Thus, to save space AES
* decryption is typically disabled by setting AES_DECRYPTION to 0 in aes.h.
*/
// We always need our forward tables
static uchar FSb[256]; // Forward substitution box (FSb)
static uint32_t FT0[256]; // Forward key schedule assembly tables
static uint32_t FT1[256];
static uint32_t FT2[256];
static uint32_t FT3[256];
#if AES_DECRYPTION // We ONLY need reverse for decryption
static uchar RSb[256]; // Reverse substitution box (RSb)
static uint32_t RT0[256]; // Reverse key schedule assembly tables
static uint32_t RT1[256];
static uint32_t RT2[256];
static uint32_t RT3[256];
#endif /* AES_DECRYPTION */
static uint32_t RCON[10]; // AES round constants
/*
* Platform Endianness Neutralizing Load and Store Macro definitions
* AES wants platform-neutral Little Endian (LE) byte ordering
*/
#define GET_UINT32_LE(n, b, i) \
{ \
(n) = ((uint32_t) (b)[(i)]) | ((uint32_t) (b)[(i) + 1] << 8) | \
((uint32_t) (b)[(i) + 2] << 16) | ((uint32_t) (b)[(i) + 3] << 24); \
}
#define PUT_UINT32_LE(n, b, i) \
{ \
(b)[(i)] = (uchar) ((n)); \
(b)[(i) + 1] = (uchar) ((n) >> 8); \
(b)[(i) + 2] = (uchar) ((n) >> 16); \
(b)[(i) + 3] = (uchar) ((n) >> 24); \
}
/*
* AES forward and reverse encryption round processing macros
*/
#define AES_FROUND(X0, X1, X2, X3, Y0, Y1, Y2, Y3) \
{ \
X0 = *RK++ ^ FT0[(Y0) &0xFF] ^ FT1[(Y1 >> 8) & 0xFF] ^ \
FT2[(Y2 >> 16) & 0xFF] ^ FT3[(Y3 >> 24) & 0xFF]; \
\
X1 = *RK++ ^ FT0[(Y1) &0xFF] ^ FT1[(Y2 >> 8) & 0xFF] ^ \
FT2[(Y3 >> 16) & 0xFF] ^ FT3[(Y0 >> 24) & 0xFF]; \
\
X2 = *RK++ ^ FT0[(Y2) &0xFF] ^ FT1[(Y3 >> 8) & 0xFF] ^ \
FT2[(Y0 >> 16) & 0xFF] ^ FT3[(Y1 >> 24) & 0xFF]; \
\
X3 = *RK++ ^ FT0[(Y3) &0xFF] ^ FT1[(Y0 >> 8) & 0xFF] ^ \
FT2[(Y1 >> 16) & 0xFF] ^ FT3[(Y2 >> 24) & 0xFF]; \
}
#define AES_RROUND(X0, X1, X2, X3, Y0, Y1, Y2, Y3) \
{ \
X0 = *RK++ ^ RT0[(Y0) &0xFF] ^ RT1[(Y3 >> 8) & 0xFF] ^ \
RT2[(Y2 >> 16) & 0xFF] ^ RT3[(Y1 >> 24) & 0xFF]; \
\
X1 = *RK++ ^ RT0[(Y1) &0xFF] ^ RT1[(Y0 >> 8) & 0xFF] ^ \
RT2[(Y3 >> 16) & 0xFF] ^ RT3[(Y2 >> 24) & 0xFF]; \
\
X2 = *RK++ ^ RT0[(Y2) &0xFF] ^ RT1[(Y1 >> 8) & 0xFF] ^ \
RT2[(Y0 >> 16) & 0xFF] ^ RT3[(Y3 >> 24) & 0xFF]; \
\
X3 = *RK++ ^ RT0[(Y3) &0xFF] ^ RT1[(Y2 >> 8) & 0xFF] ^ \
RT2[(Y1 >> 16) & 0xFF] ^ RT3[(Y0 >> 24) & 0xFF]; \
}
/*
* These macros improve the readability of the key
* generation initialization code by collapsing
* repetitive common operations into logical pieces.
*/
#define ROTL8(x) ((x << 8) & 0xFFFFFFFF) | (x >> 24)
#define XTIME(x) ((x << 1) ^ ((x & 0x80) ? 0x1B : 0x00))
#define MUL(x, y) ((x && y) ? pow[(log[x] + log[y]) % 255] : 0)
#define MIX(x, y) \
{ \
y = ((y << 1) | (y >> 7)) & 0xFF; \
x ^= y; \
}
#define CPY128 \
{ \
*RK++ = *SK++; \
*RK++ = *SK++; \
*RK++ = *SK++; \
*RK++ = *SK++; \
}
/******************************************************************************
*
* AES_INIT_KEYGEN_TABLES
*
* Fills the AES key expansion tables allocated above with their static
* data. This is not "per key" data, but static system-wide read-only
* table data. THIS FUNCTION IS NOT THREAD SAFE. It must be called once
* at system initialization to setup the tables for all subsequent use.
*
******************************************************************************/
void aes_init_keygen_tables(void) {
int i, x, y, z; // general purpose iteration and computation locals
int pow[256];
int log[256];
if (aes_tables_inited) return;
// fill the 'pow' and 'log' tables over GF(2^8)
for (i = 0, x = 1; i < 256; i++) {
pow[i] = x;
log[x] = i;
x = (x ^ XTIME(x)) & 0xFF;
}
// compute the round constants
for (i = 0, x = 1; i < 10; i++) {
RCON[i] = (uint32_t) x;
x = XTIME(x) & 0xFF;
}
// fill the forward and reverse substitution boxes
FSb[0x00] = 0x63;
#if AES_DECRYPTION // whether AES decryption is supported
RSb[0x63] = 0x00;
#endif /* AES_DECRYPTION */
for (i = 1; i < 256; i++) {
x = y = pow[255 - log[i]];
MIX(x, y);
MIX(x, y);
MIX(x, y);
MIX(x, y);
FSb[i] = (uchar) (x ^= 0x63);
#if AES_DECRYPTION // whether AES decryption is supported
RSb[x] = (uchar) i;
#endif /* AES_DECRYPTION */
}
// generate the forward and reverse key expansion tables
for (i = 0; i < 256; i++) {
x = FSb[i];
y = XTIME(x) & 0xFF;
z = (y ^ x) & 0xFF;
FT0[i] = ((uint32_t) y) ^ ((uint32_t) x << 8) ^ ((uint32_t) x << 16) ^
((uint32_t) z << 24);
FT1[i] = ROTL8(FT0[i]);
FT2[i] = ROTL8(FT1[i]);
FT3[i] = ROTL8(FT2[i]);
#if AES_DECRYPTION // whether AES decryption is supported
x = RSb[i];
RT0[i] = ((uint32_t) MUL(0x0E, x)) ^ ((uint32_t) MUL(0x09, x) << 8) ^
((uint32_t) MUL(0x0D, x) << 16) ^ ((uint32_t) MUL(0x0B, x) << 24);
RT1[i] = ROTL8(RT0[i]);
RT2[i] = ROTL8(RT1[i]);
RT3[i] = ROTL8(RT2[i]);
#endif /* AES_DECRYPTION */
}
aes_tables_inited = 1; // flag that the tables have been generated
} // to permit subsequent use of the AES cipher
/******************************************************************************
*
* AES_SET_ENCRYPTION_KEY
*
* This is called by 'aes_setkey' when we're establishing a key for
* subsequent encryption. We give it a pointer to the encryption
* context, a pointer to the key, and the key's length in bytes.
* Valid lengths are: 16, 24 or 32 bytes (128, 192, 256 bits).
*
******************************************************************************/
static int aes_set_encryption_key(aes_context *ctx, const uchar *key, uint keysize) {
uint i; // general purpose iteration local
uint32_t *RK = ctx->rk; // initialize our RoundKey buffer pointer
for (i = 0; i < (keysize >> 2); i++) {
GET_UINT32_LE(RK[i], key, i << 2);
}
switch (ctx->rounds) {
case 10:
for (i = 0; i < 10; i++, RK += 4) {
RK[4] = RK[0] ^ RCON[i] ^ ((uint32_t) FSb[(RK[3] >> 8) & 0xFF]) ^
((uint32_t) FSb[(RK[3] >> 16) & 0xFF] << 8) ^
((uint32_t) FSb[(RK[3] >> 24) & 0xFF] << 16) ^
((uint32_t) FSb[(RK[3]) & 0xFF] << 24);
RK[5] = RK[1] ^ RK[4];
RK[6] = RK[2] ^ RK[5];
RK[7] = RK[3] ^ RK[6];
}
break;
case 12:
for (i = 0; i < 8; i++, RK += 6) {
RK[6] = RK[0] ^ RCON[i] ^ ((uint32_t) FSb[(RK[5] >> 8) & 0xFF]) ^
((uint32_t) FSb[(RK[5] >> 16) & 0xFF] << 8) ^
((uint32_t) FSb[(RK[5] >> 24) & 0xFF] << 16) ^
((uint32_t) FSb[(RK[5]) & 0xFF] << 24);
RK[7] = RK[1] ^ RK[6];
RK[8] = RK[2] ^ RK[7];
RK[9] = RK[3] ^ RK[8];
RK[10] = RK[4] ^ RK[9];
RK[11] = RK[5] ^ RK[10];
}
break;
case 14:
for (i = 0; i < 7; i++, RK += 8) {
RK[8] = RK[0] ^ RCON[i] ^ ((uint32_t) FSb[(RK[7] >> 8) & 0xFF]) ^
((uint32_t) FSb[(RK[7] >> 16) & 0xFF] << 8) ^
((uint32_t) FSb[(RK[7] >> 24) & 0xFF] << 16) ^
((uint32_t) FSb[(RK[7]) & 0xFF] << 24);
RK[9] = RK[1] ^ RK[8];
RK[10] = RK[2] ^ RK[9];
RK[11] = RK[3] ^ RK[10];
RK[12] = RK[4] ^ ((uint32_t) FSb[(RK[11]) & 0xFF]) ^
((uint32_t) FSb[(RK[11] >> 8) & 0xFF] << 8) ^
((uint32_t) FSb[(RK[11] >> 16) & 0xFF] << 16) ^
((uint32_t) FSb[(RK[11] >> 24) & 0xFF] << 24);
RK[13] = RK[5] ^ RK[12];
RK[14] = RK[6] ^ RK[13];
RK[15] = RK[7] ^ RK[14];
}
break;
default:
return -1;
}
return (0);
}
#if AES_DECRYPTION // whether AES decryption is supported
/******************************************************************************
*
* AES_SET_DECRYPTION_KEY
*
* This is called by 'aes_setkey' when we're establishing a
* key for subsequent decryption. We give it a pointer to
* the encryption context, a pointer to the key, and the key's
* length in bits. Valid lengths are: 128, 192, or 256 bits.
*
******************************************************************************/
static int aes_set_decryption_key(aes_context *ctx, const uchar *key, uint keysize) {
int i, j;
aes_context cty; // a calling aes context for set_encryption_key
uint32_t *RK = ctx->rk; // initialize our RoundKey buffer pointer
uint32_t *SK;
int ret;
cty.rounds = ctx->rounds; // initialize our local aes context
cty.rk = cty.buf; // round count and key buf pointer
if ((ret = aes_set_encryption_key(&cty, key, keysize)) != 0) return (ret);
SK = cty.rk + cty.rounds * 4;
CPY128 // copy a 128-bit block from *SK to *RK
for (i = ctx->rounds - 1, SK -= 8; i > 0; i--, SK -= 8) {
for (j = 0; j < 4; j++, SK++) {
*RK++ = RT0[FSb[(*SK) & 0xFF]] ^ RT1[FSb[(*SK >> 8) & 0xFF]] ^
RT2[FSb[(*SK >> 16) & 0xFF]] ^ RT3[FSb[(*SK >> 24) & 0xFF]];
}
}
CPY128 // copy a 128-bit block from *SK to *RK
memset(&cty, 0, sizeof(aes_context)); // clear local aes context
return (0);
}
#endif /* AES_DECRYPTION */
/******************************************************************************
*
* AES_SETKEY
*
* Invoked to establish the key schedule for subsequent encryption/decryption
*
******************************************************************************/
int aes_setkey(aes_context *ctx, // AES context provided by our caller
int mode, // ENCRYPT or DECRYPT flag
const uchar *key, // pointer to the key
uint keysize) // key length in bytes
{
// since table initialization is not thread safe, we could either add
// system-specific mutexes and init the AES key generation tables on
// demand, or ask the developer to simply call "gcm_initialize" once during
// application startup before threading begins. That's what we choose.
if (!aes_tables_inited) return (-1); // fail the call when not inited.
ctx->mode = mode; // capture the key type we're creating
ctx->rk = ctx->buf; // initialize our round key pointer
switch (keysize) // set the rounds count based upon the keysize
{
case 16:
ctx->rounds = 10;
break; // 16-byte, 128-bit key
case 24:
ctx->rounds = 12;
break; // 24-byte, 192-bit key
case 32:
ctx->rounds = 14;
break; // 32-byte, 256-bit key
default:
return (-1);
}
#if AES_DECRYPTION
if (mode == DECRYPT) // expand our key for encryption or decryption
return (aes_set_decryption_key(ctx, key, keysize));
else /* ENCRYPT */
#endif /* AES_DECRYPTION */
return (aes_set_encryption_key(ctx, key, keysize));
}
/******************************************************************************
*
* AES_CIPHER
*
* Perform AES encryption and decryption.
* The AES context will have been setup with the encryption mode
* and all keying information appropriate for the task.
*
******************************************************************************/
int aes_cipher(aes_context *ctx, const uchar input[16], uchar output[16]) {
int i;
uint32_t *RK, X0, X1, X2, X3, Y0, Y1, Y2, Y3; // general purpose locals
RK = ctx->rk;
GET_UINT32_LE(X0, input, 0);
X0 ^= *RK++; // load our 128-bit
GET_UINT32_LE(X1, input, 4);
X1 ^= *RK++; // input buffer in a storage
GET_UINT32_LE(X2, input, 8);
X2 ^= *RK++; // memory endian-neutral way
GET_UINT32_LE(X3, input, 12);
X3 ^= *RK++;
#if AES_DECRYPTION // whether AES decryption is supported
if (ctx->mode == DECRYPT) {
for (i = (ctx->rounds >> 1) - 1; i > 0; i--) {
AES_RROUND(Y0, Y1, Y2, Y3, X0, X1, X2, X3);
AES_RROUND(X0, X1, X2, X3, Y0, Y1, Y2, Y3);
}
AES_RROUND(Y0, Y1, Y2, Y3, X0, X1, X2, X3);
X0 = *RK++ ^ ((uint32_t) RSb[(Y0) &0xFF]) ^
((uint32_t) RSb[(Y3 >> 8) & 0xFF] << 8) ^
((uint32_t) RSb[(Y2 >> 16) & 0xFF] << 16) ^
((uint32_t) RSb[(Y1 >> 24) & 0xFF] << 24);
X1 = *RK++ ^ ((uint32_t) RSb[(Y1) &0xFF]) ^
((uint32_t) RSb[(Y0 >> 8) & 0xFF] << 8) ^
((uint32_t) RSb[(Y3 >> 16) & 0xFF] << 16) ^
((uint32_t) RSb[(Y2 >> 24) & 0xFF] << 24);
X2 = *RK++ ^ ((uint32_t) RSb[(Y2) &0xFF]) ^
((uint32_t) RSb[(Y1 >> 8) & 0xFF] << 8) ^
((uint32_t) RSb[(Y0 >> 16) & 0xFF] << 16) ^
((uint32_t) RSb[(Y3 >> 24) & 0xFF] << 24);
X3 = *RK++ ^ ((uint32_t) RSb[(Y3) &0xFF]) ^
((uint32_t) RSb[(Y2 >> 8) & 0xFF] << 8) ^
((uint32_t) RSb[(Y1 >> 16) & 0xFF] << 16) ^
((uint32_t) RSb[(Y0 >> 24) & 0xFF] << 24);
} else /* ENCRYPT */
{
#endif /* AES_DECRYPTION */
for (i = (ctx->rounds >> 1) - 1; i > 0; i--) {
AES_FROUND(Y0, Y1, Y2, Y3, X0, X1, X2, X3);
AES_FROUND(X0, X1, X2, X3, Y0, Y1, Y2, Y3);
}
AES_FROUND(Y0, Y1, Y2, Y3, X0, X1, X2, X3);
X0 = *RK++ ^ ((uint32_t) FSb[(Y0) &0xFF]) ^
((uint32_t) FSb[(Y1 >> 8) & 0xFF] << 8) ^
((uint32_t) FSb[(Y2 >> 16) & 0xFF] << 16) ^
((uint32_t) FSb[(Y3 >> 24) & 0xFF] << 24);
X1 = *RK++ ^ ((uint32_t) FSb[(Y1) &0xFF]) ^
((uint32_t) FSb[(Y2 >> 8) & 0xFF] << 8) ^
((uint32_t) FSb[(Y3 >> 16) & 0xFF] << 16) ^
((uint32_t) FSb[(Y0 >> 24) & 0xFF] << 24);
X2 = *RK++ ^ ((uint32_t) FSb[(Y2) &0xFF]) ^
((uint32_t) FSb[(Y3 >> 8) & 0xFF] << 8) ^
((uint32_t) FSb[(Y0 >> 16) & 0xFF] << 16) ^
((uint32_t) FSb[(Y1 >> 24) & 0xFF] << 24);
X3 = *RK++ ^ ((uint32_t) FSb[(Y3) &0xFF]) ^
((uint32_t) FSb[(Y0 >> 8) & 0xFF] << 8) ^
((uint32_t) FSb[(Y1 >> 16) & 0xFF] << 16) ^
((uint32_t) FSb[(Y2 >> 24) & 0xFF] << 24);
#if AES_DECRYPTION // whether AES decryption is supported
}
#endif /* AES_DECRYPTION */
PUT_UINT32_LE(X0, output, 0);
PUT_UINT32_LE(X1, output, 4);
PUT_UINT32_LE(X2, output, 8);
PUT_UINT32_LE(X3, output, 12);
return (0);
}
/* end of aes.c */
/******************************************************************************
*
* THIS SOURCE CODE IS HEREBY PLACED INTO THE PUBLIC DOMAIN FOR THE GOOD OF ALL
*
* This is a simple and straightforward implementation of AES-GCM authenticated
* encryption. The focus of this work was correctness & accuracy. It is written
* in straight 'C' without any particular focus upon optimization or speed. It
* should be endian (memory byte order) neutral since the few places that care
* are handled explicitly.
*
* This implementation of AES-GCM was created by Steven M. Gibson of GRC.com.
*
* It is intended for general purpose use, but was written in support of GRC's
* reference implementation of the SQRL (Secure Quick Reliable Login) client.
*
* See: http://csrc.nist.gov/publications/nistpubs/800-38D/SP-800-38D.pdf
* http://csrc.nist.gov/groups/ST/toolkit/BCM/documents/proposedmodes/
* gcm/gcm-revised-spec.pdf
*
* NO COPYRIGHT IS CLAIMED IN THIS WORK, HOWEVER, NEITHER IS ANY WARRANTY MADE
* REGARDING ITS FITNESS FOR ANY PARTICULAR PURPOSE. USE IT AT YOUR OWN RISK.
*
*******************************************************************************/
/******************************************************************************
* ==== IMPLEMENTATION WARNING ====
*
* This code was developed for use within SQRL's fixed environmnent. Thus, it
* is somewhat less "general purpose" than it would be if it were designed as
* a general purpose AES-GCM library. Specifically, it bothers with almost NO
* error checking on parameter limits, buffer bounds, etc. It assumes that it
* is being invoked by its author or by someone who understands the values it
* expects to receive. Its behavior will be undefined otherwise.
*
* All functions that might fail are defined to return 'ints' to indicate a
* problem. Most do not do so now. But this allows for error propagation out
* of internal functions if robust error checking should ever be desired.
*
******************************************************************************/
/* Calculating the "GHASH"
*
* There are many ways of calculating the so-called GHASH in software, each with
* a traditional size vs performance tradeoff. The GHASH (Galois field hash) is
* an intriguing construction which takes two 128-bit strings (also the cipher's
* block size and the fundamental operation size for the system) and hashes them
* into a third 128-bit result.
*
* Many implementation solutions have been worked out that use large precomputed
* table lookups in place of more time consuming bit fiddling, and this approach
* can be scaled easily upward or downward as needed to change the time/space
* tradeoff. It's been studied extensively and there's a solid body of theory
* and practice. For example, without using any lookup tables an implementation
* might obtain 119 cycles per byte throughput, whereas using a simple, though
* large, key-specific 64 kbyte 8-bit lookup table the performance jumps to 13
* cycles per byte.
*
* And Intel's processors have, since 2010, included an instruction which does
* the entire 128x128->128 bit job in just several 64x64->128 bit pieces.
*
* Since SQRL is interactive, and only processing a few 128-bit blocks, I've
* settled upon a relatively slower but appealing small-table compromise which
* folds a bunch of not only time consuming but also bit twiddling into a simple
* 16-entry table which is attributed to Victor Shoup's 1996 work while at
* Bellcore: "On Fast and Provably Secure MessageAuthentication Based on
* Universal Hashing." See: http://www.shoup.net/papers/macs.pdf
* See, also section 4.1 of the "gcm-revised-spec" cited above.
*/
/*
* This 16-entry table of pre-computed constants is used by the
* GHASH multiplier to improve over a strictly table-free but
* significantly slower 128x128 bit multiple within GF(2^128).
*/
static const uint64_t last4[16] = {
0x0000, 0x1c20, 0x3840, 0x2460, 0x7080, 0x6ca0, 0x48c0, 0x54e0,
0xe100, 0xfd20, 0xd940, 0xc560, 0x9180, 0x8da0, 0xa9c0, 0xb5e0};
/*
* Platform Endianness Neutralizing Load and Store Macro definitions
* GCM wants platform-neutral Big Endian (BE) byte ordering
*/
#define GET_UINT32_BE(n, b, i) \
{ \
(n) = ((uint32_t) (b)[(i)] << 24) | ((uint32_t) (b)[(i) + 1] << 16) | \
((uint32_t) (b)[(i) + 2] << 8) | ((uint32_t) (b)[(i) + 3]); \
}
#define PUT_UINT32_BE(n, b, i) \
{ \
(b)[(i)] = (uchar) ((n) >> 24); \
(b)[(i) + 1] = (uchar) ((n) >> 16); \
(b)[(i) + 2] = (uchar) ((n) >> 8); \
(b)[(i) + 3] = (uchar) ((n)); \
}
/******************************************************************************
*
* GCM_INITIALIZE
*
* Must be called once to initialize the GCM library.
*
* At present, this only calls the AES keygen table generator, which expands
* the AES keying tables for use. This is NOT A THREAD-SAFE function, so it
* MUST be called during system initialization before a multi-threading
* environment is running.
*
******************************************************************************/
int gcm_initialize(void) {
aes_init_keygen_tables();
return (0);
}
/******************************************************************************
*
* GCM_MULT
*
* Performs a GHASH operation on the 128-bit input vector 'x', setting
* the 128-bit output vector to 'x' times H using our precomputed tables.
* 'x' and 'output' are seen as elements of GCM's GF(2^128) Galois field.
*
******************************************************************************/
static void gcm_mult(gcm_context *ctx, // pointer to established context
const uchar x[16], // pointer to 128-bit input vector
uchar output[16]) // pointer to 128-bit output vector
{
int i;
uchar lo, hi, rem;
uint64_t zh, zl;
lo = (uchar) (x[15] & 0x0f);
hi = (uchar) (x[15] >> 4);
zh = ctx->HH[lo];
zl = ctx->HL[lo];
for (i = 15; i >= 0; i--) {
lo = (uchar) (x[i] & 0x0f);
hi = (uchar) (x[i] >> 4);
if (i != 15) {
rem = (uchar) (zl & 0x0f);
zl = (zh << 60) | (zl >> 4);
zh = (zh >> 4);
zh ^= (uint64_t) last4[rem] << 48;
zh ^= ctx->HH[lo];
zl ^= ctx->HL[lo];
}
rem = (uchar) (zl & 0x0f);
zl = (zh << 60) | (zl >> 4);
zh = (zh >> 4);
zh ^= (uint64_t) last4[rem] << 48;
zh ^= ctx->HH[hi];
zl ^= ctx->HL[hi];
}
PUT_UINT32_BE(zh >> 32, output, 0);
PUT_UINT32_BE(zh, output, 4);
PUT_UINT32_BE(zl >> 32, output, 8);
PUT_UINT32_BE(zl, output, 12);
}
/******************************************************************************
*
* GCM_SETKEY
*
* This is called to set the AES-GCM key. It initializes the AES key
* and populates the gcm context's pre-calculated HTables.
*
******************************************************************************/
int gcm_setkey(gcm_context *ctx, // pointer to caller-provided gcm context
const uchar *key, // pointer to the AES encryption key
const uint keysize) // size in bytes (must be 16, 24, 32 for
// 128, 192 or 256-bit keys respectively)
{
int ret, i, j;
uint64_t hi, lo;
uint64_t vl, vh;
unsigned char h[16];
memset(ctx, 0, sizeof(gcm_context)); // zero caller-provided GCM context
memset(h, 0, 16); // initialize the block to encrypt
// encrypt the null 128-bit block to generate a key-based value
// which is then used to initialize our GHASH lookup tables
if ((ret = aes_setkey(&ctx->aes_ctx, ENCRYPT, key, keysize)) != 0)
return (ret);
if ((ret = aes_cipher(&ctx->aes_ctx, h, h)) != 0) return (ret);
GET_UINT32_BE(hi, h, 0); // pack h as two 64-bit ints, big-endian
GET_UINT32_BE(lo, h, 4);
vh = (uint64_t) hi << 32 | lo;
GET_UINT32_BE(hi, h, 8);
GET_UINT32_BE(lo, h, 12);
vl = (uint64_t) hi << 32 | lo;
ctx->HL[8] = vl; // 8 = 1000 corresponds to 1 in GF(2^128)
ctx->HH[8] = vh;
ctx->HH[0] = 0; // 0 corresponds to 0 in GF(2^128)
ctx->HL[0] = 0;
for (i = 4; i > 0; i >>= 1) {
uint32_t T = (uint32_t) (vl & 1) * 0xe1000000U;
vl = (vh << 63) | (vl >> 1);
vh = (vh >> 1) ^ ((uint64_t) T << 32);
ctx->HL[i] = vl;
ctx->HH[i] = vh;
}
for (i = 2; i < 16; i <<= 1) {
uint64_t *HiL = ctx->HL + i, *HiH = ctx->HH + i;
vh = *HiH;
vl = *HiL;
for (j = 1; j < i; j++) {
HiH[j] = vh ^ ctx->HH[j];
HiL[j] = vl ^ ctx->HL[j];
}
}
return (0);
}
/******************************************************************************
*
* GCM processing occurs four phases: SETKEY, START, UPDATE and FINISH.
*
* SETKEY:
*
* START: Sets the Encryption/Decryption mode.
* Accepts the initialization vector and additional data.
*
* UPDATE: Encrypts or decrypts the plaintext or ciphertext.
*
* FINISH: Performs a final GHASH to generate the authentication tag.
*
******************************************************************************
*
* GCM_START
*
* Given a user-provided GCM context, this initializes it, sets the encryption
* mode, and preprocesses the initialization vector and additional AEAD data.
*
******************************************************************************/
int gcm_start(gcm_context *ctx, // pointer to user-provided GCM context
int mode, // GCM_ENCRYPT or GCM_DECRYPT
const uchar *iv, // pointer to initialization vector
size_t iv_len, // IV length in bytes (should == 12)
const uchar *add, // ptr to additional AEAD data (NULL if none)
size_t add_len) // length of additional AEAD data (bytes)
{
int ret; // our error return if the AES encrypt fails
uchar work_buf[16]; // XOR source built from provided IV if len != 16
const uchar *p; // general purpose array pointer
size_t use_len; // byte count to process, up to 16 bytes
size_t i; // local loop iterator
// since the context might be reused under the same key
// we zero the working buffers for this next new process
memset(ctx->y, 0x00, sizeof(ctx->y));
memset(ctx->buf, 0x00, sizeof(ctx->buf));
ctx->len = 0;
ctx->add_len = 0;
ctx->mode = mode; // set the GCM encryption/decryption mode
ctx->aes_ctx.mode = ENCRYPT; // GCM *always* runs AES in ENCRYPTION mode
if (iv_len == 12) { // GCM natively uses a 12-byte, 96-bit IV
memcpy(ctx->y, iv, iv_len); // copy the IV to the top of the 'y' buff
ctx->y[15] = 1; // start "counting" from 1 (not 0)
} else // if we don't have a 12-byte IV, we GHASH whatever we've been given
{
memset(work_buf, 0x00, 16); // clear the working buffer
PUT_UINT32_BE(iv_len * 8, work_buf, 12); // place the IV into buffer
p = iv;
while (iv_len > 0) {
use_len = (iv_len < 16) ? iv_len : 16;
for (i = 0; i < use_len; i++) ctx->y[i] ^= p[i];
gcm_mult(ctx, ctx->y, ctx->y);
iv_len -= use_len;
p += use_len;
}
for (i = 0; i < 16; i++) ctx->y[i] ^= work_buf[i];
gcm_mult(ctx, ctx->y, ctx->y);
}
if ((ret = aes_cipher(&ctx->aes_ctx, ctx->y, ctx->base_ectr)) != 0)
return (ret);
ctx->add_len = add_len;
p = add;
while (add_len > 0) {
use_len = (add_len < 16) ? add_len : 16;
for (i = 0; i < use_len; i++) ctx->buf[i] ^= p[i];
gcm_mult(ctx, ctx->buf, ctx->buf);
add_len -= use_len;
p += use_len;
}
return (0);
}
/******************************************************************************
*
* GCM_UPDATE
*
* This is called once or more to process bulk plaintext or ciphertext data.
* We give this some number of bytes of input and it returns the same number
* of output bytes. If called multiple times (which is fine) all but the final
* invocation MUST be called with length mod 16 == 0. (Only the final call can
* have a partial block length of < 128 bits.)
*
******************************************************************************/
int gcm_update(gcm_context *ctx, // pointer to user-provided GCM context
size_t length, // length, in bytes, of data to process
const uchar *input, // pointer to source data
uchar *output) // pointer to destination data
{
int ret; // our error return if the AES encrypt fails
uchar ectr[16]; // counter-mode cipher output for XORing
size_t use_len; // byte count to process, up to 16 bytes
size_t i; // local loop iterator
ctx->len += length; // bump the GCM context's running length count
while (length > 0) {
// clamp the length to process at 16 bytes
use_len = (length < 16) ? length : 16;
// increment the context's 128-bit IV||Counter 'y' vector
for (i = 16; i > 12; i--)
if (++ctx->y[i - 1] != 0) break;
// encrypt the context's 'y' vector under the established key
if ((ret = aes_cipher(&ctx->aes_ctx, ctx->y, ectr)) != 0) return (ret);
// encrypt or decrypt the input to the output
if (ctx->mode == ENCRYPT) {
for (i = 0; i < use_len; i++) {
// XOR the cipher's ouptut vector (ectr) with our input
output[i] = (uchar) (ectr[i] ^ input[i]);
// now we mix in our data into the authentication hash.
// if we're ENcrypting we XOR in the post-XOR (output)
// results, but if we're DEcrypting we XOR in the input
// data
ctx->buf[i] ^= output[i];
}
} else {
for (i = 0; i < use_len; i++) {
// but if we're DEcrypting we XOR in the input data first,
// i.e. before saving to ouput data, otherwise if the input
// and output buffer are the same (inplace decryption) we
// would not get the correct auth tag
ctx->buf[i] ^= input[i];
// XOR the cipher's ouptut vector (ectr) with our input
output[i] = (uchar) (ectr[i] ^ input[i]);
}
}
gcm_mult(ctx, ctx->buf, ctx->buf); // perform a GHASH operation
length -= use_len; // drop the remaining byte count to process
input += use_len; // bump our input pointer forward
output += use_len; // bump our output pointer forward
}
return (0);
}
/******************************************************************************
*
* GCM_FINISH
*
* This is called once after all calls to GCM_UPDATE to finalize the GCM.
* It performs the final GHASH to produce the resulting authentication TAG.
*
******************************************************************************/
int gcm_finish(gcm_context *ctx, // pointer to user-provided GCM context
uchar *tag, // pointer to buffer which receives the tag
size_t tag_len) // length, in bytes, of the tag-receiving buf
{
uchar work_buf[16];
uint64_t orig_len = ctx->len * 8;
uint64_t orig_add_len = ctx->add_len * 8;
size_t i;
if (tag_len != 0) memcpy(tag, ctx->base_ectr, tag_len);
if (orig_len || orig_add_len) {
memset(work_buf, 0x00, 16);
PUT_UINT32_BE((orig_add_len >> 32), work_buf, 0);
PUT_UINT32_BE((orig_add_len), work_buf, 4);
PUT_UINT32_BE((orig_len >> 32), work_buf, 8);
PUT_UINT32_BE((orig_len), work_buf, 12);
for (i = 0; i < 16; i++) ctx->buf[i] ^= work_buf[i];
gcm_mult(ctx, ctx->buf, ctx->buf);
for (i = 0; i < tag_len; i++) tag[i] ^= ctx->buf[i];
}
return (0);
}
/******************************************************************************
*
* GCM_CRYPT_AND_TAG
*
* This either encrypts or decrypts the user-provided data and, either
* way, generates an authentication tag of the requested length. It must be
* called with a GCM context whose key has already been set with GCM_SETKEY.
*
* The user would typically call this explicitly to ENCRYPT a buffer of data
* and optional associated data, and produce its an authentication tag.
*
* To reverse the process the user would typically call the companion
* GCM_AUTH_DECRYPT function to decrypt data and verify a user-provided
* authentication tag. The GCM_AUTH_DECRYPT function calls this function
* to perform its decryption and tag generation, which it then compares.
*
******************************************************************************/
int gcm_crypt_and_tag(
gcm_context *ctx, // gcm context with key already setup
int mode, // cipher direction: GCM_ENCRYPT or GCM_DECRYPT
const uchar *iv, // pointer to the 12-byte initialization vector
size_t iv_len, // byte length if the IV. should always be 12
const uchar *add, // pointer to the non-ciphered additional data
size_t add_len, // byte length of the additional AEAD data
const uchar *input, // pointer to the cipher data source
uchar *output, // pointer to the cipher data destination
size_t length, // byte length of the cipher data
uchar *tag, // pointer to the tag to be generated
size_t tag_len) // byte length of the tag to be generated
{ /*
assuming that the caller has already invoked gcm_setkey to
prepare the gcm context with the keying material, we simply
invoke each of the three GCM sub-functions in turn...
*/
gcm_start(ctx, mode, iv, iv_len, add, add_len);
gcm_update(ctx, length, input, output);
gcm_finish(ctx, tag, tag_len);
return (0);
}
/******************************************************************************
*
* GCM_AUTH_DECRYPT
*
* This DECRYPTS a user-provided data buffer with optional associated data.
* It then verifies a user-supplied authentication tag against the tag just
* re-created during decryption to verify that the data has not been altered.
*
* This function calls GCM_CRYPT_AND_TAG (above) to perform the decryption
* and authentication tag generation.
*
******************************************************************************/
int gcm_auth_decrypt(
gcm_context *ctx, // gcm context with key already setup
const uchar *iv, // pointer to the 12-byte initialization vector
size_t iv_len, // byte length if the IV. should always be 12
const uchar *add, // pointer to the non-ciphered additional data
size_t add_len, // byte length of the additional AEAD data
const uchar *input, // pointer to the cipher data source
uchar *output, // pointer to the cipher data destination
size_t length, // byte length of the cipher data
const uchar *tag, // pointer to the tag to be authenticated
size_t tag_len) // byte length of the tag <= 16
{
uchar check_tag[16]; // the tag generated and returned by decryption
int diff; // an ORed flag to detect authentication errors
size_t i; // our local iterator
/*
we use GCM_DECRYPT_AND_TAG (above) to perform our decryption
(which is an identical XORing to reverse the previous one)
and also to re-generate the matching authentication tag
*/
gcm_crypt_and_tag(ctx, DECRYPT, iv, iv_len, add, add_len, input, output,
length, check_tag, tag_len);
// now we verify the authentication tag in 'constant time'
for (diff = 0, i = 0; i < tag_len; i++) diff |= tag[i] ^ check_tag[i];
if (diff != 0) { // see whether any bits differed?
memset(output, 0, length); // if so... wipe the output data
return (GCM_AUTH_FAILURE); // return GCM_AUTH_FAILURE
}
return (0);
}
/******************************************************************************
*
* GCM_ZERO_CTX
*
* The GCM context contains both the GCM context and the AES context.
* This includes keying and key-related material which is security-
* sensitive, so it MUST be zeroed after use. This function does that.
*
******************************************************************************/
void gcm_zero_ctx(gcm_context *ctx) {
// zero the context originally provided to us
memset(ctx, 0, sizeof(gcm_context));
}
//
// aes-gcm.c
// Pods
//
// Created by Markus Kosmal on 20/11/14.
//
//
int aes_gcm_encrypt(unsigned char *output, //
const unsigned char *input, size_t input_length,
const unsigned char *key, const size_t key_len,
const unsigned char *iv, const size_t iv_len,
unsigned char *aead, size_t aead_len, unsigned char *tag,
const size_t tag_len) {
int ret = 0; // our return value
gcm_context ctx; // includes the AES context structure
gcm_setkey(&ctx, key, (const uint) key_len);
ret = gcm_crypt_and_tag(&ctx, ENCRYPT, iv, iv_len, aead, aead_len, input, output,
input_length, tag, tag_len);
gcm_zero_ctx(&ctx);
return (ret);
}
int aes_gcm_decrypt(unsigned char *output, const unsigned char *input,
size_t input_length, const unsigned char *key,
const size_t key_len, const unsigned char *iv,
const size_t iv_len) {
int ret = 0; // our return value
gcm_context ctx; // includes the AES context structure
size_t tag_len = 0;
unsigned char *tag_buf = NULL;
gcm_setkey(&ctx, key, (const uint) key_len);
ret = gcm_crypt_and_tag(&ctx, DECRYPT, iv, iv_len, NULL, 0, input, output,
input_length, tag_buf, tag_len);
gcm_zero_ctx(&ctx);
return (ret);
}
#endif
// End of aes128 PD
#ifdef MG_ENABLE_LINES
#line 1 "src/tls_builtin.c"
#endif
#if MG_TLS == MG_TLS_BUILTIN
// handshake is re-entrant, so we need to keep track of its state
enum mg_tls_hs_state {
MG_TLS_HS_CLIENT_HELLO, // first, wait for ClientHello
MG_TLS_HS_SERVER_HELLO, // then, send all server handshake data at once
MG_TLS_HS_CLIENT_CHANGE_CIPHER, // finally wait for ClientChangeCipher
MG_TLS_HS_CLIENT_FINISH, // and ClientFinish (encrypted)
MG_TLS_HS_DONE, // finish handshake, start application data flow
};
// per-connection TLS data
struct tls_data {
enum mg_tls_hs_state state; // keep track of connection handshake progress
struct mg_iobuf send; // For the receive path, we're reusing c->rtls
mg_sha256_ctx sha256; // incremental SHA-256 hash for TLS handshake
uint32_t sseq; // server sequence number, used in encryption
uint32_t cseq; // client sequence number, used in decryption
uint8_t session_id[32]; // client session ID between the handshake states
uint8_t x25519_cli[32]; // client X25519 key between the handshake states
uint8_t x25519_sec[32]; // x25519 secret between the handshake states
struct mg_str server_cert_der; // server certificate in DER format
uint8_t server_key[32]; // server EC private key
// keys for AES encryption
uint8_t handshake_secret[32];
uint8_t server_write_key[16];
uint8_t server_write_iv[12];
uint8_t server_finished_key[32];
uint8_t client_write_key[16];
uint8_t client_write_iv[12];
uint8_t client_finished_key[32];
};
#define MG_LOAD_BE16(p) ((uint16_t) ((MG_U8P(p)[0] << 8U) | MG_U8P(p)[1]))
#define TLS_HDR_SIZE 5 // 1 byte type, 2 bytes version, 2 bytes len
// for derived tls keys we need SHA256([0]*32)
static uint8_t zeros[32] = {0};
static uint8_t zeros_sha256_digest[32] =
"\xe3\xb0\xc4\x42\x98\xfc\x1c\x14\x9a\xfb\xf4\xc8\x99\x6f\xb9\x24"
"\x27\xae\x41\xe4\x64\x9b\x93\x4c\xa4\x95\x99\x1b\x78\x52\xb8\x55";
#define X25519_BYTES 32
const uint8_t X25519_BASE_POINT[X25519_BYTES] = {9};
#define X25519_WBITS 32
typedef uint32_t limb_t;
typedef uint64_t dlimb_t;
typedef int64_t sdlimb_t;
#define LIMB(x) (uint32_t)(x##ull), (uint32_t) ((x##ull) >> 32)
#define NLIMBS (256 / X25519_WBITS)
typedef limb_t fe[NLIMBS];
static limb_t umaal(limb_t *carry, limb_t acc, limb_t mand, limb_t mier) {
dlimb_t tmp = (dlimb_t) mand * mier + acc + *carry;
*carry = (limb_t) (tmp >> X25519_WBITS);
return (limb_t) tmp;
}
// These functions are implemented in terms of umaal on ARM
static limb_t adc(limb_t *carry, limb_t acc, limb_t mand) {
dlimb_t total = (dlimb_t) *carry + acc + mand;
*carry = (limb_t) (total >> X25519_WBITS);
return (limb_t) total;
}
static limb_t adc0(limb_t *carry, limb_t acc) {
dlimb_t total = (dlimb_t) *carry + acc;
*carry = (limb_t) (total >> X25519_WBITS);
return (limb_t) total;
}
// - Precondition: carry is small.
// - Invariant: result of propagate is < 2^255 + 1 word
// - In particular, always less than 2p.
// - Also, output x >= min(x,19)
static void propagate(fe x, limb_t over) {
unsigned i;
limb_t carry;
over = x[NLIMBS - 1] >> (X25519_WBITS - 1) | over << 1;
x[NLIMBS - 1] &= ~((limb_t) 1 << (X25519_WBITS - 1));
carry = over * 19;
for (i = 0; i < NLIMBS; i++) {
x[i] = adc0(&carry, x[i]);
}
}
static void add(fe out, const fe a, const fe b) {
unsigned i;
limb_t carry = 0;
for (i = 0; i < NLIMBS; i++) {
out[i] = adc(&carry, a[i], b[i]);
}
propagate(out, carry);
}
static void sub(fe out, const fe a, const fe b) {
unsigned i;
sdlimb_t carry = -38;
for (i = 0; i < NLIMBS; i++) {
carry = carry + a[i] - b[i];
out[i] = (limb_t) carry;
carry >>= X25519_WBITS;
}
propagate(out, (limb_t) (1 + carry));
}
// `b` can contain less than 8 limbs, thus we use `limb_t *` instead of `fe`
// to avoid build warnings
static void mul(fe out, const fe a, const limb_t *b, unsigned nb) {
limb_t accum[2 * NLIMBS] = {0};
unsigned i, j;
limb_t carry2;
for (i = 0; i < nb; i++) {
limb_t mand = b[i];
carry2 = 0;
for (j = 0; j < NLIMBS; j++) {
accum[i + j] = umaal(&carry2, accum[i + j], mand, a[j]);
}
accum[i + j] = carry2;
}
carry2 = 0;
for (j = 0; j < NLIMBS; j++) {
out[j] = umaal(&carry2, accum[j], 38, accum[j + NLIMBS]);
}
propagate(out, carry2);
}
static void sqr(fe out, const fe a) {
mul(out, a, a, NLIMBS);
}
static void mul1(fe out, const fe a) {
mul(out, a, out, NLIMBS);
}
static void sqr1(fe a) {
mul1(a, a);
}
static void condswap(limb_t a[2 * NLIMBS], limb_t b[2 * NLIMBS],
limb_t doswap) {
unsigned i;
for (i = 0; i < 2 * NLIMBS; i++) {
limb_t xor = (a[i] ^ b[i]) & doswap;
a[i] ^= xor;
b[i] ^= xor;
}
}
// Canonicalize a field element x, reducing it to the least residue which is
// congruent to it mod 2^255-19
// - Precondition: x < 2^255 + 1 word
static limb_t canon(fe x) {
// First, add 19.
unsigned i;
limb_t carry0 = 19;
limb_t res;
sdlimb_t carry;
for (i = 0; i < NLIMBS; i++) {
x[i] = adc0(&carry0, x[i]);
}
propagate(x, carry0);
// Here, 19 <= x2 < 2^255
// - This is because we added 19, so before propagate it can't be less
// than 19. After propagate, it still can't be less than 19, because if
// propagate does anything it adds 19.
// - We know that the high bit must be clear, because either the input was ~
// 2^255 + one word + 19 (in which case it propagates to at most 2 words) or
// it was < 2^255. So now, if we subtract 19, we will get back to something in
// [0,2^255-19).
carry = -19;
res = 0;
for (i = 0; i < NLIMBS; i++) {
carry += x[i];
res |= x[i] = (limb_t) carry;
carry >>= X25519_WBITS;
}
return (limb_t) (((dlimb_t) res - 1) >> X25519_WBITS);
}
static const limb_t a24[1] = {121665};
static void ladder_part1(fe xs[5]) {
limb_t *x2 = xs[0], *z2 = xs[1], *x3 = xs[2], *z3 = xs[3], *t1 = xs[4];
add(t1, x2, z2); // t1 = A
sub(z2, x2, z2); // z2 = B
add(x2, x3, z3); // x2 = C
sub(z3, x3, z3); // z3 = D
mul1(z3, t1); // z3 = DA
mul1(x2, z2); // x3 = BC
add(x3, z3, x2); // x3 = DA+CB
sub(z3, z3, x2); // z3 = DA-CB
sqr1(t1); // t1 = AA
sqr1(z2); // z2 = BB
sub(x2, t1, z2); // x2 = E = AA-BB
mul(z2, x2, a24, sizeof(a24) / sizeof(a24[0])); // z2 = E*a24
add(z2, z2, t1); // z2 = E*a24 + AA
}
static void ladder_part2(fe xs[5], const fe x1) {
limb_t *x2 = xs[0], *z2 = xs[1], *x3 = xs[2], *z3 = xs[3], *t1 = xs[4];
sqr1(z3); // z3 = (DA-CB)^2
mul1(z3, x1); // z3 = x1 * (DA-CB)^2
sqr1(x3); // x3 = (DA+CB)^2
mul1(z2, x2); // z2 = AA*(E*a24+AA)
sub(x2, t1, x2); // x2 = BB again
mul1(x2, t1); // x2 = AA*BB
}
static void x25519_core(fe xs[5], const uint8_t scalar[X25519_BYTES],
const uint8_t *x1, int clamp) {
int i;
limb_t swap = 0;
limb_t *x2 = xs[0], *x3 = xs[2], *z3 = xs[3];
memset(xs, 0, 4 * sizeof(fe));
x2[0] = z3[0] = 1;
memcpy(x3, x1, sizeof(fe));
for (i = 255; i >= 0; i--) {
uint8_t bytei = scalar[i / 8];
limb_t doswap;
if (clamp) {
if (i / 8 == 0) {
bytei &= (uint8_t) ~7U;
} else if (i / 8 == X25519_BYTES - 1) {
bytei &= 0x7F;
bytei |= 0x40;
}
}
doswap = 0 - (limb_t) ((bytei >> (i % 8)) & 1);
condswap(x2, x3, swap ^ doswap);
swap = doswap;
ladder_part1(xs);
ladder_part2(xs, (const limb_t *) x1);
}
condswap(x2, x3, swap);
}
static int x25519(uint8_t out[X25519_BYTES], const uint8_t scalar[X25519_BYTES],
const uint8_t x1[X25519_BYTES], int clamp) {
int i, ret;
fe xs[5];
limb_t *x2, *z2, *z3, *prev;
static const struct {
uint8_t a, c, n;
} steps[13] = {{2, 1, 1}, {2, 1, 1}, {4, 2, 3}, {2, 4, 6}, {3, 1, 1},
{3, 2, 12}, {4, 3, 25}, {2, 3, 25}, {2, 4, 50}, {3, 2, 125},
{3, 1, 2}, {3, 1, 2}, {3, 1, 1}};
x25519_core(xs, scalar, x1, clamp);
// Precomputed inversion chain
x2 = xs[0];
z2 = xs[1];
z3 = xs[3];
prev = z2;
for (i = 0; i < 13; i++) {
int j;
limb_t *a = xs[steps[i].a];
for (j = steps[i].n; j > 0; j--) {
sqr(a, prev);
prev = a;
}
mul1(a, xs[steps[i].c]);
}
// Here prev = z3
// x2 /= z2
mul((limb_t *) out, x2, z3, NLIMBS);
ret = (int) canon((limb_t *) out);
if (!clamp) ret = 0;
return ret;
}
// helper to hexdump buffers inline
static void mg_tls_hexdump(const char *msg, uint8_t *buf, size_t bufsz) {
char p[512];
MG_VERBOSE(("%s: %s", msg, mg_hex(buf, bufsz, p)));
}
// TLS1.3 secret derivation based on the key label
static void mg_tls_derive_secret(const char *label, uint8_t *key, size_t keysz,
uint8_t *data, size_t datasz, uint8_t *hash,
size_t hashsz) {
size_t labelsz = strlen(label);
uint8_t secret[32];
uint8_t packed[256] = {0, (uint8_t) hashsz, (uint8_t) labelsz};
// TODO: assert lengths of label, key, data and hash
memmove(packed + 3, label, labelsz);
packed[3 + labelsz] = (uint8_t) datasz;
memmove(packed + labelsz + 4, data, datasz);
packed[4 + labelsz + datasz] = 1;
mg_hmac_sha256(secret, key, keysz, packed, 5 + labelsz + datasz);
memmove(hash, secret, hashsz);
}
// Did we receive a full TLS message in the c->rtls buffer?
static bool mg_tls_got_msg(struct mg_connection *c) {
return c->rtls.len >= (size_t) TLS_HDR_SIZE &&
c->rtls.len >= (size_t) (TLS_HDR_SIZE + MG_LOAD_BE16(c->rtls.buf + 3));
}
// Remove a single TLS record from the recv buffer
static void mg_tls_drop_packet(struct mg_iobuf *rio) {
uint16_t n = MG_LOAD_BE16(rio->buf + 3) + TLS_HDR_SIZE;
mg_iobuf_del(rio, 0, n);
}
// read and parse ClientHello record
static int mg_tls_client_hello(struct mg_connection *c) {
struct tls_data *tls = c->tls;
struct mg_iobuf *rio = &c->rtls;
uint8_t session_id_len;
uint16_t j;
uint16_t cipher_suites_len;
uint16_t ext_len;
uint8_t *ext;
if (!mg_tls_got_msg(c)) {
return MG_IO_WAIT;
}
if (rio->buf[0] != 0x16 || rio->buf[5] != 0x01) {
mg_error(c, "not a hello packet");
return -1;
}
mg_sha256_update(&tls->sha256, rio->buf + 5, rio->len - 5);
session_id_len = rio->buf[43];
if (session_id_len == sizeof(tls->session_id)) {
memmove(tls->session_id, rio->buf + 44, session_id_len);
} else if (session_id_len != 0) {
MG_INFO(("bad session id len"));
}
cipher_suites_len = MG_LOAD_BE16(rio->buf + 44 + session_id_len);
ext_len = MG_LOAD_BE16(rio->buf + 48 + session_id_len + cipher_suites_len);
ext = rio->buf + 50 + session_id_len + cipher_suites_len;
for (j = 0; j < ext_len;) {
uint16_t k;
uint16_t key_exchange_len;
uint8_t *key_exchange;
uint16_t n = MG_LOAD_BE16(ext + j + 2);
if (ext[j] != 0x00 ||
ext[j + 1] != 0x33) { // not a key share extension, ignore
j += (uint16_t) (n + 4);
continue;
}
key_exchange_len = MG_LOAD_BE16(ext + j + 5);
key_exchange = ext + j + 6;
for (k = 0; k < key_exchange_len;) {
uint16_t m = MG_LOAD_BE16(key_exchange + k + 2);
if (m == 32 && key_exchange[k] == 0x00 && key_exchange[k + 1] == 0x1d) {
memmove(tls->x25519_cli, key_exchange + k + 4, m);
mg_tls_drop_packet(rio);
return 0;
}
k += (uint16_t) (m + 4);
}
j += (uint16_t) (n + 4);
}
mg_error(c, "bad client hello");
return -1;
}
// put ServerHello record into wio buffer
static void mg_tls_server_hello(struct mg_connection *c) {
struct tls_data *tls = c->tls;
struct mg_iobuf *wio = &tls->send;
uint8_t msg_server_hello[122] =
// server hello, tls 1.2
"\x02\x00\x00\x76\x03\x03"
// random (32 bytes)
"\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe"
"\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe\xfe"
// session ID length + session ID (32 bytes)
"\x20"
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"
"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"
#if defined(CHACHA20) && CHACHA20
// TLS_CHACHA20_POLY1305_SHA256 + no compression
"\x13\x03\x00"
#else
// TLS_AES_128_GCM_SHA256 + no compression
"\x13\x01\x00"
#endif
// extensions + keyshare
"\x00\x2e\x00\x33\x00\x24\x00\x1d\x00\x20"
// x25519 keyshare
"\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab"
"\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab\xab"
// supported versions (tls1.3 == 0x304)
"\x00\x2b\x00\x02\x03\x04";
// calculate keyshare
uint8_t x25519_pub[X25519_BYTES];
uint8_t x25519_prv[X25519_BYTES];
mg_random(x25519_prv, sizeof(x25519_prv));
x25519(x25519_pub, x25519_prv, X25519_BASE_POINT, 1);
x25519(tls->x25519_sec, x25519_prv, tls->x25519_cli, 1);
mg_tls_hexdump("x25519 sec", tls->x25519_sec, sizeof(tls->x25519_sec));
// fill in the gaps: session ID + keyshare
memmove(msg_server_hello + 39, tls->session_id, sizeof(tls->session_id));
memmove(msg_server_hello + 84, x25519_pub, sizeof(x25519_pub));
// server hello message
mg_iobuf_add(wio, wio->len, "\x16\x03\x03\x00\x7a", 5);
mg_iobuf_add(wio, wio->len, msg_server_hello, sizeof(msg_server_hello));
mg_sha256_update(&tls->sha256, msg_server_hello, sizeof(msg_server_hello));
// change cipher message
mg_iobuf_add(wio, wio->len, "\x14\x03\x03\x00\x01\x01", 6);
}
// at this point we have x25519 shared secret, we can generate a set of derived
// handshake encryption keys
static void mg_tls_generate_handshake_keys(struct mg_connection *c) {
struct tls_data *tls = c->tls;
mg_sha256_ctx sha256;
uint8_t early_secret[32];
uint8_t pre_extract_secret[32];
uint8_t hello_hash[32];
uint8_t server_hs_secret[32];
uint8_t client_hs_secret[32];
mg_hmac_sha256(early_secret, NULL, 0, zeros, sizeof(zeros));
mg_tls_derive_secret("tls13 derived", early_secret, 32, zeros_sha256_digest,
32, pre_extract_secret, 32);
mg_hmac_sha256(tls->handshake_secret, pre_extract_secret,
sizeof(pre_extract_secret), tls->x25519_sec,
sizeof(tls->x25519_sec));
mg_tls_hexdump("hs secret", tls->handshake_secret, 32);
// mg_sha256_final is not idempotent, need to copy sha256 context to calculate
// the digest
memmove(&sha256, &tls->sha256, sizeof(mg_sha256_ctx));
mg_sha256_final(hello_hash, &sha256);
// derive keys needed for the rest of the handshake
mg_tls_derive_secret("tls13 s hs traffic", tls->handshake_secret, 32,
hello_hash, 32, server_hs_secret, 32);
mg_tls_derive_secret("tls13 key", server_hs_secret, 32, NULL, 0,
tls->server_write_key, 16);
mg_tls_derive_secret("tls13 iv", server_hs_secret, 32, NULL, 0,
tls->server_write_iv, 12);
mg_tls_derive_secret("tls13 finished", server_hs_secret, 32, NULL, 0,
tls->server_finished_key, 32);
mg_tls_hexdump("s hs traffic", server_hs_secret, 32);
mg_tls_derive_secret("tls13 c hs traffic", tls->handshake_secret, 32,
hello_hash, 32, client_hs_secret, 32);
mg_tls_derive_secret("tls13 key", client_hs_secret, 32, NULL, 0,
tls->client_write_key, 16);
mg_tls_derive_secret("tls13 iv", client_hs_secret, 32, NULL, 0,
tls->client_write_iv, 12);
mg_tls_derive_secret("tls13 finished", client_hs_secret, 32, NULL, 0,
tls->client_finished_key, 32);
}
// AES GCM encryption of the message + put encoded data into the write buffer
static void mg_tls_encrypt(struct mg_connection *c, const uint8_t *msg,
size_t msgsz, uint8_t msgtype) {
struct tls_data *tls = c->tls;
struct mg_iobuf *wio = &tls->send;
uint8_t *outmsg;
uint8_t *tag;
size_t encsz = msgsz + 16 + 1;
uint8_t hdr[5] = {0x17, 0x03, 0x03, (encsz >> 8) & 0xff, encsz & 0xff};
uint8_t associated_data[5] = {0x17, 0x03, 0x03, (encsz >> 8) & 0xff,
encsz & 0xff};
uint8_t nonce[12];
memmove(nonce, tls->server_write_iv, sizeof(tls->server_write_iv));
nonce[8] ^= (uint8_t) ((tls->sseq >> 24) & 255U);
nonce[9] ^= (uint8_t) ((tls->sseq >> 16) & 255U);
nonce[10] ^= (uint8_t) ((tls->sseq >> 8) & 255U);
nonce[11] ^= (uint8_t) ((tls->sseq) & 255U);
gcm_initialize();
mg_iobuf_add(wio, wio->len, hdr, sizeof(hdr));
mg_iobuf_resize(wio, wio->len + encsz);
outmsg = wio->buf + wio->len;
tag = wio->buf + wio->len + msgsz + 1;
memmove(outmsg, msg, msgsz);
outmsg[msgsz] = msgtype;
aes_gcm_encrypt(outmsg, outmsg, msgsz + 1, tls->server_write_key,
sizeof(tls->server_write_key), nonce, sizeof(nonce),
associated_data, sizeof(associated_data), tag, 16);
wio->len += encsz;
tls->sseq++;
}
// read an encrypted message, decrypt it into read buffer (AES GCM)
static int mg_tls_recv_decrypt(struct mg_connection *c, void *buf,
size_t bufsz) {
struct tls_data *tls = c->tls;
struct mg_iobuf *rio = &c->rtls;
// struct mg_iobuf *rio = &tls->recv;
uint16_t msgsz;
uint8_t *msg;
uint8_t nonce[12];
int r;
for (;;) {
if (!mg_tls_got_msg(c)) {
return MG_IO_WAIT;
}
if (rio->buf[0] == 0x17) {
break;
} else if (rio->buf[0] == 0x15) {
MG_INFO(("TLS ALERT packet received")); // TODO: drop packet?
} else {
mg_error(c, "unexpected packet");
return -1;
}
}
msgsz = MG_LOAD_BE16(rio->buf + 3);
msg = rio->buf + 5;
memmove(nonce, tls->client_write_iv, sizeof(tls->client_write_iv));
nonce[8] ^= (uint8_t) ((tls->cseq >> 24) & 255U);
nonce[9] ^= (uint8_t) ((tls->cseq >> 16) & 255U);
nonce[10] ^= (uint8_t) ((tls->cseq >> 8) & 255U);
nonce[11] ^= (uint8_t) ((tls->cseq) & 255U);
aes_gcm_decrypt(msg, msg, msgsz - 16, tls->client_write_key,
sizeof(tls->client_write_key), nonce, sizeof(nonce));
r = msgsz - 16 - 1;
if (msg[r] == 0x17) {
if (bufsz > 0) {
memmove(buf, msg, msgsz - 16);
}
} else {
r = 0;
}
tls->cseq++;
mg_tls_drop_packet(rio);
return r;
}
static void mg_tls_server_extensions(struct mg_connection *c) {
struct tls_data *tls = c->tls;
// server extensions
uint8_t ext[6] = {0x08, 0, 0, 2, 0, 0};
mg_sha256_update(&tls->sha256, ext, sizeof(ext));
mg_tls_encrypt(c, ext, sizeof(ext), 0x16);
}
static void mg_tls_server_cert(struct mg_connection *c) {
struct tls_data *tls = c->tls;
// server DER certificate (empty)
size_t n = tls->server_cert_der.len;
uint8_t *cert = calloc(1, 13 + n); // FIXME: free
cert[0] = 0x0b; // handshake header
cert[1] = (uint8_t) (((n + 9) >> 16) & 255U); // 3 bytes: payload length
cert[2] = (uint8_t) (((n + 9) >> 8) & 255U);
cert[3] = (uint8_t) ((n + 9) & 255U);
cert[4] = 0; // request context
cert[5] = (uint8_t) (((n + 5) >> 16) & 255U); // 3 bytes: cert (s) length
cert[6] = (uint8_t) (((n + 5) >> 8) & 255U);
cert[7] = (uint8_t) ((n + 5) & 255U);
cert[8] =
(uint8_t) (((n) >> 16) & 255U); // 3 bytes: first (and only) cert len
cert[9] = (uint8_t) (((n) >> 8) & 255U);
cert[10] = (uint8_t) (n & 255U);
// bytes 11+ are certificate in DER format
memmove(cert + 11, tls->server_cert_der.ptr, n);
cert[11 + n] = cert[12 + n] = 0; // certificate extensions (none)
mg_sha256_update(&tls->sha256, cert, 13 + n);
mg_tls_encrypt(c, cert, 13 + n, 0x16);
}
// type adapter between uECC hash context and our sha256 implementation
typedef struct SHA256_HashContext {
uECC_HashContext uECC;
mg_sha256_ctx ctx;
} SHA256_HashContext;
static void init_SHA256(const uECC_HashContext *base) {
SHA256_HashContext *c = (SHA256_HashContext *) base;
mg_sha256_init(&c->ctx);
}
static void update_SHA256(const uECC_HashContext *base, const uint8_t *message,
unsigned message_size) {
SHA256_HashContext *c = (SHA256_HashContext *) base;
mg_sha256_update(&c->ctx, message, message_size);
}
static void finish_SHA256(const uECC_HashContext *base, uint8_t *hash_result) {
SHA256_HashContext *c = (SHA256_HashContext *) base;
mg_sha256_final(hash_result, &c->ctx);
}
static void mg_tls_server_verify_ecdsa(struct mg_connection *c) {
struct tls_data *tls = c->tls;
// server certificate verify packet
uint8_t verify[82] = {0x0f, 0x00, 0x00, 0x00, 0x04, 0x03, 0x00, 0x00};
size_t sigsz, verifysz = 0;
uint8_t hash[32] = {0}, tmp[2 * 32 + 64] = {0};
struct SHA256_HashContext ctx = {
{&init_SHA256, &update_SHA256, &finish_SHA256, 64, 32, tmp},
{{0}, 0, 0, {0}}};
int neg1, neg2;
uint8_t sig[64], sig_content[130] = {
" "
" "
"TLS 1.3, server CertificateVerify\0"};
mg_sha256_ctx sha256;
memmove(&sha256, &tls->sha256, sizeof(mg_sha256_ctx));
mg_sha256_final(sig_content + 98, &sha256);
mg_sha256_init(&sha256);
mg_sha256_update(&sha256, sig_content, sizeof(sig_content));
mg_sha256_final(hash, &sha256);
uECC_sign_deterministic(tls->server_key, hash, sizeof(hash), &ctx.uECC, sig,
uECC_secp256r1());
neg1 = !!(sig[0] & 0x80);
neg2 = !!(sig[32] & 0x80);
verify[8] = 0x30; // ASN.1 SEQUENCE
verify[9] = (uint8_t) (68 + neg1 + neg2);
verify[10] = 0x02; // ASN.1 INTEGER
verify[11] = (uint8_t) (32 + neg1);
memmove(verify + 12 + neg1, sig, 32);
verify[12 + 32 + neg1] = 0x02; // ASN.1 INTEGER
verify[13 + 32 + neg1] = (uint8_t) (32 + neg2);
memmove(verify + 14 + 32 + neg1 + neg2, sig + 32, 32);
sigsz = (size_t) (70 + neg1 + neg2);
verifysz = 8U + sigsz;
verify[3] = (uint8_t) (sigsz + 4);
verify[7] = (uint8_t) sigsz;
mg_tls_hexdump("verify", verify, verifysz);
mg_sha256_update(&tls->sha256, verify, verifysz);
mg_tls_encrypt(c, verify, verifysz, 0x16);
}
static void mg_tls_server_finish(struct mg_connection *c) {
struct tls_data *tls = c->tls;
struct mg_iobuf *wio = &tls->send;
mg_sha256_ctx sha256;
uint8_t hash[32];
uint8_t finish[36] = {0x14, 0, 0, 32};
memmove(&sha256, &tls->sha256, sizeof(mg_sha256_ctx));
mg_sha256_final(hash, &sha256);
mg_hmac_sha256(finish + 4, tls->server_finished_key, 32, hash, 32);
mg_tls_hexdump("hash", hash, sizeof(hash));
mg_tls_hexdump("key", tls->server_finished_key,
sizeof(tls->server_finished_key));
mg_tls_encrypt(c, finish, sizeof(finish), 0x16);
mg_io_send(c, wio->buf, wio->len);
wio->len = 0;
mg_sha256_update(&tls->sha256, finish, sizeof(finish));
}
static int mg_tls_client_change_cipher(struct mg_connection *c) {
// struct tls_data *tls = c->tls;
struct mg_iobuf *rio = &c->rtls;
for (;;) {
if (!mg_tls_got_msg(c)) {
return MG_IO_WAIT;
}
if (rio->buf[0] == 0x14) { // got a ChangeCipher record
break;
} else if (rio->buf[0] == 0x15) { // skip Alert records
MG_DEBUG(("TLS ALERT packet received"));
mg_tls_drop_packet(rio);
} else {
mg_error(c, "unexpected packet");
return MG_IO_ERR;
}
}
// consume ChangeCipher packet
mg_tls_drop_packet(rio);
return 0;
}
static int mg_tls_client_finish(struct mg_connection *c) {
uint8_t tmp[2048];
int n = mg_tls_recv_decrypt(c, tmp, sizeof(tmp));
if (n < 0) {
return -1;
}
// TODO: make sure it's a ClientFinish record
return 0;
}
static void mg_tls_generate_application_keys(struct mg_connection *c) {
struct tls_data *tls = c->tls;
uint8_t hash[32];
uint8_t premaster_secret[32];
uint8_t master_secret[32];
uint8_t server_secret[32];
uint8_t client_secret[32];
mg_sha256_ctx sha256;
memmove(&sha256, &tls->sha256, sizeof(mg_sha256_ctx));
mg_sha256_final(hash, &sha256);
mg_tls_derive_secret("tls13 derived", tls->handshake_secret, 32,
zeros_sha256_digest, 32, premaster_secret, 32);
mg_hmac_sha256(master_secret, premaster_secret, 32, zeros, 32);
mg_tls_derive_secret("tls13 s ap traffic", master_secret, 32, hash, 32,
server_secret, 32);
mg_tls_derive_secret("tls13 key", server_secret, 32, NULL, 0,
tls->server_write_key, 16);
mg_tls_derive_secret("tls13 iv", server_secret, 32, NULL, 0,
tls->server_write_iv, 12);
mg_tls_derive_secret("tls13 c ap traffic", master_secret, 32, hash, 32,
client_secret, 32);
mg_tls_derive_secret("tls13 key", client_secret, 32, NULL, 0,
tls->client_write_key, 16);
mg_tls_derive_secret("tls13 iv", client_secret, 32, NULL, 0,
tls->client_write_iv, 12);
tls->sseq = tls->cseq = 0;
}
void mg_tls_handshake(struct mg_connection *c) {
struct tls_data *tls = c->tls;
switch (tls->state) {
case MG_TLS_HS_CLIENT_HELLO:
if (mg_tls_client_hello(c) < 0) {
return;
}
tls->state = MG_TLS_HS_SERVER_HELLO;
// fallthrough
case MG_TLS_HS_SERVER_HELLO:
mg_tls_server_hello(c);
mg_tls_generate_handshake_keys(c);
mg_tls_server_extensions(c);
mg_tls_server_cert(c);
mg_tls_server_verify_ecdsa(c);
mg_tls_server_finish(c);
tls->state = MG_TLS_HS_CLIENT_CHANGE_CIPHER;
// fallthrough
case MG_TLS_HS_CLIENT_CHANGE_CIPHER:
if (mg_tls_client_change_cipher(c) < 0) {
return;
}
tls->state = MG_TLS_HS_CLIENT_FINISH;
// fallthrough
case MG_TLS_HS_CLIENT_FINISH:
if (mg_tls_client_finish(c) < 0) {
return;
}
mg_tls_generate_application_keys(c);
tls->state = MG_TLS_HS_DONE;
// fallthrough
case MG_TLS_HS_DONE: c->is_tls_hs = 0; return;
}
}
static int mg_parse_pem(const struct mg_str pem, const struct mg_str label,
struct mg_str *der) {
size_t n = 0, m = 0;
char *s;
const char *c;
struct mg_str caps[5];
if (!mg_match(pem, mg_str("#-----BEGIN #-----#-----END #-----#"), caps)) {
*der = mg_strdup(pem);
return 0;
}
if (mg_strcmp(caps[1], label) != 0 || mg_strcmp(caps[3], label) != 0) {
return -1; // bad label
}
if ((s = calloc(1, caps[2].len)) == NULL) {
return -1;
}
for (c = caps[2].ptr; c < caps[2].ptr + caps[2].len; c++) {
if (*c == ' ' || *c == '\n' || *c == '\r' || *c == '\t') {
continue;
}
s[n++] = *c;
}
m = mg_base64_decode(s, n, s, n);
if (m == 0) {
free(s);
return -1;
}
der->ptr = s;
der->len = m;
return 0;
}
void mg_tls_init(struct mg_connection *c, const struct mg_tls_opts *opts) {
struct mg_str key;
struct tls_data *tls = (struct tls_data *) calloc(1, sizeof(struct tls_data));
if (tls == NULL) {
mg_error(c, "tls oom");
return;
}
// parse PEM or DER EC key
if (opts->key.ptr == NULL ||
mg_parse_pem(opts->key, mg_str_s("EC PRIVATE KEY"), &key) < 0) {
MG_ERROR(("Failed to load EC private key"));
return;
}
if (key.len < 39) {
MG_ERROR(("EC private key too short"));
return;
}
// expect ASN.1 SEQUENCE=[INTEGER=1, BITSTRING of 32 bytes, ...]
// 30 nn 02 01 01 04 20 [key] ...
if (key.ptr[0] != 0x30 || (key.ptr[1] & 0x80) != 0) {
MG_ERROR(("EC private key: ASN.1 bad sequence"));
return;
}
if (memcmp(key.ptr + 2, "\x02\x01\x01\x04\x20", 5) != 0) {
MG_ERROR(("EC private key: ASN.1 bad data"));
}
memmove(tls->server_key, key.ptr + 7, 32);
free((void *) key.ptr);
// parse PEM or DER certificate
if (mg_parse_pem(opts->cert, mg_str_s("CERTIFICATE"), &tls->server_cert_der) <
0) {
MG_ERROR(("Failed to load certificate"));
return;
}
// tls->send.align = tls->recv.align = MG_IO_SIZE;
tls->send.align = MG_IO_SIZE;
c->tls = tls;
c->is_tls = c->is_tls_hs = 1;
mg_sha256_init(&tls->sha256);
}
void mg_tls_free(struct mg_connection *c) {
struct tls_data *tls = c->tls;
if (tls != NULL) {
mg_iobuf_free(&tls->send);
free((void *) tls->server_cert_der.ptr);
}
free(c->tls);
c->tls = NULL;
}
long mg_tls_send(struct mg_connection *c, const void *buf, size_t len) {
struct tls_data *tls = c->tls;
long n = MG_IO_WAIT;
if (len > MG_IO_SIZE) len = MG_IO_SIZE;
mg_tls_encrypt(c, buf, len, 0x17);
while (tls->send.len > 0 &&
(n = mg_io_send(c, tls->send.buf, tls->send.len)) > 0) {
mg_iobuf_del(&tls->send, 0, (size_t) n);
}
if (n == MG_IO_ERR || n == MG_IO_WAIT) return n;
return (long) len;
}
long mg_tls_recv(struct mg_connection *c, void *buf, size_t len) {
return mg_tls_recv_decrypt(c, buf, len);
}
size_t mg_tls_pending(struct mg_connection *c) {
return mg_tls_got_msg(c) ? 1 : 0;
}
void mg_tls_ctx_init(struct mg_mgr *mgr) {
(void) mgr;
}
void mg_tls_ctx_free(struct mg_mgr *mgr) {
(void) mgr;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/tls_dummy.c"
#endif
#if MG_TLS == MG_TLS_NONE
void mg_tls_init(struct mg_connection *c, const struct mg_tls_opts *opts) {
(void) opts;
mg_error(c, "TLS is not enabled");
}
void mg_tls_handshake(struct mg_connection *c) {
(void) c;
}
void mg_tls_free(struct mg_connection *c) {
(void) c;
}
long mg_tls_recv(struct mg_connection *c, void *buf, size_t len) {
return c == NULL || buf == NULL || len == 0 ? 0 : -1;
}
long mg_tls_send(struct mg_connection *c, const void *buf, size_t len) {
return c == NULL || buf == NULL || len == 0 ? 0 : -1;
}
size_t mg_tls_pending(struct mg_connection *c) {
(void) c;
return 0;
}
void mg_tls_ctx_init(struct mg_mgr *mgr) {
(void) mgr;
}
void mg_tls_ctx_free(struct mg_mgr *mgr) {
(void) mgr;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/tls_mbed.c"
#endif
#if MG_TLS == MG_TLS_MBED
#if defined(MBEDTLS_VERSION_NUMBER) && MBEDTLS_VERSION_NUMBER >= 0x03000000
#define MG_MBEDTLS_RNG_GET , mg_mbed_rng, NULL
#else
#define MG_MBEDTLS_RNG_GET
#endif
static int mg_mbed_rng(void *ctx, unsigned char *buf, size_t len) {
mg_random(buf, len);
(void) ctx;
return 0;
}
static bool mg_load_cert(struct mg_str str, mbedtls_x509_crt *p) {
int rc;
if (str.ptr == NULL || str.ptr[0] == '\0' || str.ptr[0] == '*') return true;
if (str.ptr[0] == '-') str.len++; // PEM, include trailing NUL
if ((rc = mbedtls_x509_crt_parse(p, (uint8_t *) str.ptr, str.len)) != 0) {
MG_ERROR(("cert err %#x", -rc));
return false;
}
return true;
}
static bool mg_load_key(struct mg_str str, mbedtls_pk_context *p) {
int rc;
if (str.ptr == NULL || str.ptr[0] == '\0' || str.ptr[0] == '*') return true;
if (str.ptr[0] == '-') str.len++; // PEM, include trailing NUL
if ((rc = mbedtls_pk_parse_key(p, (uint8_t *) str.ptr, str.len, NULL,
0 MG_MBEDTLS_RNG_GET)) != 0) {
MG_ERROR(("key err %#x", -rc));
return false;
}
return true;
}
void mg_tls_free(struct mg_connection *c) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
if (tls != NULL) {
mbedtls_ssl_free(&tls->ssl);
mbedtls_pk_free(&tls->pk);
mbedtls_x509_crt_free(&tls->ca);
mbedtls_x509_crt_free(&tls->cert);
mbedtls_ssl_config_free(&tls->conf);
#ifdef MBEDTLS_SSL_SESSION_TICKETS
mbedtls_ssl_ticket_free(&tls->ticket);
#endif
free(tls);
c->tls = NULL;
}
}
static int mg_net_send(void *ctx, const unsigned char *buf, size_t len) {
long n = mg_io_send((struct mg_connection *) ctx, buf, len);
MG_VERBOSE(("%lu n=%ld e=%d", ((struct mg_connection *) ctx)->id, n, errno));
if (n == MG_IO_WAIT) return MBEDTLS_ERR_SSL_WANT_WRITE;
if (n == MG_IO_RESET) return MBEDTLS_ERR_NET_CONN_RESET;
if (n == MG_IO_ERR) return MBEDTLS_ERR_NET_SEND_FAILED;
return (int) n;
}
static int mg_net_recv(void *ctx, unsigned char *buf, size_t len) {
long n = mg_io_recv((struct mg_connection *) ctx, buf, len);
MG_VERBOSE(("%lu n=%ld", ((struct mg_connection *) ctx)->id, n));
if (n == MG_IO_WAIT) return MBEDTLS_ERR_SSL_WANT_WRITE;
if (n == MG_IO_RESET) return MBEDTLS_ERR_NET_CONN_RESET;
if (n == MG_IO_ERR) return MBEDTLS_ERR_NET_RECV_FAILED;
return (int) n;
}
void mg_tls_handshake(struct mg_connection *c) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
int rc = mbedtls_ssl_handshake(&tls->ssl);
if (rc == 0) { // Success
MG_DEBUG(("%lu success", c->id));
c->is_tls_hs = 0;
mg_call(c, MG_EV_TLS_HS, NULL);
} else if (rc == MBEDTLS_ERR_SSL_WANT_READ ||
rc == MBEDTLS_ERR_SSL_WANT_WRITE) { // Still pending
MG_VERBOSE(("%lu pending, %d%d %d (-%#x)", c->id, c->is_connecting,
c->is_tls_hs, rc, -rc));
} else {
mg_error(c, "TLS handshake: -%#x", -rc); // Error
}
}
static void debug_cb(void *c, int lev, const char *s, int n, const char *s2) {
n = (int) strlen(s2) - 1;
MG_INFO(("%lu %d %.*s", ((struct mg_connection *) c)->id, lev, n, s2));
(void) s;
}
void mg_tls_init(struct mg_connection *c, const struct mg_tls_opts *opts) {
struct mg_tls *tls = (struct mg_tls *) calloc(1, sizeof(*tls));
int rc = 0;
c->tls = tls;
if (c->tls == NULL) {
mg_error(c, "TLS OOM");
goto fail;
}
if (c->is_listening) goto fail;
MG_DEBUG(("%lu Setting TLS", c->id));
MG_PROF_ADD(c, "mbedtls_init_start");
mbedtls_ssl_init(&tls->ssl);
mbedtls_ssl_config_init(&tls->conf);
mbedtls_x509_crt_init(&tls->ca);
mbedtls_x509_crt_init(&tls->cert);
mbedtls_pk_init(&tls->pk);
mbedtls_ssl_conf_dbg(&tls->conf, debug_cb, c);
#if defined(MG_MBEDTLS_DEBUG_LEVEL)
mbedtls_debug_set_threshold(MG_MBEDTLS_DEBUG_LEVEL);
#endif
if ((rc = mbedtls_ssl_config_defaults(
&tls->conf,
c->is_client ? MBEDTLS_SSL_IS_CLIENT : MBEDTLS_SSL_IS_SERVER,
MBEDTLS_SSL_TRANSPORT_STREAM, MBEDTLS_SSL_PRESET_DEFAULT)) != 0) {
mg_error(c, "tls defaults %#x", -rc);
goto fail;
}
mbedtls_ssl_conf_rng(&tls->conf, mg_mbed_rng, c);
if (opts->ca.len == 0 || mg_vcmp(&opts->ca, "*") == 0) {
mbedtls_ssl_conf_authmode(&tls->conf, MBEDTLS_SSL_VERIFY_NONE);
} else {
if (mg_load_cert(opts->ca, &tls->ca) == false) goto fail;
mbedtls_ssl_conf_ca_chain(&tls->conf, &tls->ca, NULL);
if (c->is_client && opts->name.ptr != NULL && opts->name.ptr[0] != '\0') {
char *host = mg_mprintf("%.*s", opts->name.len, opts->name.ptr);
mbedtls_ssl_set_hostname(&tls->ssl, host);
MG_DEBUG(("%lu hostname verification: %s", c->id, host));
free(host);
}
mbedtls_ssl_conf_authmode(&tls->conf, MBEDTLS_SSL_VERIFY_REQUIRED);
}
if (!mg_load_cert(opts->cert, &tls->cert)) goto fail;
if (!mg_load_key(opts->key, &tls->pk)) goto fail;
if (tls->cert.version &&
(rc = mbedtls_ssl_conf_own_cert(&tls->conf, &tls->cert, &tls->pk)) != 0) {
mg_error(c, "own cert %#x", -rc);
goto fail;
}
#ifdef MBEDTLS_SSL_SESSION_TICKETS
mbedtls_ssl_conf_session_tickets_cb(
&tls->conf, mbedtls_ssl_ticket_write, mbedtls_ssl_ticket_parse,
&((struct mg_tls_ctx *) c->mgr->tls_ctx)->tickets);
#endif
if ((rc = mbedtls_ssl_setup(&tls->ssl, &tls->conf)) != 0) {
mg_error(c, "setup err %#x", -rc);
goto fail;
}
c->is_tls = 1;
c->is_tls_hs = 1;
mbedtls_ssl_set_bio(&tls->ssl, c, mg_net_send, mg_net_recv, 0);
MG_PROF_ADD(c, "mbedtls_init_end");
if (c->is_client && c->is_resolving == 0 && c->is_connecting == 0) {
mg_tls_handshake(c);
}
return;
fail:
mg_tls_free(c);
}
size_t mg_tls_pending(struct mg_connection *c) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
return tls == NULL ? 0 : mbedtls_ssl_get_bytes_avail(&tls->ssl);
}
long mg_tls_recv(struct mg_connection *c, void *buf, size_t len) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
long n = mbedtls_ssl_read(&tls->ssl, (unsigned char *) buf, len);
if (n == MBEDTLS_ERR_SSL_WANT_READ || n == MBEDTLS_ERR_SSL_WANT_WRITE)
return MG_IO_WAIT;
if (n <= 0) return MG_IO_ERR;
return n;
}
long mg_tls_send(struct mg_connection *c, const void *buf, size_t len) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
long n = mbedtls_ssl_write(&tls->ssl, (unsigned char *) buf, len);
if (n == MBEDTLS_ERR_SSL_WANT_READ || n == MBEDTLS_ERR_SSL_WANT_WRITE)
return MG_IO_WAIT;
if (n <= 0) return MG_IO_ERR;
return n;
}
void mg_tls_ctx_init(struct mg_mgr *mgr) {
struct mg_tls_ctx *ctx = (struct mg_tls_ctx *) calloc(1, sizeof(*ctx));
if (ctx == NULL) {
MG_ERROR(("TLS context init OOM"));
} else {
#ifdef MBEDTLS_SSL_SESSION_TICKETS
int rc;
mbedtls_ssl_ticket_init(&ctx->tickets);
if ((rc = mbedtls_ssl_ticket_setup(&ctx->tickets, mg_mbed_rng, NULL,
MBEDTLS_CIPHER_AES_128_GCM, 86400)) !=
0) {
MG_ERROR((" mbedtls_ssl_ticket_setup %#x", -rc));
}
#endif
mgr->tls_ctx = ctx;
}
}
void mg_tls_ctx_free(struct mg_mgr *mgr) {
struct mg_tls_ctx *ctx = (struct mg_tls_ctx *) mgr->tls_ctx;
if (ctx != NULL) {
#ifdef MBEDTLS_SSL_SESSION_TICKETS
mbedtls_ssl_ticket_free(&ctx->tickets);
#endif
free(ctx);
mgr->tls_ctx = NULL;
}
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/tls_openssl.c"
#endif
#if MG_TLS == MG_TLS_OPENSSL
static int tls_err_cb(const char *s, size_t len, void *c) {
int n = (int) len - 1;
MG_ERROR(("%lu %.*s", ((struct mg_connection *) c)->id, n, s));
return 0; // undocumented
}
static int mg_tls_err(struct mg_connection *c, struct mg_tls *tls, int res) {
int err = SSL_get_error(tls->ssl, res);
// We've just fetched the last error from the queue.
// Now we need to clear the error queue. If we do not, then the following
// can happen (actually reported):
// - A new connection is accept()-ed with cert error (e.g. self-signed cert)
// - Since all accept()-ed connections share listener's context,
// - *ALL* SSL accepted connection report read error on the next poll cycle.
// Thus a single errored connection can close all the rest, unrelated ones.
// Clearing the error keeps the shared SSL_CTX in an OK state.
if (err != 0) ERR_print_errors_cb(tls_err_cb, c);
ERR_clear_error();
if (err == SSL_ERROR_WANT_READ) return 0;
if (err == SSL_ERROR_WANT_WRITE) return 0;
return err;
}
static STACK_OF(X509_INFO) * load_ca_certs(struct mg_str ca) {
BIO *bio = BIO_new_mem_buf(ca.ptr, (int) ca.len);
STACK_OF(X509_INFO) *certs =
bio ? PEM_X509_INFO_read_bio(bio, NULL, NULL, NULL) : NULL;
if (bio) BIO_free(bio);
return certs;
}
static bool add_ca_certs(SSL_CTX *ctx, STACK_OF(X509_INFO) * certs) {
X509_STORE *cert_store = SSL_CTX_get_cert_store(ctx);
for (int i = 0; i < sk_X509_INFO_num(certs); i++) {
X509_INFO *cert_info = sk_X509_INFO_value(certs, i);
if (cert_info->x509 && !X509_STORE_add_cert(cert_store, cert_info->x509))
return false;
}
return true;
}
static EVP_PKEY *load_key(struct mg_str s) {
BIO *bio = BIO_new_mem_buf(s.ptr, (int) (long) s.len);
EVP_PKEY *key = bio ? PEM_read_bio_PrivateKey(bio, NULL, 0, NULL) : NULL;
if (bio) BIO_free(bio);
return key;
}
static X509 *load_cert(struct mg_str s) {
BIO *bio = BIO_new_mem_buf(s.ptr, (int) (long) s.len);
X509 *cert = bio == NULL ? NULL
: s.ptr[0] == '-'
? PEM_read_bio_X509(bio, NULL, NULL, NULL) // PEM
: d2i_X509_bio(bio, NULL); // DER
if (bio) BIO_free(bio);
return cert;
}
static long mg_bio_ctrl(BIO *b, int cmd, long larg, void *pargs) {
long ret = 0;
if (cmd == BIO_CTRL_PUSH) ret = 1;
if (cmd == BIO_CTRL_POP) ret = 1;
if (cmd == BIO_CTRL_FLUSH) ret = 1;
if (cmd == BIO_C_SET_NBIO) ret = 1;
// MG_DEBUG(("%d -> %ld", cmd, ret));
(void) b, (void) cmd, (void) larg, (void) pargs;
return ret;
}
static int mg_bio_read(BIO *bio, char *buf, int len) {
struct mg_connection *c = (struct mg_connection *) BIO_get_data(bio);
long res = mg_io_recv(c, buf, (size_t) len);
// MG_DEBUG(("%p %d %ld", buf, len, res));
len = res > 0 ? (int) res : -1;
if (res == MG_IO_WAIT) BIO_set_retry_read(bio);
return len;
}
static int mg_bio_write(BIO *bio, const char *buf, int len) {
struct mg_connection *c = (struct mg_connection *) BIO_get_data(bio);
long res = mg_io_send(c, buf, (size_t) len);
// MG_DEBUG(("%p %d %ld", buf, len, res));
len = res > 0 ? (int) res : -1;
if (res == MG_IO_WAIT) BIO_set_retry_write(bio);
return len;
}
void mg_tls_init(struct mg_connection *c, const struct mg_tls_opts *opts) {
struct mg_tls *tls = (struct mg_tls *) calloc(1, sizeof(*tls));
const char *id = "mongoose";
static unsigned char s_initialised = 0;
BIO *bio = NULL;
int rc;
if (tls == NULL) {
mg_error(c, "TLS OOM");
goto fail;
}
if (!s_initialised) {
SSL_library_init();
s_initialised++;
}
MG_DEBUG(("%lu Setting TLS", c->id));
tls->ctx = c->is_client ? SSL_CTX_new(SSLv23_client_method())
: SSL_CTX_new(SSLv23_server_method());
if ((tls->ssl = SSL_new(tls->ctx)) == NULL) {
mg_error(c, "SSL_new");
goto fail;
}
SSL_set_session_id_context(tls->ssl, (const uint8_t *) id,
(unsigned) strlen(id));
// Disable deprecated protocols
SSL_set_options(tls->ssl, SSL_OP_NO_SSLv2);
SSL_set_options(tls->ssl, SSL_OP_NO_SSLv3);
SSL_set_options(tls->ssl, SSL_OP_NO_TLSv1);
SSL_set_options(tls->ssl, SSL_OP_NO_TLSv1_1);
#ifdef MG_ENABLE_OPENSSL_NO_COMPRESSION
SSL_set_options(tls->ssl, SSL_OP_NO_COMPRESSION);
#endif
#ifdef MG_ENABLE_OPENSSL_CIPHER_SERVER_PREFERENCE
SSL_set_options(tls->ssl, SSL_OP_CIPHER_SERVER_PREFERENCE);
#endif
if (opts->ca.ptr != NULL && opts->ca.ptr[0] != '\0') {
SSL_set_verify(tls->ssl, SSL_VERIFY_PEER | SSL_VERIFY_FAIL_IF_NO_PEER_CERT,
NULL);
STACK_OF(X509_INFO) *certs = load_ca_certs(opts->ca);
rc = add_ca_certs(tls->ctx, certs);
sk_X509_INFO_pop_free(certs, X509_INFO_free);
if (!rc) {
mg_error(c, "CA err");
goto fail;
}
}
if (opts->cert.ptr != NULL && opts->cert.ptr[0] != '\0') {
X509 *cert = load_cert(opts->cert);
rc = cert == NULL ? 0 : SSL_use_certificate(tls->ssl, cert);
X509_free(cert);
if (cert == NULL || rc != 1) {
mg_error(c, "CERT err %d", mg_tls_err(c, tls, rc));
goto fail;
}
}
if (opts->key.ptr != NULL && opts->key.ptr[0] != '\0') {
EVP_PKEY *key = load_key(opts->key);
rc = key == NULL ? 0 : SSL_use_PrivateKey(tls->ssl, key);
EVP_PKEY_free(key);
if (key == NULL || rc != 1) {
mg_error(c, "KEY err %d", mg_tls_err(c, tls, rc));
goto fail;
}
}
SSL_set_mode(tls->ssl, SSL_MODE_ACCEPT_MOVING_WRITE_BUFFER);
#if OPENSSL_VERSION_NUMBER > 0x10002000L
(void) SSL_set_ecdh_auto(tls->ssl, 1);
#endif
#if OPENSSL_VERSION_NUMBER >= 0x10100000L
if (opts->name.len > 0) {
char *s = mg_mprintf("%.*s", (int) opts->name.len, opts->name.ptr);
SSL_set1_host(tls->ssl, s);
SSL_set_tlsext_host_name(tls->ssl, s);
free(s);
}
#endif
tls->bm = BIO_meth_new(BIO_get_new_index() | BIO_TYPE_SOURCE_SINK, "bio_mg");
BIO_meth_set_write(tls->bm, mg_bio_write);
BIO_meth_set_read(tls->bm, mg_bio_read);
BIO_meth_set_ctrl(tls->bm, mg_bio_ctrl);
bio = BIO_new(tls->bm);
BIO_set_data(bio, c);
SSL_set_bio(tls->ssl, bio, bio);
c->tls = tls;
c->is_tls = 1;
c->is_tls_hs = 1;
if (c->is_client && c->is_resolving == 0 && c->is_connecting == 0) {
mg_tls_handshake(c);
}
MG_DEBUG(("%lu SSL %s OK", c->id, c->is_accepted ? "accept" : "client"));
return;
fail:
free(tls);
}
void mg_tls_handshake(struct mg_connection *c) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
int rc = c->is_client ? SSL_connect(tls->ssl) : SSL_accept(tls->ssl);
if (rc == 1) {
MG_DEBUG(("%lu success", c->id));
c->is_tls_hs = 0;
mg_call(c, MG_EV_TLS_HS, NULL);
} else {
int code = mg_tls_err(c, tls, rc);
if (code != 0) mg_error(c, "tls hs: rc %d, err %d", rc, code);
}
}
void mg_tls_free(struct mg_connection *c) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
if (tls == NULL) return;
SSL_free(tls->ssl);
SSL_CTX_free(tls->ctx);
BIO_meth_free(tls->bm);
free(tls);
c->tls = NULL;
}
size_t mg_tls_pending(struct mg_connection *c) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
return tls == NULL ? 0 : (size_t) SSL_pending(tls->ssl);
}
long mg_tls_recv(struct mg_connection *c, void *buf, size_t len) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
int n = SSL_read(tls->ssl, buf, (int) len);
if (n < 0 && mg_tls_err(c, tls, n) == 0) return MG_IO_WAIT;
if (n <= 0) return MG_IO_ERR;
return n;
}
long mg_tls_send(struct mg_connection *c, const void *buf, size_t len) {
struct mg_tls *tls = (struct mg_tls *) c->tls;
int n = SSL_write(tls->ssl, buf, (int) len);
if (n < 0 && mg_tls_err(c, tls, n) == 0) return MG_IO_WAIT;
if (n <= 0) return MG_IO_ERR;
return n;
}
void mg_tls_ctx_init(struct mg_mgr *mgr) {
(void) mgr;
}
void mg_tls_ctx_free(struct mg_mgr *mgr) {
(void) mgr;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/tls_uecc.c"
#endif
/* Copyright 2014, Kenneth MacKay. Licensed under the BSD 2-clause license. */
#if MG_TLS == MG_TLS_BUILTIN
#ifndef uECC_RNG_MAX_TRIES
#define uECC_RNG_MAX_TRIES 64
#endif
#if uECC_ENABLE_VLI_API
#define uECC_VLI_API
#else
#define uECC_VLI_API static
#endif
#if (uECC_PLATFORM == uECC_avr) || (uECC_PLATFORM == uECC_arm) || \
(uECC_PLATFORM == uECC_arm_thumb) || (uECC_PLATFORM == uECC_arm_thumb2)
#define CONCATX(a, ...) a##__VA_ARGS__
#define CONCAT(a, ...) CONCATX(a, __VA_ARGS__)
#define STRX(a) #a
#define STR(a) STRX(a)
#define EVAL(...) EVAL1(EVAL1(EVAL1(EVAL1(__VA_ARGS__))))
#define EVAL1(...) EVAL2(EVAL2(EVAL2(EVAL2(__VA_ARGS__))))
#define EVAL2(...) EVAL3(EVAL3(EVAL3(EVAL3(__VA_ARGS__))))
#define EVAL3(...) EVAL4(EVAL4(EVAL4(EVAL4(__VA_ARGS__))))
#define EVAL4(...) __VA_ARGS__
#define DEC_1 0
#define DEC_2 1
#define DEC_3 2
#define DEC_4 3
#define DEC_5 4
#define DEC_6 5
#define DEC_7 6
#define DEC_8 7
#define DEC_9 8
#define DEC_10 9
#define DEC_11 10
#define DEC_12 11
#define DEC_13 12
#define DEC_14 13
#define DEC_15 14
#define DEC_16 15
#define DEC_17 16
#define DEC_18 17
#define DEC_19 18
#define DEC_20 19
#define DEC_21 20
#define DEC_22 21
#define DEC_23 22
#define DEC_24 23
#define DEC_25 24
#define DEC_26 25
#define DEC_27 26
#define DEC_28 27
#define DEC_29 28
#define DEC_30 29
#define DEC_31 30
#define DEC_32 31
#define DEC(N) CONCAT(DEC_, N)
#define SECOND_ARG(_, val, ...) val
#define SOME_CHECK_0 ~, 0
#define GET_SECOND_ARG(...) SECOND_ARG(__VA_ARGS__, SOME, )
#define SOME_OR_0(N) GET_SECOND_ARG(CONCAT(SOME_CHECK_, N))
#define EMPTY(...)
#define DEFER(...) __VA_ARGS__ EMPTY()
#define REPEAT_NAME_0() REPEAT_0
#define REPEAT_NAME_SOME() REPEAT_SOME
#define REPEAT_0(...)
#define REPEAT_SOME(N, stuff) \
DEFER(CONCAT(REPEAT_NAME_, SOME_OR_0(DEC(N))))()(DEC(N), stuff) stuff
#define REPEAT(N, stuff) EVAL(REPEAT_SOME(N, stuff))
#define REPEATM_NAME_0() REPEATM_0
#define REPEATM_NAME_SOME() REPEATM_SOME
#define REPEATM_0(...)
#define REPEATM_SOME(N, macro) \
macro(N) DEFER(CONCAT(REPEATM_NAME_, SOME_OR_0(DEC(N))))()(DEC(N), macro)
#define REPEATM(N, macro) EVAL(REPEATM_SOME(N, macro))
#endif
//
#if (uECC_WORD_SIZE == 1)
#if uECC_SUPPORTS_secp160r1
#define uECC_MAX_WORDS 21 /* Due to the size of curve_n. */
#endif
#if uECC_SUPPORTS_secp192r1
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 24
#endif
#if uECC_SUPPORTS_secp224r1
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 28
#endif
#if (uECC_SUPPORTS_secp256r1 || uECC_SUPPORTS_secp256k1)
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 32
#endif
#elif (uECC_WORD_SIZE == 4)
#if uECC_SUPPORTS_secp160r1
#define uECC_MAX_WORDS 6 /* Due to the size of curve_n. */
#endif
#if uECC_SUPPORTS_secp192r1
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 6
#endif
#if uECC_SUPPORTS_secp224r1
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 7
#endif
#if (uECC_SUPPORTS_secp256r1 || uECC_SUPPORTS_secp256k1)
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 8
#endif
#elif (uECC_WORD_SIZE == 8)
#if uECC_SUPPORTS_secp160r1
#define uECC_MAX_WORDS 3
#endif
#if uECC_SUPPORTS_secp192r1
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 3
#endif
#if uECC_SUPPORTS_secp224r1
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 4
#endif
#if (uECC_SUPPORTS_secp256r1 || uECC_SUPPORTS_secp256k1)
#undef uECC_MAX_WORDS
#define uECC_MAX_WORDS 4
#endif
#endif /* uECC_WORD_SIZE */
#define BITS_TO_WORDS(num_bits) \
((wordcount_t) ((num_bits + ((uECC_WORD_SIZE * 8) - 1)) / \
(uECC_WORD_SIZE * 8)))
#define BITS_TO_BYTES(num_bits) ((num_bits + 7) / 8)
struct uECC_Curve_t {
wordcount_t num_words;
wordcount_t num_bytes;
bitcount_t num_n_bits;
uECC_word_t p[uECC_MAX_WORDS];
uECC_word_t n[uECC_MAX_WORDS];
uECC_word_t G[uECC_MAX_WORDS * 2];
uECC_word_t b[uECC_MAX_WORDS];
void (*double_jacobian)(uECC_word_t *X1, uECC_word_t *Y1, uECC_word_t *Z1,
uECC_Curve curve);
#if uECC_SUPPORT_COMPRESSED_POINT
void (*mod_sqrt)(uECC_word_t *a, uECC_Curve curve);
#endif
void (*x_side)(uECC_word_t *result, const uECC_word_t *x, uECC_Curve curve);
#if (uECC_OPTIMIZATION_LEVEL > 0)
void (*mmod_fast)(uECC_word_t *result, uECC_word_t *product);
#endif
};
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
static void bcopy(uint8_t *dst, const uint8_t *src, unsigned num_bytes) {
while (0 != num_bytes) {
num_bytes--;
dst[num_bytes] = src[num_bytes];
}
}
#endif
static cmpresult_t uECC_vli_cmp_unsafe(const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words);
#if (uECC_PLATFORM == uECC_arm || uECC_PLATFORM == uECC_arm_thumb || \
uECC_PLATFORM == uECC_arm_thumb2)
#endif
#if (uECC_PLATFORM == uECC_avr)
#endif
#ifndef asm_clear
#define asm_clear 0
#endif
#ifndef asm_set
#define asm_set 0
#endif
#ifndef asm_add
#define asm_add 0
#endif
#ifndef asm_sub
#define asm_sub 0
#endif
#ifndef asm_mult
#define asm_mult 0
#endif
#ifndef asm_rshift1
#define asm_rshift1 0
#endif
#ifndef asm_mmod_fast_secp256r1
#define asm_mmod_fast_secp256r1 0
#endif
#if defined(default_RNG_defined) && default_RNG_defined
static uECC_RNG_Function g_rng_function = &default_RNG;
#else
static uECC_RNG_Function g_rng_function = 0;
#endif
void uECC_set_rng(uECC_RNG_Function rng_function) {
g_rng_function = rng_function;
}
uECC_RNG_Function uECC_get_rng(void) {
return g_rng_function;
}
int uECC_curve_private_key_size(uECC_Curve curve) {
return BITS_TO_BYTES(curve->num_n_bits);
}
int uECC_curve_public_key_size(uECC_Curve curve) {
return 2 * curve->num_bytes;
}
#if !asm_clear
uECC_VLI_API void uECC_vli_clear(uECC_word_t *vli, wordcount_t num_words) {
wordcount_t i;
for (i = 0; i < num_words; ++i) {
vli[i] = 0;
}
}
#endif /* !asm_clear */
/* Constant-time comparison to zero - secure way to compare long integers */
/* Returns 1 if vli == 0, 0 otherwise. */
uECC_VLI_API uECC_word_t uECC_vli_isZero(const uECC_word_t *vli,
wordcount_t num_words) {
uECC_word_t bits = 0;
wordcount_t i;
for (i = 0; i < num_words; ++i) {
bits |= vli[i];
}
return (bits == 0);
}
/* Returns nonzero if bit 'bit' of vli is set. */
uECC_VLI_API uECC_word_t uECC_vli_testBit(const uECC_word_t *vli,
bitcount_t bit) {
return (vli[bit >> uECC_WORD_BITS_SHIFT] &
((uECC_word_t) 1 << (bit & uECC_WORD_BITS_MASK)));
}
/* Counts the number of words in vli. */
static wordcount_t vli_numDigits(const uECC_word_t *vli,
const wordcount_t max_words) {
wordcount_t i;
/* Search from the end until we find a non-zero digit.
We do it in reverse because we expect that most digits will be nonzero. */
for (i = max_words - 1; i >= 0 && vli[i] == 0; --i) {
}
return (i + 1);
}
/* Counts the number of bits required to represent vli. */
uECC_VLI_API bitcount_t uECC_vli_numBits(const uECC_word_t *vli,
const wordcount_t max_words) {
uECC_word_t i;
uECC_word_t digit;
wordcount_t num_digits = vli_numDigits(vli, max_words);
if (num_digits == 0) {
return 0;
}
digit = vli[num_digits - 1];
for (i = 0; digit; ++i) {
digit >>= 1;
}
return (((bitcount_t) ((num_digits - 1) << uECC_WORD_BITS_SHIFT)) +
(bitcount_t) i);
}
/* Sets dest = src. */
#if !asm_set
uECC_VLI_API void uECC_vli_set(uECC_word_t *dest, const uECC_word_t *src,
wordcount_t num_words) {
wordcount_t i;
for (i = 0; i < num_words; ++i) {
dest[i] = src[i];
}
}
#endif /* !asm_set */
/* Returns sign of left - right. */
static cmpresult_t uECC_vli_cmp_unsafe(const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words) {
wordcount_t i;
for (i = num_words - 1; i >= 0; --i) {
if (left[i] > right[i]) {
return 1;
} else if (left[i] < right[i]) {
return -1;
}
}
return 0;
}
/* Constant-time comparison function - secure way to compare long integers */
/* Returns one if left == right, zero otherwise. */
uECC_VLI_API uECC_word_t uECC_vli_equal(const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words) {
uECC_word_t diff = 0;
wordcount_t i;
for (i = num_words - 1; i >= 0; --i) {
diff |= (left[i] ^ right[i]);
}
return (diff == 0);
}
uECC_VLI_API uECC_word_t uECC_vli_sub(uECC_word_t *result,
const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words);
/* Returns sign of left - right, in constant time. */
uECC_VLI_API cmpresult_t uECC_vli_cmp(const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words) {
uECC_word_t tmp[uECC_MAX_WORDS];
uECC_word_t neg = !!uECC_vli_sub(tmp, left, right, num_words);
uECC_word_t equal = uECC_vli_isZero(tmp, num_words);
return (cmpresult_t) (!equal - 2 * neg);
}
/* Computes vli = vli >> 1. */
#if !asm_rshift1
uECC_VLI_API void uECC_vli_rshift1(uECC_word_t *vli, wordcount_t num_words) {
uECC_word_t *end = vli;
uECC_word_t carry = 0;
vli += num_words;
while (vli-- > end) {
uECC_word_t temp = *vli;
*vli = (temp >> 1) | carry;
carry = temp << (uECC_WORD_BITS - 1);
}
}
#endif /* !asm_rshift1 */
/* Computes result = left + right, returning carry. Can modify in place. */
#if !asm_add
uECC_VLI_API uECC_word_t uECC_vli_add(uECC_word_t *result,
const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words) {
uECC_word_t carry = 0;
wordcount_t i;
for (i = 0; i < num_words; ++i) {
uECC_word_t sum = left[i] + right[i] + carry;
if (sum != left[i]) {
carry = (sum < left[i]);
}
result[i] = sum;
}
return carry;
}
#endif /* !asm_add */
/* Computes result = left - right, returning borrow. Can modify in place. */
#if !asm_sub
uECC_VLI_API uECC_word_t uECC_vli_sub(uECC_word_t *result,
const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words) {
uECC_word_t borrow = 0;
wordcount_t i;
for (i = 0; i < num_words; ++i) {
uECC_word_t diff = left[i] - right[i] - borrow;
if (diff != left[i]) {
borrow = (diff > left[i]);
}
result[i] = diff;
}
return borrow;
}
#endif /* !asm_sub */
#if !asm_mult || (uECC_SQUARE_FUNC && !asm_square) || \
(uECC_SUPPORTS_secp256k1 && (uECC_OPTIMIZATION_LEVEL > 0) && \
((uECC_WORD_SIZE == 1) || (uECC_WORD_SIZE == 8)))
static void muladd(uECC_word_t a, uECC_word_t b, uECC_word_t *r0,
uECC_word_t *r1, uECC_word_t *r2) {
#if uECC_WORD_SIZE == 8
uint64_t a0 = a & 0xffffffff;
uint64_t a1 = a >> 32;
uint64_t b0 = b & 0xffffffff;
uint64_t b1 = b >> 32;
uint64_t i0 = a0 * b0;
uint64_t i1 = a0 * b1;
uint64_t i2 = a1 * b0;
uint64_t i3 = a1 * b1;
uint64_t p0, p1;
i2 += (i0 >> 32);
i2 += i1;
if (i2 < i1) { /* overflow */
i3 += 0x100000000;
}
p0 = (i0 & 0xffffffff) | (i2 << 32);
p1 = i3 + (i2 >> 32);
*r0 += p0;
*r1 += (p1 + (*r0 < p0));
*r2 += ((*r1 < p1) || (*r1 == p1 && *r0 < p0));
#else
uECC_dword_t p = (uECC_dword_t) a * b;
uECC_dword_t r01 = ((uECC_dword_t) (*r1) << uECC_WORD_BITS) | *r0;
r01 += p;
*r2 += (r01 < p);
*r1 = (uECC_word_t) (r01 >> uECC_WORD_BITS);
*r0 = (uECC_word_t) r01;
#endif
}
#endif /* muladd needed */
#if !asm_mult
uECC_VLI_API void uECC_vli_mult(uECC_word_t *result, const uECC_word_t *left,
const uECC_word_t *right,
wordcount_t num_words) {
uECC_word_t r0 = 0;
uECC_word_t r1 = 0;
uECC_word_t r2 = 0;
wordcount_t i, k;
/* Compute each digit of result in sequence, maintaining the carries. */
for (k = 0; k < num_words; ++k) {
for (i = 0; i <= k; ++i) {
muladd(left[i], right[k - i], &r0, &r1, &r2);
}
result[k] = r0;
r0 = r1;
r1 = r2;
r2 = 0;
}
for (k = num_words; k < num_words * 2 - 1; ++k) {
for (i = (wordcount_t) ((k + 1) - num_words); i < num_words; ++i) {
muladd(left[i], right[k - i], &r0, &r1, &r2);
}
result[k] = r0;
r0 = r1;
r1 = r2;
r2 = 0;
}
result[num_words * 2 - 1] = r0;
}
#endif /* !asm_mult */
#if uECC_SQUARE_FUNC
#if !asm_square
static void mul2add(uECC_word_t a, uECC_word_t b, uECC_word_t *r0,
uECC_word_t *r1, uECC_word_t *r2) {
#if uECC_WORD_SIZE == 8
uint64_t a0 = a & 0xffffffffull;
uint64_t a1 = a >> 32;
uint64_t b0 = b & 0xffffffffull;
uint64_t b1 = b >> 32;
uint64_t i0 = a0 * b0;
uint64_t i1 = a0 * b1;
uint64_t i2 = a1 * b0;
uint64_t i3 = a1 * b1;
uint64_t p0, p1;
i2 += (i0 >> 32);
i2 += i1;
if (i2 < i1) { /* overflow */
i3 += 0x100000000ull;
}
p0 = (i0 & 0xffffffffull) | (i2 << 32);
p1 = i3 + (i2 >> 32);
*r2 += (p1 >> 63);
p1 = (p1 << 1) | (p0 >> 63);
p0 <<= 1;
*r0 += p0;
*r1 += (p1 + (*r0 < p0));
*r2 += ((*r1 < p1) || (*r1 == p1 && *r0 < p0));
#else
uECC_dword_t p = (uECC_dword_t) a * b;
uECC_dword_t r01 = ((uECC_dword_t) (*r1) << uECC_WORD_BITS) | *r0;
*r2 += (p >> (uECC_WORD_BITS * 2 - 1));
p *= 2;
r01 += p;
*r2 += (r01 < p);
*r1 = r01 >> uECC_WORD_BITS;
*r0 = (uECC_word_t) r01;
#endif
}
uECC_VLI_API void uECC_vli_square(uECC_word_t *result, const uECC_word_t *left,
wordcount_t num_words) {
uECC_word_t r0 = 0;
uECC_word_t r1 = 0;
uECC_word_t r2 = 0;
wordcount_t i, k;
for (k = 0; k < num_words * 2 - 1; ++k) {
uECC_word_t min = (k < num_words ? 0 : (k + 1) - num_words);
for (i = min; i <= k && i <= k - i; ++i) {
if (i < k - i) {
mul2add(left[i], left[k - i], &r0, &r1, &r2);
} else {
muladd(left[i], left[k - i], &r0, &r1, &r2);
}
}
result[k] = r0;
r0 = r1;
r1 = r2;
r2 = 0;
}
result[num_words * 2 - 1] = r0;
}
#endif /* !asm_square */
#else /* uECC_SQUARE_FUNC */
#if uECC_ENABLE_VLI_API
uECC_VLI_API void uECC_vli_square(uECC_word_t *result, const uECC_word_t *left,
wordcount_t num_words) {
uECC_vli_mult(result, left, left, num_words);
}
#endif /* uECC_ENABLE_VLI_API */
#endif /* uECC_SQUARE_FUNC */
/* Computes result = (left + right) % mod.
Assumes that left < mod and right < mod, and that result does not overlap
mod. */
uECC_VLI_API void uECC_vli_modAdd(uECC_word_t *result, const uECC_word_t *left,
const uECC_word_t *right,
const uECC_word_t *mod,
wordcount_t num_words) {
uECC_word_t carry = uECC_vli_add(result, left, right, num_words);
if (carry || uECC_vli_cmp_unsafe(mod, result, num_words) != 1) {
/* result > mod (result = mod + remainder), so subtract mod to get
* remainder. */
uECC_vli_sub(result, result, mod, num_words);
}
}
/* Computes result = (left - right) % mod.
Assumes that left < mod and right < mod, and that result does not overlap
mod. */
uECC_VLI_API void uECC_vli_modSub(uECC_word_t *result, const uECC_word_t *left,
const uECC_word_t *right,
const uECC_word_t *mod,
wordcount_t num_words) {
uECC_word_t l_borrow = uECC_vli_sub(result, left, right, num_words);
if (l_borrow) {
/* In this case, result == -diff == (max int) - diff. Since -x % d == d - x,
we can get the correct result from result + mod (with overflow). */
uECC_vli_add(result, result, mod, num_words);
}
}
/* Computes result = product % mod, where product is 2N words long. */
/* Currently only designed to work for curve_p or curve_n. */
uECC_VLI_API void uECC_vli_mmod(uECC_word_t *result, uECC_word_t *product,
const uECC_word_t *mod, wordcount_t num_words) {
uECC_word_t mod_multiple[2 * uECC_MAX_WORDS];
uECC_word_t tmp[2 * uECC_MAX_WORDS];
uECC_word_t *v[2] = {tmp, product};
uECC_word_t index;
/* Shift mod so its highest set bit is at the maximum position. */
bitcount_t shift = (bitcount_t) (
(num_words * 2 * uECC_WORD_BITS) - uECC_vli_numBits(mod, num_words));
wordcount_t word_shift = (wordcount_t) (shift / uECC_WORD_BITS);
wordcount_t bit_shift = (wordcount_t) (shift % uECC_WORD_BITS);
uECC_word_t carry = 0;
uECC_vli_clear(mod_multiple, word_shift);
if (bit_shift > 0) {
for (index = 0; index < (uECC_word_t) num_words; ++index) {
mod_multiple[(uECC_word_t) word_shift + index] =
(uECC_word_t) (mod[index] << bit_shift) | carry;
carry = mod[index] >> (uECC_WORD_BITS - bit_shift);
}
} else {
uECC_vli_set(mod_multiple + word_shift, mod, num_words);
}
for (index = 1; shift >= 0; --shift) {
uECC_word_t borrow = 0;
wordcount_t i;
for (i = 0; i < num_words * 2; ++i) {
uECC_word_t diff = v[index][i] - mod_multiple[i] - borrow;
if (diff != v[index][i]) {
borrow = (diff > v[index][i]);
}
v[1 - index][i] = diff;
}
index = !(index ^ borrow); /* Swap the index if there was no borrow */
uECC_vli_rshift1(mod_multiple, num_words);
mod_multiple[num_words - 1] |= mod_multiple[num_words]
<< (uECC_WORD_BITS - 1);
uECC_vli_rshift1(mod_multiple + num_words, num_words);
}
uECC_vli_set(result, v[index], num_words);
}
/* Computes result = (left * right) % mod. */
uECC_VLI_API void uECC_vli_modMult(uECC_word_t *result, const uECC_word_t *left,
const uECC_word_t *right,
const uECC_word_t *mod,
wordcount_t num_words) {
uECC_word_t product[2 * uECC_MAX_WORDS];
uECC_vli_mult(product, left, right, num_words);
uECC_vli_mmod(result, product, mod, num_words);
}
uECC_VLI_API void uECC_vli_modMult_fast(uECC_word_t *result,
const uECC_word_t *left,
const uECC_word_t *right,
uECC_Curve curve) {
uECC_word_t product[2 * uECC_MAX_WORDS];
uECC_vli_mult(product, left, right, curve->num_words);
#if (uECC_OPTIMIZATION_LEVEL > 0)
curve->mmod_fast(result, product);
#else
uECC_vli_mmod(result, product, curve->p, curve->num_words);
#endif
}
#if uECC_SQUARE_FUNC
#if uECC_ENABLE_VLI_API
/* Computes result = left^2 % mod. */
uECC_VLI_API void uECC_vli_modSquare(uECC_word_t *result,
const uECC_word_t *left,
const uECC_word_t *mod,
wordcount_t num_words) {
uECC_word_t product[2 * uECC_MAX_WORDS];
uECC_vli_square(product, left, num_words);
uECC_vli_mmod(result, product, mod, num_words);
}
#endif /* uECC_ENABLE_VLI_API */
uECC_VLI_API void uECC_vli_modSquare_fast(uECC_word_t *result,
const uECC_word_t *left,
uECC_Curve curve) {
uECC_word_t product[2 * uECC_MAX_WORDS];
uECC_vli_square(product, left, curve->num_words);
#if (uECC_OPTIMIZATION_LEVEL > 0)
curve->mmod_fast(result, product);
#else
uECC_vli_mmod(result, product, curve->p, curve->num_words);
#endif
}
#else /* uECC_SQUARE_FUNC */
#if uECC_ENABLE_VLI_API
uECC_VLI_API void uECC_vli_modSquare(uECC_word_t *result,
const uECC_word_t *left,
const uECC_word_t *mod,
wordcount_t num_words) {
uECC_vli_modMult(result, left, left, mod, num_words);
}
#endif /* uECC_ENABLE_VLI_API */
uECC_VLI_API void uECC_vli_modSquare_fast(uECC_word_t *result,
const uECC_word_t *left,
uECC_Curve curve) {
uECC_vli_modMult_fast(result, left, left, curve);
}
#endif /* uECC_SQUARE_FUNC */
#define EVEN(vli) (!(vli[0] & 1))
static void vli_modInv_update(uECC_word_t *uv, const uECC_word_t *mod,
wordcount_t num_words) {
uECC_word_t carry = 0;
if (!EVEN(uv)) {
carry = uECC_vli_add(uv, uv, mod, num_words);
}
uECC_vli_rshift1(uv, num_words);
if (carry) {
uv[num_words - 1] |= HIGH_BIT_SET;
}
}
/* Computes result = (1 / input) % mod. All VLIs are the same size.
See "From Euclid's GCD to Montgomery Multiplication to the Great Divide" */
uECC_VLI_API void uECC_vli_modInv(uECC_word_t *result, const uECC_word_t *input,
const uECC_word_t *mod,
wordcount_t num_words) {
uECC_word_t a[uECC_MAX_WORDS], b[uECC_MAX_WORDS], u[uECC_MAX_WORDS],
v[uECC_MAX_WORDS];
cmpresult_t cmpResult;
if (uECC_vli_isZero(input, num_words)) {
uECC_vli_clear(result, num_words);
return;
}
uECC_vli_set(a, input, num_words);
uECC_vli_set(b, mod, num_words);
uECC_vli_clear(u, num_words);
u[0] = 1;
uECC_vli_clear(v, num_words);
while ((cmpResult = uECC_vli_cmp_unsafe(a, b, num_words)) != 0) {
if (EVEN(a)) {
uECC_vli_rshift1(a, num_words);
vli_modInv_update(u, mod, num_words);
} else if (EVEN(b)) {
uECC_vli_rshift1(b, num_words);
vli_modInv_update(v, mod, num_words);
} else if (cmpResult > 0) {
uECC_vli_sub(a, a, b, num_words);
uECC_vli_rshift1(a, num_words);
if (uECC_vli_cmp_unsafe(u, v, num_words) < 0) {
uECC_vli_add(u, u, mod, num_words);
}
uECC_vli_sub(u, u, v, num_words);
vli_modInv_update(u, mod, num_words);
} else {
uECC_vli_sub(b, b, a, num_words);
uECC_vli_rshift1(b, num_words);
if (uECC_vli_cmp_unsafe(v, u, num_words) < 0) {
uECC_vli_add(v, v, mod, num_words);
}
uECC_vli_sub(v, v, u, num_words);
vli_modInv_update(v, mod, num_words);
}
}
uECC_vli_set(result, u, num_words);
}
/* ------ Point operations ------ */
/* Copyright 2015, Kenneth MacKay. Licensed under the BSD 2-clause license. */
#ifndef _UECC_CURVE_SPECIFIC_H_
#define _UECC_CURVE_SPECIFIC_H_
#define num_bytes_secp160r1 20
#define num_bytes_secp192r1 24
#define num_bytes_secp224r1 28
#define num_bytes_secp256r1 32
#define num_bytes_secp256k1 32
#if (uECC_WORD_SIZE == 1)
#define num_words_secp160r1 20
#define num_words_secp192r1 24
#define num_words_secp224r1 28
#define num_words_secp256r1 32
#define num_words_secp256k1 32
#define BYTES_TO_WORDS_8(a, b, c, d, e, f, g, h) \
0x##a, 0x##b, 0x##c, 0x##d, 0x##e, 0x##f, 0x##g, 0x##h
#define BYTES_TO_WORDS_4(a, b, c, d) 0x##a, 0x##b, 0x##c, 0x##d
#elif (uECC_WORD_SIZE == 4)
#define num_words_secp160r1 5
#define num_words_secp192r1 6
#define num_words_secp224r1 7
#define num_words_secp256r1 8
#define num_words_secp256k1 8
#define BYTES_TO_WORDS_8(a, b, c, d, e, f, g, h) 0x##d##c##b##a, 0x##h##g##f##e
#define BYTES_TO_WORDS_4(a, b, c, d) 0x##d##c##b##a
#elif (uECC_WORD_SIZE == 8)
#define num_words_secp160r1 3
#define num_words_secp192r1 3
#define num_words_secp224r1 4
#define num_words_secp256r1 4
#define num_words_secp256k1 4
#define BYTES_TO_WORDS_8(a, b, c, d, e, f, g, h) 0x##h##g##f##e##d##c##b##a##U
#define BYTES_TO_WORDS_4(a, b, c, d) 0x##d##c##b##a##U
#endif /* uECC_WORD_SIZE */
#if uECC_SUPPORTS_secp160r1 || uECC_SUPPORTS_secp192r1 || \
uECC_SUPPORTS_secp224r1 || uECC_SUPPORTS_secp256r1
static void double_jacobian_default(uECC_word_t *X1, uECC_word_t *Y1,
uECC_word_t *Z1, uECC_Curve curve) {
/* t1 = X, t2 = Y, t3 = Z */
uECC_word_t t4[uECC_MAX_WORDS];
uECC_word_t t5[uECC_MAX_WORDS];
wordcount_t num_words = curve->num_words;
if (uECC_vli_isZero(Z1, num_words)) {
return;
}
uECC_vli_modSquare_fast(t4, Y1, curve); /* t4 = y1^2 */
uECC_vli_modMult_fast(t5, X1, t4, curve); /* t5 = x1*y1^2 = A */
uECC_vli_modSquare_fast(t4, t4, curve); /* t4 = y1^4 */
uECC_vli_modMult_fast(Y1, Y1, Z1, curve); /* t2 = y1*z1 = z3 */
uECC_vli_modSquare_fast(Z1, Z1, curve); /* t3 = z1^2 */
uECC_vli_modAdd(X1, X1, Z1, curve->p, num_words); /* t1 = x1 + z1^2 */
uECC_vli_modAdd(Z1, Z1, Z1, curve->p, num_words); /* t3 = 2*z1^2 */
uECC_vli_modSub(Z1, X1, Z1, curve->p, num_words); /* t3 = x1 - z1^2 */
uECC_vli_modMult_fast(X1, X1, Z1, curve); /* t1 = x1^2 - z1^4 */
uECC_vli_modAdd(Z1, X1, X1, curve->p, num_words); /* t3 = 2*(x1^2 - z1^4) */
uECC_vli_modAdd(X1, X1, Z1, curve->p, num_words); /* t1 = 3*(x1^2 - z1^4) */
if (uECC_vli_testBit(X1, 0)) {
uECC_word_t l_carry = uECC_vli_add(X1, X1, curve->p, num_words);
uECC_vli_rshift1(X1, num_words);
X1[num_words - 1] |= l_carry << (uECC_WORD_BITS - 1);
} else {
uECC_vli_rshift1(X1, num_words);
}
/* t1 = 3/2*(x1^2 - z1^4) = B */
uECC_vli_modSquare_fast(Z1, X1, curve); /* t3 = B^2 */
uECC_vli_modSub(Z1, Z1, t5, curve->p, num_words); /* t3 = B^2 - A */
uECC_vli_modSub(Z1, Z1, t5, curve->p, num_words); /* t3 = B^2 - 2A = x3 */
uECC_vli_modSub(t5, t5, Z1, curve->p, num_words); /* t5 = A - x3 */
uECC_vli_modMult_fast(X1, X1, t5, curve); /* t1 = B * (A - x3) */
uECC_vli_modSub(t4, X1, t4, curve->p,
num_words); /* t4 = B * (A - x3) - y1^4 = y3 */
uECC_vli_set(X1, Z1, num_words);
uECC_vli_set(Z1, Y1, num_words);
uECC_vli_set(Y1, t4, num_words);
}
/* Computes result = x^3 + ax + b. result must not overlap x. */
static void x_side_default(uECC_word_t *result, const uECC_word_t *x,
uECC_Curve curve) {
uECC_word_t _3[uECC_MAX_WORDS] = {3}; /* -a = 3 */
wordcount_t num_words = curve->num_words;
uECC_vli_modSquare_fast(result, x, curve); /* r = x^2 */
uECC_vli_modSub(result, result, _3, curve->p, num_words); /* r = x^2 - 3 */
uECC_vli_modMult_fast(result, result, x, curve); /* r = x^3 - 3x */
uECC_vli_modAdd(result, result, curve->b, curve->p,
num_words); /* r = x^3 - 3x + b */
}
#endif /* uECC_SUPPORTS_secp... */
#if uECC_SUPPORT_COMPRESSED_POINT
#if uECC_SUPPORTS_secp160r1 || uECC_SUPPORTS_secp192r1 || \
uECC_SUPPORTS_secp256r1 || uECC_SUPPORTS_secp256k1
/* Compute a = sqrt(a) (mod curve_p). */
static void mod_sqrt_default(uECC_word_t *a, uECC_Curve curve) {
bitcount_t i;
uECC_word_t p1[uECC_MAX_WORDS] = {1};
uECC_word_t l_result[uECC_MAX_WORDS] = {1};
wordcount_t num_words = curve->num_words;
/* When curve->p == 3 (mod 4), we can compute
sqrt(a) = a^((curve->p + 1) / 4) (mod curve->p). */
uECC_vli_add(p1, curve->p, p1, num_words); /* p1 = curve_p + 1 */
for (i = uECC_vli_numBits(p1, num_words) - 1; i > 1; --i) {
uECC_vli_modSquare_fast(l_result, l_result, curve);
if (uECC_vli_testBit(p1, i)) {
uECC_vli_modMult_fast(l_result, l_result, a, curve);
}
}
uECC_vli_set(a, l_result, num_words);
}
#endif /* uECC_SUPPORTS_secp... */
#endif /* uECC_SUPPORT_COMPRESSED_POINT */
#if uECC_SUPPORTS_secp160r1
#if (uECC_OPTIMIZATION_LEVEL > 0)
static void vli_mmod_fast_secp160r1(uECC_word_t *result, uECC_word_t *product);
#endif
static const struct uECC_Curve_t curve_secp160r1 = {
num_words_secp160r1,
num_bytes_secp160r1,
161, /* num_n_bits */
{BYTES_TO_WORDS_8(FF, FF, FF, 7F, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_4(FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(57, 22, 75, CA, D3, AE, 27, F9),
BYTES_TO_WORDS_8(C8, F4, 01, 00, 00, 00, 00, 00),
BYTES_TO_WORDS_8(00, 00, 00, 00, 01, 00, 00, 00)},
{BYTES_TO_WORDS_8(82, FC, CB, 13, B9, 8B, C3, 68),
BYTES_TO_WORDS_8(89, 69, 64, 46, 28, 73, F5, 8E),
BYTES_TO_WORDS_4(68, B5, 96, 4A),
BYTES_TO_WORDS_8(32, FB, C5, 7A, 37, 51, 23, 04),
BYTES_TO_WORDS_8(12, C9, DC, 59, 7D, 94, 68, 31),
BYTES_TO_WORDS_4(55, 28, A6, 23)},
{BYTES_TO_WORDS_8(45, FA, 65, C5, AD, D4, D4, 81),
BYTES_TO_WORDS_8(9F, F8, AC, 65, 8B, 7A, BD, 54),
BYTES_TO_WORDS_4(FC, BE, 97, 1C)},
&double_jacobian_default,
#if uECC_SUPPORT_COMPRESSED_POINT
&mod_sqrt_default,
#endif
&x_side_default,
#if (uECC_OPTIMIZATION_LEVEL > 0)
&vli_mmod_fast_secp160r1
#endif
};
uECC_Curve uECC_secp160r1(void) {
return &curve_secp160r1;
}
#if (uECC_OPTIMIZATION_LEVEL > 0 && !asm_mmod_fast_secp160r1)
/* Computes result = product % curve_p
see http://www.isys.uni-klu.ac.at/PDF/2001-0126-MT.pdf page 354
Note that this only works if log2(omega) < log2(p) / 2 */
static void omega_mult_secp160r1(uECC_word_t *result, const uECC_word_t *right);
#if uECC_WORD_SIZE == 8
static void vli_mmod_fast_secp160r1(uECC_word_t *result, uECC_word_t *product) {
uECC_word_t tmp[2 * num_words_secp160r1];
uECC_word_t copy;
uECC_vli_clear(tmp, num_words_secp160r1);
uECC_vli_clear(tmp + num_words_secp160r1, num_words_secp160r1);
omega_mult_secp160r1(tmp,
product + num_words_secp160r1 - 1); /* (Rq, q) = q * c */
product[num_words_secp160r1 - 1] &= 0xffffffff;
copy = tmp[num_words_secp160r1 - 1];
tmp[num_words_secp160r1 - 1] &= 0xffffffff;
uECC_vli_add(result, product, tmp, num_words_secp160r1); /* (C, r) = r + q */
uECC_vli_clear(product, num_words_secp160r1);
tmp[num_words_secp160r1 - 1] = copy;
omega_mult_secp160r1(product, tmp + num_words_secp160r1 - 1); /* Rq*c */
uECC_vli_add(result, result, product,
num_words_secp160r1); /* (C1, r) = r + Rq*c */
while (uECC_vli_cmp_unsafe(result, curve_secp160r1.p, num_words_secp160r1) >
0) {
uECC_vli_sub(result, result, curve_secp160r1.p, num_words_secp160r1);
}
}
static void omega_mult_secp160r1(uint64_t *result, const uint64_t *right) {
uint32_t carry;
unsigned i;
/* Multiply by (2^31 + 1). */
carry = 0;
for (i = 0; i < num_words_secp160r1; ++i) {
uint64_t tmp = (right[i] >> 32) | (right[i + 1] << 32);
result[i] = (tmp << 31) + tmp + carry;
carry = (tmp >> 33) + (result[i] < tmp || (carry && result[i] == tmp));
}
result[i] = carry;
}
#else
static void vli_mmod_fast_secp160r1(uECC_word_t *result, uECC_word_t *product) {
uECC_word_t tmp[2 * num_words_secp160r1];
uECC_word_t carry;
uECC_vli_clear(tmp, num_words_secp160r1);
uECC_vli_clear(tmp + num_words_secp160r1, num_words_secp160r1);
omega_mult_secp160r1(tmp,
product + num_words_secp160r1); /* (Rq, q) = q * c */
carry = uECC_vli_add(result, product, tmp,
num_words_secp160r1); /* (C, r) = r + q */
uECC_vli_clear(product, num_words_secp160r1);
omega_mult_secp160r1(product, tmp + num_words_secp160r1); /* Rq*c */
carry += uECC_vli_add(result, result, product,
num_words_secp160r1); /* (C1, r) = r + Rq*c */
while (carry > 0) {
--carry;
uECC_vli_sub(result, result, curve_secp160r1.p, num_words_secp160r1);
}
if (uECC_vli_cmp_unsafe(result, curve_secp160r1.p, num_words_secp160r1) > 0) {
uECC_vli_sub(result, result, curve_secp160r1.p, num_words_secp160r1);
}
}
#endif
#if uECC_WORD_SIZE == 1
static void omega_mult_secp160r1(uint8_t *result, const uint8_t *right) {
uint8_t carry;
uint8_t i;
/* Multiply by (2^31 + 1). */
uECC_vli_set(result + 4, right, num_words_secp160r1); /* 2^32 */
uECC_vli_rshift1(result + 4, num_words_secp160r1); /* 2^31 */
result[3] = right[0] << 7; /* get last bit from shift */
carry =
uECC_vli_add(result, result, right, num_words_secp160r1); /* 2^31 + 1 */
for (i = num_words_secp160r1; carry; ++i) {
uint16_t sum = (uint16_t) result[i] + carry;
result[i] = (uint8_t) sum;
carry = sum >> 8;
}
}
#elif uECC_WORD_SIZE == 4
static void omega_mult_secp160r1(uint32_t *result, const uint32_t *right) {
uint32_t carry;
unsigned i;
/* Multiply by (2^31 + 1). */
uECC_vli_set(result + 1, right, num_words_secp160r1); /* 2^32 */
uECC_vli_rshift1(result + 1, num_words_secp160r1); /* 2^31 */
result[0] = right[0] << 31; /* get last bit from shift */
carry =
uECC_vli_add(result, result, right, num_words_secp160r1); /* 2^31 + 1 */
for (i = num_words_secp160r1; carry; ++i) {
uint64_t sum = (uint64_t) result[i] + carry;
result[i] = (uint32_t) sum;
carry = sum >> 32;
}
}
#endif /* uECC_WORD_SIZE */
#endif /* (uECC_OPTIMIZATION_LEVEL > 0 && !asm_mmod_fast_secp160r1) */
#endif /* uECC_SUPPORTS_secp160r1 */
#if uECC_SUPPORTS_secp192r1
#if (uECC_OPTIMIZATION_LEVEL > 0)
static void vli_mmod_fast_secp192r1(uECC_word_t *result, uECC_word_t *product);
#endif
static const struct uECC_Curve_t curve_secp192r1 = {
num_words_secp192r1,
num_bytes_secp192r1,
192, /* num_n_bits */
{BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FE, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(31, 28, D2, B4, B1, C9, 6B, 14),
BYTES_TO_WORDS_8(36, F8, DE, 99, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(12, 10, FF, 82, FD, 0A, FF, F4),
BYTES_TO_WORDS_8(00, 88, A1, 43, EB, 20, BF, 7C),
BYTES_TO_WORDS_8(F6, 90, 30, B0, 0E, A8, 8D, 18),
BYTES_TO_WORDS_8(11, 48, 79, 1E, A1, 77, F9, 73),
BYTES_TO_WORDS_8(D5, CD, 24, 6B, ED, 11, 10, 63),
BYTES_TO_WORDS_8(78, DA, C8, FF, 95, 2B, 19, 07)},
{BYTES_TO_WORDS_8(B1, B9, 46, C1, EC, DE, B8, FE),
BYTES_TO_WORDS_8(49, 30, 24, 72, AB, E9, A7, 0F),
BYTES_TO_WORDS_8(E7, 80, 9C, E5, 19, 05, 21, 64)},
&double_jacobian_default,
#if uECC_SUPPORT_COMPRESSED_POINT
&mod_sqrt_default,
#endif
&x_side_default,
#if (uECC_OPTIMIZATION_LEVEL > 0)
&vli_mmod_fast_secp192r1
#endif
};
uECC_Curve uECC_secp192r1(void) {
return &curve_secp192r1;
}
#if (uECC_OPTIMIZATION_LEVEL > 0)
/* Computes result = product % curve_p.
See algorithm 5 and 6 from http://www.isys.uni-klu.ac.at/PDF/2001-0126-MT.pdf
*/
#if uECC_WORD_SIZE == 1
static void vli_mmod_fast_secp192r1(uint8_t *result, uint8_t *product) {
uint8_t tmp[num_words_secp192r1];
uint8_t carry;
uECC_vli_set(result, product, num_words_secp192r1);
uECC_vli_set(tmp, &product[24], num_words_secp192r1);
carry = uECC_vli_add(result, result, tmp, num_words_secp192r1);
tmp[0] = tmp[1] = tmp[2] = tmp[3] = tmp[4] = tmp[5] = tmp[6] = tmp[7] = 0;
tmp[8] = product[24];
tmp[9] = product[25];
tmp[10] = product[26];
tmp[11] = product[27];
tmp[12] = product[28];
tmp[13] = product[29];
tmp[14] = product[30];
tmp[15] = product[31];
tmp[16] = product[32];
tmp[17] = product[33];
tmp[18] = product[34];
tmp[19] = product[35];
tmp[20] = product[36];
tmp[21] = product[37];
tmp[22] = product[38];
tmp[23] = product[39];
carry += uECC_vli_add(result, result, tmp, num_words_secp192r1);
tmp[0] = tmp[8] = product[40];
tmp[1] = tmp[9] = product[41];
tmp[2] = tmp[10] = product[42];
tmp[3] = tmp[11] = product[43];
tmp[4] = tmp[12] = product[44];
tmp[5] = tmp[13] = product[45];
tmp[6] = tmp[14] = product[46];
tmp[7] = tmp[15] = product[47];
tmp[16] = tmp[17] = tmp[18] = tmp[19] = tmp[20] = tmp[21] = tmp[22] =
tmp[23] = 0;
carry += uECC_vli_add(result, result, tmp, num_words_secp192r1);
while (carry || uECC_vli_cmp_unsafe(curve_secp192r1.p, result,
num_words_secp192r1) != 1) {
carry -=
uECC_vli_sub(result, result, curve_secp192r1.p, num_words_secp192r1);
}
}
#elif uECC_WORD_SIZE == 4
static void vli_mmod_fast_secp192r1(uint32_t *result, uint32_t *product) {
uint32_t tmp[num_words_secp192r1];
int carry;
uECC_vli_set(result, product, num_words_secp192r1);
uECC_vli_set(tmp, &product[6], num_words_secp192r1);
carry = uECC_vli_add(result, result, tmp, num_words_secp192r1);
tmp[0] = tmp[1] = 0;
tmp[2] = product[6];
tmp[3] = product[7];
tmp[4] = product[8];
tmp[5] = product[9];
carry += uECC_vli_add(result, result, tmp, num_words_secp192r1);
tmp[0] = tmp[2] = product[10];
tmp[1] = tmp[3] = product[11];
tmp[4] = tmp[5] = 0;
carry += uECC_vli_add(result, result, tmp, num_words_secp192r1);
while (carry || uECC_vli_cmp_unsafe(curve_secp192r1.p, result,
num_words_secp192r1) != 1) {
carry -=
uECC_vli_sub(result, result, curve_secp192r1.p, num_words_secp192r1);
}
}
#else
static void vli_mmod_fast_secp192r1(uint64_t *result, uint64_t *product) {
uint64_t tmp[num_words_secp192r1];
int carry;
uECC_vli_set(result, product, num_words_secp192r1);
uECC_vli_set(tmp, &product[3], num_words_secp192r1);
carry = (int) uECC_vli_add(result, result, tmp, num_words_secp192r1);
tmp[0] = 0;
tmp[1] = product[3];
tmp[2] = product[4];
carry += uECC_vli_add(result, result, tmp, num_words_secp192r1);
tmp[0] = tmp[1] = product[5];
tmp[2] = 0;
carry += uECC_vli_add(result, result, tmp, num_words_secp192r1);
while (carry || uECC_vli_cmp_unsafe(curve_secp192r1.p, result,
num_words_secp192r1) != 1) {
carry -=
uECC_vli_sub(result, result, curve_secp192r1.p, num_words_secp192r1);
}
}
#endif /* uECC_WORD_SIZE */
#endif /* (uECC_OPTIMIZATION_LEVEL > 0) */
#endif /* uECC_SUPPORTS_secp192r1 */
#if uECC_SUPPORTS_secp224r1
#if uECC_SUPPORT_COMPRESSED_POINT
static void mod_sqrt_secp224r1(uECC_word_t *a, uECC_Curve curve);
#endif
#if (uECC_OPTIMIZATION_LEVEL > 0)
static void vli_mmod_fast_secp224r1(uECC_word_t *result, uECC_word_t *product);
#endif
static const struct uECC_Curve_t curve_secp224r1 = {
num_words_secp224r1,
num_bytes_secp224r1,
224, /* num_n_bits */
{BYTES_TO_WORDS_8(01, 00, 00, 00, 00, 00, 00, 00),
BYTES_TO_WORDS_8(00, 00, 00, 00, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_4(FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(3D, 2A, 5C, 5C, 45, 29, DD, 13),
BYTES_TO_WORDS_8(3E, F0, B8, E0, A2, 16, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_4(FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(21, 1D, 5C, 11, D6, 80, 32, 34),
BYTES_TO_WORDS_8(22, 11, C2, 56, D3, C1, 03, 4A),
BYTES_TO_WORDS_8(B9, 90, 13, 32, 7F, BF, B4, 6B),
BYTES_TO_WORDS_4(BD, 0C, 0E, B7),
BYTES_TO_WORDS_8(34, 7E, 00, 85, 99, 81, D5, 44),
BYTES_TO_WORDS_8(64, 47, 07, 5A, A0, 75, 43, CD),
BYTES_TO_WORDS_8(E6, DF, 22, 4C, FB, 23, F7, B5),
BYTES_TO_WORDS_4(88, 63, 37, BD)},
{BYTES_TO_WORDS_8(B4, FF, 55, 23, 43, 39, 0B, 27),
BYTES_TO_WORDS_8(BA, D8, BF, D7, B7, B0, 44, 50),
BYTES_TO_WORDS_8(56, 32, 41, F5, AB, B3, 04, 0C),
BYTES_TO_WORDS_4(85, 0A, 05, B4)},
&double_jacobian_default,
#if uECC_SUPPORT_COMPRESSED_POINT
&mod_sqrt_secp224r1,
#endif
&x_side_default,
#if (uECC_OPTIMIZATION_LEVEL > 0)
&vli_mmod_fast_secp224r1
#endif
};
uECC_Curve uECC_secp224r1(void) {
return &curve_secp224r1;
}
#if uECC_SUPPORT_COMPRESSED_POINT
/* Routine 3.2.4 RS; from http://www.nsa.gov/ia/_files/nist-routines.pdf */
static void mod_sqrt_secp224r1_rs(uECC_word_t *d1, uECC_word_t *e1,
uECC_word_t *f1, const uECC_word_t *d0,
const uECC_word_t *e0,
const uECC_word_t *f0) {
uECC_word_t t[num_words_secp224r1];
uECC_vli_modSquare_fast(t, d0, &curve_secp224r1); /* t <-- d0 ^ 2 */
uECC_vli_modMult_fast(e1, d0, e0, &curve_secp224r1); /* e1 <-- d0 * e0 */
uECC_vli_modAdd(d1, t, f0, curve_secp224r1.p,
num_words_secp224r1); /* d1 <-- t + f0 */
uECC_vli_modAdd(e1, e1, e1, curve_secp224r1.p,
num_words_secp224r1); /* e1 <-- e1 + e1 */
uECC_vli_modMult_fast(f1, t, f0, &curve_secp224r1); /* f1 <-- t * f0 */
uECC_vli_modAdd(f1, f1, f1, curve_secp224r1.p,
num_words_secp224r1); /* f1 <-- f1 + f1 */
uECC_vli_modAdd(f1, f1, f1, curve_secp224r1.p,
num_words_secp224r1); /* f1 <-- f1 + f1 */
}
/* Routine 3.2.5 RSS; from http://www.nsa.gov/ia/_files/nist-routines.pdf */
static void mod_sqrt_secp224r1_rss(uECC_word_t *d1, uECC_word_t *e1,
uECC_word_t *f1, const uECC_word_t *d0,
const uECC_word_t *e0, const uECC_word_t *f0,
const bitcount_t j) {
bitcount_t i;
uECC_vli_set(d1, d0, num_words_secp224r1); /* d1 <-- d0 */
uECC_vli_set(e1, e0, num_words_secp224r1); /* e1 <-- e0 */
uECC_vli_set(f1, f0, num_words_secp224r1); /* f1 <-- f0 */
for (i = 1; i <= j; i++) {
mod_sqrt_secp224r1_rs(d1, e1, f1, d1, e1, f1); /* RS (d1,e1,f1,d1,e1,f1) */
}
}
/* Routine 3.2.6 RM; from http://www.nsa.gov/ia/_files/nist-routines.pdf */
static void mod_sqrt_secp224r1_rm(uECC_word_t *d2, uECC_word_t *e2,
uECC_word_t *f2, const uECC_word_t *c,
const uECC_word_t *d0, const uECC_word_t *e0,
const uECC_word_t *d1,
const uECC_word_t *e1) {
uECC_word_t t1[num_words_secp224r1];
uECC_word_t t2[num_words_secp224r1];
uECC_vli_modMult_fast(t1, e0, e1, &curve_secp224r1); /* t1 <-- e0 * e1 */
uECC_vli_modMult_fast(t1, t1, c, &curve_secp224r1); /* t1 <-- t1 * c */
/* t1 <-- p - t1 */
uECC_vli_modSub(t1, curve_secp224r1.p, t1, curve_secp224r1.p,
num_words_secp224r1);
uECC_vli_modMult_fast(t2, d0, d1, &curve_secp224r1); /* t2 <-- d0 * d1 */
uECC_vli_modAdd(t2, t2, t1, curve_secp224r1.p,
num_words_secp224r1); /* t2 <-- t2 + t1 */
uECC_vli_modMult_fast(t1, d0, e1, &curve_secp224r1); /* t1 <-- d0 * e1 */
uECC_vli_modMult_fast(e2, d1, e0, &curve_secp224r1); /* e2 <-- d1 * e0 */
uECC_vli_modAdd(e2, e2, t1, curve_secp224r1.p,
num_words_secp224r1); /* e2 <-- e2 + t1 */
uECC_vli_modSquare_fast(f2, e2, &curve_secp224r1); /* f2 <-- e2^2 */
uECC_vli_modMult_fast(f2, f2, c, &curve_secp224r1); /* f2 <-- f2 * c */
/* f2 <-- p - f2 */
uECC_vli_modSub(f2, curve_secp224r1.p, f2, curve_secp224r1.p,
num_words_secp224r1);
uECC_vli_set(d2, t2, num_words_secp224r1); /* d2 <-- t2 */
}
/* Routine 3.2.7 RP; from http://www.nsa.gov/ia/_files/nist-routines.pdf */
static void mod_sqrt_secp224r1_rp(uECC_word_t *d1, uECC_word_t *e1,
uECC_word_t *f1, const uECC_word_t *c,
const uECC_word_t *r) {
wordcount_t i;
wordcount_t pow2i = 1;
uECC_word_t d0[num_words_secp224r1];
uECC_word_t e0[num_words_secp224r1] = {1}; /* e0 <-- 1 */
uECC_word_t f0[num_words_secp224r1];
uECC_vli_set(d0, r, num_words_secp224r1); /* d0 <-- r */
/* f0 <-- p - c */
uECC_vli_modSub(f0, curve_secp224r1.p, c, curve_secp224r1.p,
num_words_secp224r1);
for (i = 0; i <= 6; i++) {
mod_sqrt_secp224r1_rss(d1, e1, f1, d0, e0, f0,
pow2i); /* RSS (d1,e1,f1,d0,e0,f0,2^i) */
mod_sqrt_secp224r1_rm(d1, e1, f1, c, d1, e1, d0,
e0); /* RM (d1,e1,f1,c,d1,e1,d0,e0) */
uECC_vli_set(d0, d1, num_words_secp224r1); /* d0 <-- d1 */
uECC_vli_set(e0, e1, num_words_secp224r1); /* e0 <-- e1 */
uECC_vli_set(f0, f1, num_words_secp224r1); /* f0 <-- f1 */
pow2i *= 2;
}
}
/* Compute a = sqrt(a) (mod curve_p). */
/* Routine 3.2.8 mp_mod_sqrt_224; from
* http://www.nsa.gov/ia/_files/nist-routines.pdf */
static void mod_sqrt_secp224r1(uECC_word_t *a, uECC_Curve curve) {
(void) curve;
bitcount_t i;
uECC_word_t e1[num_words_secp224r1];
uECC_word_t f1[num_words_secp224r1];
uECC_word_t d0[num_words_secp224r1];
uECC_word_t e0[num_words_secp224r1];
uECC_word_t f0[num_words_secp224r1];
uECC_word_t d1[num_words_secp224r1];
/* s = a; using constant instead of random value */
mod_sqrt_secp224r1_rp(d0, e0, f0, a, a); /* RP (d0, e0, f0, c, s) */
mod_sqrt_secp224r1_rs(d1, e1, f1, d0, e0,
f0); /* RS (d1, e1, f1, d0, e0, f0) */
for (i = 1; i <= 95; i++) {
uECC_vli_set(d0, d1, num_words_secp224r1); /* d0 <-- d1 */
uECC_vli_set(e0, e1, num_words_secp224r1); /* e0 <-- e1 */
uECC_vli_set(f0, f1, num_words_secp224r1); /* f0 <-- f1 */
mod_sqrt_secp224r1_rs(d1, e1, f1, d0, e0,
f0); /* RS (d1, e1, f1, d0, e0, f0) */
if (uECC_vli_isZero(d1, num_words_secp224r1)) { /* if d1 == 0 */
break;
}
}
uECC_vli_modInv(f1, e0, curve_secp224r1.p,
num_words_secp224r1); /* f1 <-- 1 / e0 */
uECC_vli_modMult_fast(a, d0, f1, &curve_secp224r1); /* a <-- d0 / e0 */
}
#endif /* uECC_SUPPORT_COMPRESSED_POINT */
#if (uECC_OPTIMIZATION_LEVEL > 0)
/* Computes result = product % curve_p
from http://www.nsa.gov/ia/_files/nist-routines.pdf */
#if uECC_WORD_SIZE == 1
static void vli_mmod_fast_secp224r1(uint8_t *result, uint8_t *product) {
uint8_t tmp[num_words_secp224r1];
int8_t carry;
/* t */
uECC_vli_set(result, product, num_words_secp224r1);
/* s1 */
tmp[0] = tmp[1] = tmp[2] = tmp[3] = 0;
tmp[4] = tmp[5] = tmp[6] = tmp[7] = 0;
tmp[8] = tmp[9] = tmp[10] = tmp[11] = 0;
tmp[12] = product[28];
tmp[13] = product[29];
tmp[14] = product[30];
tmp[15] = product[31];
tmp[16] = product[32];
tmp[17] = product[33];
tmp[18] = product[34];
tmp[19] = product[35];
tmp[20] = product[36];
tmp[21] = product[37];
tmp[22] = product[38];
tmp[23] = product[39];
tmp[24] = product[40];
tmp[25] = product[41];
tmp[26] = product[42];
tmp[27] = product[43];
carry = uECC_vli_add(result, result, tmp, num_words_secp224r1);
/* s2 */
tmp[12] = product[44];
tmp[13] = product[45];
tmp[14] = product[46];
tmp[15] = product[47];
tmp[16] = product[48];
tmp[17] = product[49];
tmp[18] = product[50];
tmp[19] = product[51];
tmp[20] = product[52];
tmp[21] = product[53];
tmp[22] = product[54];
tmp[23] = product[55];
tmp[24] = tmp[25] = tmp[26] = tmp[27] = 0;
carry += uECC_vli_add(result, result, tmp, num_words_secp224r1);
/* d1 */
tmp[0] = product[28];
tmp[1] = product[29];
tmp[2] = product[30];
tmp[3] = product[31];
tmp[4] = product[32];
tmp[5] = product[33];
tmp[6] = product[34];
tmp[7] = product[35];
tmp[8] = product[36];
tmp[9] = product[37];
tmp[10] = product[38];
tmp[11] = product[39];
tmp[12] = product[40];
tmp[13] = product[41];
tmp[14] = product[42];
tmp[15] = product[43];
tmp[16] = product[44];
tmp[17] = product[45];
tmp[18] = product[46];
tmp[19] = product[47];
tmp[20] = product[48];
tmp[21] = product[49];
tmp[22] = product[50];
tmp[23] = product[51];
tmp[24] = product[52];
tmp[25] = product[53];
tmp[26] = product[54];
tmp[27] = product[55];
carry -= uECC_vli_sub(result, result, tmp, num_words_secp224r1);
/* d2 */
tmp[0] = product[44];
tmp[1] = product[45];
tmp[2] = product[46];
tmp[3] = product[47];
tmp[4] = product[48];
tmp[5] = product[49];
tmp[6] = product[50];
tmp[7] = product[51];
tmp[8] = product[52];
tmp[9] = product[53];
tmp[10] = product[54];
tmp[11] = product[55];
tmp[12] = tmp[13] = tmp[14] = tmp[15] = 0;
tmp[16] = tmp[17] = tmp[18] = tmp[19] = 0;
tmp[20] = tmp[21] = tmp[22] = tmp[23] = 0;
tmp[24] = tmp[25] = tmp[26] = tmp[27] = 0;
carry -= uECC_vli_sub(result, result, tmp, num_words_secp224r1);
if (carry < 0) {
do {
carry +=
uECC_vli_add(result, result, curve_secp224r1.p, num_words_secp224r1);
} while (carry < 0);
} else {
while (carry || uECC_vli_cmp_unsafe(curve_secp224r1.p, result,
num_words_secp224r1) != 1) {
carry -=
uECC_vli_sub(result, result, curve_secp224r1.p, num_words_secp224r1);
}
}
}
#elif uECC_WORD_SIZE == 4
static void vli_mmod_fast_secp224r1(uint32_t *result, uint32_t *product) {
uint32_t tmp[num_words_secp224r1];
int carry;
/* t */
uECC_vli_set(result, product, num_words_secp224r1);
/* s1 */
tmp[0] = tmp[1] = tmp[2] = 0;
tmp[3] = product[7];
tmp[4] = product[8];
tmp[5] = product[9];
tmp[6] = product[10];
carry = uECC_vli_add(result, result, tmp, num_words_secp224r1);
/* s2 */
tmp[3] = product[11];
tmp[4] = product[12];
tmp[5] = product[13];
tmp[6] = 0;
carry += uECC_vli_add(result, result, tmp, num_words_secp224r1);
/* d1 */
tmp[0] = product[7];
tmp[1] = product[8];
tmp[2] = product[9];
tmp[3] = product[10];
tmp[4] = product[11];
tmp[5] = product[12];
tmp[6] = product[13];
carry -= uECC_vli_sub(result, result, tmp, num_words_secp224r1);
/* d2 */
tmp[0] = product[11];
tmp[1] = product[12];
tmp[2] = product[13];
tmp[3] = tmp[4] = tmp[5] = tmp[6] = 0;
carry -= uECC_vli_sub(result, result, tmp, num_words_secp224r1);
if (carry < 0) {
do {
carry +=
uECC_vli_add(result, result, curve_secp224r1.p, num_words_secp224r1);
} while (carry < 0);
} else {
while (carry || uECC_vli_cmp_unsafe(curve_secp224r1.p, result,
num_words_secp224r1) != 1) {
carry -=
uECC_vli_sub(result, result, curve_secp224r1.p, num_words_secp224r1);
}
}
}
#else
static void vli_mmod_fast_secp224r1(uint64_t *result, uint64_t *product) {
uint64_t tmp[num_words_secp224r1];
int carry = 0;
/* t */
uECC_vli_set(result, product, num_words_secp224r1);
result[num_words_secp224r1 - 1] &= 0xffffffff;
/* s1 */
tmp[0] = 0;
tmp[1] = product[3] & 0xffffffff00000000ull;
tmp[2] = product[4];
tmp[3] = product[5] & 0xffffffff;
uECC_vli_add(result, result, tmp, num_words_secp224r1);
/* s2 */
tmp[1] = product[5] & 0xffffffff00000000ull;
tmp[2] = product[6];
tmp[3] = 0;
uECC_vli_add(result, result, tmp, num_words_secp224r1);
/* d1 */
tmp[0] = (product[3] >> 32) | (product[4] << 32);
tmp[1] = (product[4] >> 32) | (product[5] << 32);
tmp[2] = (product[5] >> 32) | (product[6] << 32);
tmp[3] = product[6] >> 32;
carry -= uECC_vli_sub(result, result, tmp, num_words_secp224r1);
/* d2 */
tmp[0] = (product[5] >> 32) | (product[6] << 32);
tmp[1] = product[6] >> 32;
tmp[2] = tmp[3] = 0;
carry -= uECC_vli_sub(result, result, tmp, num_words_secp224r1);
if (carry < 0) {
do {
carry +=
uECC_vli_add(result, result, curve_secp224r1.p, num_words_secp224r1);
} while (carry < 0);
} else {
while (uECC_vli_cmp_unsafe(curve_secp224r1.p, result,
num_words_secp224r1) != 1) {
uECC_vli_sub(result, result, curve_secp224r1.p, num_words_secp224r1);
}
}
}
#endif /* uECC_WORD_SIZE */
#endif /* (uECC_OPTIMIZATION_LEVEL > 0) */
#endif /* uECC_SUPPORTS_secp224r1 */
#if uECC_SUPPORTS_secp256r1
#if (uECC_OPTIMIZATION_LEVEL > 0)
static void vli_mmod_fast_secp256r1(uECC_word_t *result, uECC_word_t *product);
#endif
static const struct uECC_Curve_t curve_secp256r1 = {
num_words_secp256r1,
num_bytes_secp256r1,
256, /* num_n_bits */
{BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, 00, 00, 00, 00),
BYTES_TO_WORDS_8(00, 00, 00, 00, 00, 00, 00, 00),
BYTES_TO_WORDS_8(01, 00, 00, 00, FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(51, 25, 63, FC, C2, CA, B9, F3),
BYTES_TO_WORDS_8(84, 9E, 17, A7, AD, FA, E6, BC),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_8(00, 00, 00, 00, FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(96, C2, 98, D8, 45, 39, A1, F4),
BYTES_TO_WORDS_8(A0, 33, EB, 2D, 81, 7D, 03, 77),
BYTES_TO_WORDS_8(F2, 40, A4, 63, E5, E6, BC, F8),
BYTES_TO_WORDS_8(47, 42, 2C, E1, F2, D1, 17, 6B),
BYTES_TO_WORDS_8(F5, 51, BF, 37, 68, 40, B6, CB),
BYTES_TO_WORDS_8(CE, 5E, 31, 6B, 57, 33, CE, 2B),
BYTES_TO_WORDS_8(16, 9E, 0F, 7C, 4A, EB, E7, 8E),
BYTES_TO_WORDS_8(9B, 7F, 1A, FE, E2, 42, E3, 4F)},
{BYTES_TO_WORDS_8(4B, 60, D2, 27, 3E, 3C, CE, 3B),
BYTES_TO_WORDS_8(F6, B0, 53, CC, B0, 06, 1D, 65),
BYTES_TO_WORDS_8(BC, 86, 98, 76, 55, BD, EB, B3),
BYTES_TO_WORDS_8(E7, 93, 3A, AA, D8, 35, C6, 5A)},
&double_jacobian_default,
#if uECC_SUPPORT_COMPRESSED_POINT
&mod_sqrt_default,
#endif
&x_side_default,
#if (uECC_OPTIMIZATION_LEVEL > 0)
&vli_mmod_fast_secp256r1
#endif
};
uECC_Curve uECC_secp256r1(void) {
return &curve_secp256r1;
}
#if (uECC_OPTIMIZATION_LEVEL > 0 && !asm_mmod_fast_secp256r1)
/* Computes result = product % curve_p
from http://www.nsa.gov/ia/_files/nist-routines.pdf */
#if uECC_WORD_SIZE == 1
static void vli_mmod_fast_secp256r1(uint8_t *result, uint8_t *product) {
uint8_t tmp[num_words_secp256r1];
int8_t carry;
/* t */
uECC_vli_set(result, product, num_words_secp256r1);
/* s1 */
tmp[0] = tmp[1] = tmp[2] = tmp[3] = 0;
tmp[4] = tmp[5] = tmp[6] = tmp[7] = 0;
tmp[8] = tmp[9] = tmp[10] = tmp[11] = 0;
tmp[12] = product[44];
tmp[13] = product[45];
tmp[14] = product[46];
tmp[15] = product[47];
tmp[16] = product[48];
tmp[17] = product[49];
tmp[18] = product[50];
tmp[19] = product[51];
tmp[20] = product[52];
tmp[21] = product[53];
tmp[22] = product[54];
tmp[23] = product[55];
tmp[24] = product[56];
tmp[25] = product[57];
tmp[26] = product[58];
tmp[27] = product[59];
tmp[28] = product[60];
tmp[29] = product[61];
tmp[30] = product[62];
tmp[31] = product[63];
carry = uECC_vli_add(tmp, tmp, tmp, num_words_secp256r1);
carry += uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s2 */
tmp[12] = product[48];
tmp[13] = product[49];
tmp[14] = product[50];
tmp[15] = product[51];
tmp[16] = product[52];
tmp[17] = product[53];
tmp[18] = product[54];
tmp[19] = product[55];
tmp[20] = product[56];
tmp[21] = product[57];
tmp[22] = product[58];
tmp[23] = product[59];
tmp[24] = product[60];
tmp[25] = product[61];
tmp[26] = product[62];
tmp[27] = product[63];
tmp[28] = tmp[29] = tmp[30] = tmp[31] = 0;
carry += uECC_vli_add(tmp, tmp, tmp, num_words_secp256r1);
carry += uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s3 */
tmp[0] = product[32];
tmp[1] = product[33];
tmp[2] = product[34];
tmp[3] = product[35];
tmp[4] = product[36];
tmp[5] = product[37];
tmp[6] = product[38];
tmp[7] = product[39];
tmp[8] = product[40];
tmp[9] = product[41];
tmp[10] = product[42];
tmp[11] = product[43];
tmp[12] = tmp[13] = tmp[14] = tmp[15] = 0;
tmp[16] = tmp[17] = tmp[18] = tmp[19] = 0;
tmp[20] = tmp[21] = tmp[22] = tmp[23] = 0;
tmp[24] = product[56];
tmp[25] = product[57];
tmp[26] = product[58];
tmp[27] = product[59];
tmp[28] = product[60];
tmp[29] = product[61];
tmp[30] = product[62];
tmp[31] = product[63];
carry += uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s4 */
tmp[0] = product[36];
tmp[1] = product[37];
tmp[2] = product[38];
tmp[3] = product[39];
tmp[4] = product[40];
tmp[5] = product[41];
tmp[6] = product[42];
tmp[7] = product[43];
tmp[8] = product[44];
tmp[9] = product[45];
tmp[10] = product[46];
tmp[11] = product[47];
tmp[12] = product[52];
tmp[13] = product[53];
tmp[14] = product[54];
tmp[15] = product[55];
tmp[16] = product[56];
tmp[17] = product[57];
tmp[18] = product[58];
tmp[19] = product[59];
tmp[20] = product[60];
tmp[21] = product[61];
tmp[22] = product[62];
tmp[23] = product[63];
tmp[24] = product[52];
tmp[25] = product[53];
tmp[26] = product[54];
tmp[27] = product[55];
tmp[28] = product[32];
tmp[29] = product[33];
tmp[30] = product[34];
tmp[31] = product[35];
carry += uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* d1 */
tmp[0] = product[44];
tmp[1] = product[45];
tmp[2] = product[46];
tmp[3] = product[47];
tmp[4] = product[48];
tmp[5] = product[49];
tmp[6] = product[50];
tmp[7] = product[51];
tmp[8] = product[52];
tmp[9] = product[53];
tmp[10] = product[54];
tmp[11] = product[55];
tmp[12] = tmp[13] = tmp[14] = tmp[15] = 0;
tmp[16] = tmp[17] = tmp[18] = tmp[19] = 0;
tmp[20] = tmp[21] = tmp[22] = tmp[23] = 0;
tmp[24] = product[32];
tmp[25] = product[33];
tmp[26] = product[34];
tmp[27] = product[35];
tmp[28] = product[40];
tmp[29] = product[41];
tmp[30] = product[42];
tmp[31] = product[43];
carry -= uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d2 */
tmp[0] = product[48];
tmp[1] = product[49];
tmp[2] = product[50];
tmp[3] = product[51];
tmp[4] = product[52];
tmp[5] = product[53];
tmp[6] = product[54];
tmp[7] = product[55];
tmp[8] = product[56];
tmp[9] = product[57];
tmp[10] = product[58];
tmp[11] = product[59];
tmp[12] = product[60];
tmp[13] = product[61];
tmp[14] = product[62];
tmp[15] = product[63];
tmp[16] = tmp[17] = tmp[18] = tmp[19] = 0;
tmp[20] = tmp[21] = tmp[22] = tmp[23] = 0;
tmp[24] = product[36];
tmp[25] = product[37];
tmp[26] = product[38];
tmp[27] = product[39];
tmp[28] = product[44];
tmp[29] = product[45];
tmp[30] = product[46];
tmp[31] = product[47];
carry -= uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d3 */
tmp[0] = product[52];
tmp[1] = product[53];
tmp[2] = product[54];
tmp[3] = product[55];
tmp[4] = product[56];
tmp[5] = product[57];
tmp[6] = product[58];
tmp[7] = product[59];
tmp[8] = product[60];
tmp[9] = product[61];
tmp[10] = product[62];
tmp[11] = product[63];
tmp[12] = product[32];
tmp[13] = product[33];
tmp[14] = product[34];
tmp[15] = product[35];
tmp[16] = product[36];
tmp[17] = product[37];
tmp[18] = product[38];
tmp[19] = product[39];
tmp[20] = product[40];
tmp[21] = product[41];
tmp[22] = product[42];
tmp[23] = product[43];
tmp[24] = tmp[25] = tmp[26] = tmp[27] = 0;
tmp[28] = product[48];
tmp[29] = product[49];
tmp[30] = product[50];
tmp[31] = product[51];
carry -= uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d4 */
tmp[0] = product[56];
tmp[1] = product[57];
tmp[2] = product[58];
tmp[3] = product[59];
tmp[4] = product[60];
tmp[5] = product[61];
tmp[6] = product[62];
tmp[7] = product[63];
tmp[8] = tmp[9] = tmp[10] = tmp[11] = 0;
tmp[12] = product[36];
tmp[13] = product[37];
tmp[14] = product[38];
tmp[15] = product[39];
tmp[16] = product[40];
tmp[17] = product[41];
tmp[18] = product[42];
tmp[19] = product[43];
tmp[20] = product[44];
tmp[21] = product[45];
tmp[22] = product[46];
tmp[23] = product[47];
tmp[24] = tmp[25] = tmp[26] = tmp[27] = 0;
tmp[28] = product[52];
tmp[29] = product[53];
tmp[30] = product[54];
tmp[31] = product[55];
carry -= uECC_vli_sub(result, result, tmp, num_words_secp256r1);
if (carry < 0) {
do {
carry +=
uECC_vli_add(result, result, curve_secp256r1.p, num_words_secp256r1);
} while (carry < 0);
} else {
while (carry || uECC_vli_cmp_unsafe(curve_secp256r1.p, result,
num_words_secp256r1) != 1) {
carry -=
uECC_vli_sub(result, result, curve_secp256r1.p, num_words_secp256r1);
}
}
}
#elif uECC_WORD_SIZE == 4
static void vli_mmod_fast_secp256r1(uint32_t *result, uint32_t *product) {
uint32_t tmp[num_words_secp256r1];
int carry;
/* t */
uECC_vli_set(result, product, num_words_secp256r1);
/* s1 */
tmp[0] = tmp[1] = tmp[2] = 0;
tmp[3] = product[11];
tmp[4] = product[12];
tmp[5] = product[13];
tmp[6] = product[14];
tmp[7] = product[15];
carry = (int) uECC_vli_add(tmp, tmp, tmp, num_words_secp256r1);
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s2 */
tmp[3] = product[12];
tmp[4] = product[13];
tmp[5] = product[14];
tmp[6] = product[15];
tmp[7] = 0;
carry += (int) uECC_vli_add(tmp, tmp, tmp, num_words_secp256r1);
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s3 */
tmp[0] = product[8];
tmp[1] = product[9];
tmp[2] = product[10];
tmp[3] = tmp[4] = tmp[5] = 0;
tmp[6] = product[14];
tmp[7] = product[15];
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s4 */
tmp[0] = product[9];
tmp[1] = product[10];
tmp[2] = product[11];
tmp[3] = product[13];
tmp[4] = product[14];
tmp[5] = product[15];
tmp[6] = product[13];
tmp[7] = product[8];
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* d1 */
tmp[0] = product[11];
tmp[1] = product[12];
tmp[2] = product[13];
tmp[3] = tmp[4] = tmp[5] = 0;
tmp[6] = product[8];
tmp[7] = product[10];
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d2 */
tmp[0] = product[12];
tmp[1] = product[13];
tmp[2] = product[14];
tmp[3] = product[15];
tmp[4] = tmp[5] = 0;
tmp[6] = product[9];
tmp[7] = product[11];
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d3 */
tmp[0] = product[13];
tmp[1] = product[14];
tmp[2] = product[15];
tmp[3] = product[8];
tmp[4] = product[9];
tmp[5] = product[10];
tmp[6] = 0;
tmp[7] = product[12];
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d4 */
tmp[0] = product[14];
tmp[1] = product[15];
tmp[2] = 0;
tmp[3] = product[9];
tmp[4] = product[10];
tmp[5] = product[11];
tmp[6] = 0;
tmp[7] = product[13];
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
if (carry < 0) {
do {
carry +=
(int) uECC_vli_add(result, result, curve_secp256r1.p, num_words_secp256r1);
} while (carry < 0);
} else {
while (carry || uECC_vli_cmp_unsafe(curve_secp256r1.p, result,
num_words_secp256r1) != 1) {
carry -=
(int) uECC_vli_sub(result, result, curve_secp256r1.p, num_words_secp256r1);
}
}
}
#else
static void vli_mmod_fast_secp256r1(uint64_t *result, uint64_t *product) {
uint64_t tmp[num_words_secp256r1];
int carry;
/* t */
uECC_vli_set(result, product, num_words_secp256r1);
/* s1 */
tmp[0] = 0;
tmp[1] = product[5] & 0xffffffff00000000U;
tmp[2] = product[6];
tmp[3] = product[7];
carry = (int) uECC_vli_add(tmp, tmp, tmp, num_words_secp256r1);
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s2 */
tmp[1] = product[6] << 32;
tmp[2] = (product[6] >> 32) | (product[7] << 32);
tmp[3] = product[7] >> 32;
carry += (int) uECC_vli_add(tmp, tmp, tmp, num_words_secp256r1);
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s3 */
tmp[0] = product[4];
tmp[1] = product[5] & 0xffffffff;
tmp[2] = 0;
tmp[3] = product[7];
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* s4 */
tmp[0] = (product[4] >> 32) | (product[5] << 32);
tmp[1] = (product[5] >> 32) | (product[6] & 0xffffffff00000000U);
tmp[2] = product[7];
tmp[3] = (product[6] >> 32) | (product[4] << 32);
carry += (int) uECC_vli_add(result, result, tmp, num_words_secp256r1);
/* d1 */
tmp[0] = (product[5] >> 32) | (product[6] << 32);
tmp[1] = (product[6] >> 32);
tmp[2] = 0;
tmp[3] = (product[4] & 0xffffffff) | (product[5] << 32);
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d2 */
tmp[0] = product[6];
tmp[1] = product[7];
tmp[2] = 0;
tmp[3] = (product[4] >> 32) | (product[5] & 0xffffffff00000000);
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d3 */
tmp[0] = (product[6] >> 32) | (product[7] << 32);
tmp[1] = (product[7] >> 32) | (product[4] << 32);
tmp[2] = (product[4] >> 32) | (product[5] << 32);
tmp[3] = (product[6] << 32);
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
/* d4 */
tmp[0] = product[7];
tmp[1] = product[4] & 0xffffffff00000000U;
tmp[2] = product[5];
tmp[3] = product[6] & 0xffffffff00000000U;
carry -= (int) uECC_vli_sub(result, result, tmp, num_words_secp256r1);
if (carry < 0) {
do {
carry +=
(int) uECC_vli_add(result, result, curve_secp256r1.p, num_words_secp256r1);
} while (carry < 0);
} else {
while (carry || uECC_vli_cmp_unsafe(curve_secp256r1.p, result,
num_words_secp256r1) != 1) {
carry -=
(int) uECC_vli_sub(result, result, curve_secp256r1.p, num_words_secp256r1);
}
}
}
#endif /* uECC_WORD_SIZE */
#endif /* (uECC_OPTIMIZATION_LEVEL > 0 && !asm_mmod_fast_secp256r1) */
#endif /* uECC_SUPPORTS_secp256r1 */
#if uECC_SUPPORTS_secp256k1
static void double_jacobian_secp256k1(uECC_word_t *X1, uECC_word_t *Y1,
uECC_word_t *Z1, uECC_Curve curve);
static void x_side_secp256k1(uECC_word_t *result, const uECC_word_t *x,
uECC_Curve curve);
#if (uECC_OPTIMIZATION_LEVEL > 0)
static void vli_mmod_fast_secp256k1(uECC_word_t *result, uECC_word_t *product);
#endif
static const struct uECC_Curve_t curve_secp256k1 = {
num_words_secp256k1,
num_bytes_secp256k1,
256, /* num_n_bits */
{BYTES_TO_WORDS_8(2F, FC, FF, FF, FE, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(41, 41, 36, D0, 8C, 5E, D2, BF),
BYTES_TO_WORDS_8(3B, A0, 48, AF, E6, DC, AE, BA),
BYTES_TO_WORDS_8(FE, FF, FF, FF, FF, FF, FF, FF),
BYTES_TO_WORDS_8(FF, FF, FF, FF, FF, FF, FF, FF)},
{BYTES_TO_WORDS_8(98, 17, F8, 16, 5B, 81, F2, 59),
BYTES_TO_WORDS_8(D9, 28, CE, 2D, DB, FC, 9B, 02),
BYTES_TO_WORDS_8(07, 0B, 87, CE, 95, 62, A0, 55),
BYTES_TO_WORDS_8(AC, BB, DC, F9, 7E, 66, BE, 79),
BYTES_TO_WORDS_8(B8, D4, 10, FB, 8F, D0, 47, 9C),
BYTES_TO_WORDS_8(19, 54, 85, A6, 48, B4, 17, FD),
BYTES_TO_WORDS_8(A8, 08, 11, 0E, FC, FB, A4, 5D),
BYTES_TO_WORDS_8(65, C4, A3, 26, 77, DA, 3A, 48)},
{BYTES_TO_WORDS_8(07, 00, 00, 00, 00, 00, 00, 00),
BYTES_TO_WORDS_8(00, 00, 00, 00, 00, 00, 00, 00),
BYTES_TO_WORDS_8(00, 00, 00, 00, 00, 00, 00, 00),
BYTES_TO_WORDS_8(00, 00, 00, 00, 00, 00, 00, 00)},
&double_jacobian_secp256k1,
#if uECC_SUPPORT_COMPRESSED_POINT
&mod_sqrt_default,
#endif
&x_side_secp256k1,
#if (uECC_OPTIMIZATION_LEVEL > 0)
&vli_mmod_fast_secp256k1
#endif
};
uECC_Curve uECC_secp256k1(void) {
return &curve_secp256k1;
}
/* Double in place */
static void double_jacobian_secp256k1(uECC_word_t *X1, uECC_word_t *Y1,
uECC_word_t *Z1, uECC_Curve curve) {
/* t1 = X, t2 = Y, t3 = Z */
uECC_word_t t4[num_words_secp256k1];
uECC_word_t t5[num_words_secp256k1];
if (uECC_vli_isZero(Z1, num_words_secp256k1)) {
return;
}
uECC_vli_modSquare_fast(t5, Y1, curve); /* t5 = y1^2 */
uECC_vli_modMult_fast(t4, X1, t5, curve); /* t4 = x1*y1^2 = A */
uECC_vli_modSquare_fast(X1, X1, curve); /* t1 = x1^2 */
uECC_vli_modSquare_fast(t5, t5, curve); /* t5 = y1^4 */
uECC_vli_modMult_fast(Z1, Y1, Z1, curve); /* t3 = y1*z1 = z3 */
uECC_vli_modAdd(Y1, X1, X1, curve->p, num_words_secp256k1); /* t2 = 2*x1^2 */
uECC_vli_modAdd(Y1, Y1, X1, curve->p, num_words_secp256k1); /* t2 = 3*x1^2 */
if (uECC_vli_testBit(Y1, 0)) {
uECC_word_t carry = uECC_vli_add(Y1, Y1, curve->p, num_words_secp256k1);
uECC_vli_rshift1(Y1, num_words_secp256k1);
Y1[num_words_secp256k1 - 1] |= carry << (uECC_WORD_BITS - 1);
} else {
uECC_vli_rshift1(Y1, num_words_secp256k1);
}
/* t2 = 3/2*(x1^2) = B */
uECC_vli_modSquare_fast(X1, Y1, curve); /* t1 = B^2 */
uECC_vli_modSub(X1, X1, t4, curve->p, num_words_secp256k1); /* t1 = B^2 - A */
uECC_vli_modSub(X1, X1, t4, curve->p,
num_words_secp256k1); /* t1 = B^2 - 2A = x3 */
uECC_vli_modSub(t4, t4, X1, curve->p, num_words_secp256k1); /* t4 = A - x3 */
uECC_vli_modMult_fast(Y1, Y1, t4, curve); /* t2 = B * (A - x3) */
uECC_vli_modSub(Y1, Y1, t5, curve->p,
num_words_secp256k1); /* t2 = B * (A - x3) - y1^4 = y3 */
}
/* Computes result = x^3 + b. result must not overlap x. */
static void x_side_secp256k1(uECC_word_t *result, const uECC_word_t *x,
uECC_Curve curve) {
uECC_vli_modSquare_fast(result, x, curve); /* r = x^2 */
uECC_vli_modMult_fast(result, result, x, curve); /* r = x^3 */
uECC_vli_modAdd(result, result, curve->b, curve->p,
num_words_secp256k1); /* r = x^3 + b */
}
#if (uECC_OPTIMIZATION_LEVEL > 0 && !asm_mmod_fast_secp256k1)
static void omega_mult_secp256k1(uECC_word_t *result, const uECC_word_t *right);
static void vli_mmod_fast_secp256k1(uECC_word_t *result, uECC_word_t *product) {
uECC_word_t tmp[2 * num_words_secp256k1];
uECC_word_t carry;
uECC_vli_clear(tmp, num_words_secp256k1);
uECC_vli_clear(tmp + num_words_secp256k1, num_words_secp256k1);
omega_mult_secp256k1(tmp,
product + num_words_secp256k1); /* (Rq, q) = q * c */
carry = uECC_vli_add(result, product, tmp,
num_words_secp256k1); /* (C, r) = r + q */
uECC_vli_clear(product, num_words_secp256k1);
omega_mult_secp256k1(product, tmp + num_words_secp256k1); /* Rq*c */
carry += uECC_vli_add(result, result, product,
num_words_secp256k1); /* (C1, r) = r + Rq*c */
while (carry > 0) {
--carry;
uECC_vli_sub(result, result, curve_secp256k1.p, num_words_secp256k1);
}
if (uECC_vli_cmp_unsafe(result, curve_secp256k1.p, num_words_secp256k1) > 0) {
uECC_vli_sub(result, result, curve_secp256k1.p, num_words_secp256k1);
}
}
#if uECC_WORD_SIZE == 1
static void omega_mult_secp256k1(uint8_t *result, const uint8_t *right) {
/* Multiply by (2^32 + 2^9 + 2^8 + 2^7 + 2^6 + 2^4 + 1). */
uECC_word_t r0 = 0;
uECC_word_t r1 = 0;
uECC_word_t r2 = 0;
wordcount_t k;
/* Multiply by (2^9 + 2^8 + 2^7 + 2^6 + 2^4 + 1). */
muladd(0xD1, right[0], &r0, &r1, &r2);
result[0] = r0;
r0 = r1;
r1 = r2;
/* r2 is still 0 */
for (k = 1; k < num_words_secp256k1; ++k) {
muladd(0x03, right[k - 1], &r0, &r1, &r2);
muladd(0xD1, right[k], &r0, &r1, &r2);
result[k] = r0;
r0 = r1;
r1 = r2;
r2 = 0;
}
muladd(0x03, right[num_words_secp256k1 - 1], &r0, &r1, &r2);
result[num_words_secp256k1] = r0;
result[num_words_secp256k1 + 1] = r1;
/* add the 2^32 multiple */
result[4 + num_words_secp256k1] =
uECC_vli_add(result + 4, result + 4, right, num_words_secp256k1);
}
#elif uECC_WORD_SIZE == 4
static void omega_mult_secp256k1(uint32_t *result, const uint32_t *right) {
/* Multiply by (2^9 + 2^8 + 2^7 + 2^6 + 2^4 + 1). */
uint32_t carry = 0;
wordcount_t k;
for (k = 0; k < num_words_secp256k1; ++k) {
uint64_t p = (uint64_t) 0x3D1 * right[k] + carry;
result[k] = (uint32_t) p;
carry = p >> 32;
}
result[num_words_secp256k1] = carry;
/* add the 2^32 multiple */
result[1 + num_words_secp256k1] =
uECC_vli_add(result + 1, result + 1, right, num_words_secp256k1);
}
#else
static void omega_mult_secp256k1(uint64_t *result, const uint64_t *right) {
uECC_word_t r0 = 0;
uECC_word_t r1 = 0;
uECC_word_t r2 = 0;
wordcount_t k;
/* Multiply by (2^32 + 2^9 + 2^8 + 2^7 + 2^6 + 2^4 + 1). */
for (k = 0; k < num_words_secp256k1; ++k) {
muladd(0x1000003D1ull, right[k], &r0, &r1, &r2);
result[k] = r0;
r0 = r1;
r1 = r2;
r2 = 0;
}
result[num_words_secp256k1] = r0;
}
#endif /* uECC_WORD_SIZE */
#endif /* (uECC_OPTIMIZATION_LEVEL > 0 && && !asm_mmod_fast_secp256k1) */
#endif /* uECC_SUPPORTS_secp256k1 */
#endif /* _UECC_CURVE_SPECIFIC_H_ */
/* Returns 1 if 'point' is the point at infinity, 0 otherwise. */
#define EccPoint_isZero(point, curve) \
uECC_vli_isZero((point), (wordcount_t) ((curve)->num_words * 2))
/* Point multiplication algorithm using Montgomery's ladder with co-Z
coordinates. From http://eprint.iacr.org/2011/338.pdf
*/
/* Modify (x1, y1) => (x1 * z^2, y1 * z^3) */
static void apply_z(uECC_word_t *X1, uECC_word_t *Y1,
const uECC_word_t *const Z, uECC_Curve curve) {
uECC_word_t t1[uECC_MAX_WORDS];
uECC_vli_modSquare_fast(t1, Z, curve); /* z^2 */
uECC_vli_modMult_fast(X1, X1, t1, curve); /* x1 * z^2 */
uECC_vli_modMult_fast(t1, t1, Z, curve); /* z^3 */
uECC_vli_modMult_fast(Y1, Y1, t1, curve); /* y1 * z^3 */
}
/* P = (x1, y1) => 2P, (x2, y2) => P' */
static void XYcZ_initial_double(uECC_word_t *X1, uECC_word_t *Y1,
uECC_word_t *X2, uECC_word_t *Y2,
const uECC_word_t *const initial_Z,
uECC_Curve curve) {
uECC_word_t z[uECC_MAX_WORDS];
wordcount_t num_words = curve->num_words;
if (initial_Z) {
uECC_vli_set(z, initial_Z, num_words);
} else {
uECC_vli_clear(z, num_words);
z[0] = 1;
}
uECC_vli_set(X2, X1, num_words);
uECC_vli_set(Y2, Y1, num_words);
apply_z(X1, Y1, z, curve);
curve->double_jacobian(X1, Y1, z, curve);
apply_z(X2, Y2, z, curve);
}
/* Input P = (x1, y1, Z), Q = (x2, y2, Z)
Output P' = (x1', y1', Z3), P + Q = (x3, y3, Z3)
or P => P', Q => P + Q
*/
static void XYcZ_add(uECC_word_t *X1, uECC_word_t *Y1, uECC_word_t *X2,
uECC_word_t *Y2, uECC_Curve curve) {
/* t1 = X1, t2 = Y1, t3 = X2, t4 = Y2 */
uECC_word_t t5[uECC_MAX_WORDS] = {0};
wordcount_t num_words = curve->num_words;
uECC_vli_modSub(t5, X2, X1, curve->p, num_words); /* t5 = x2 - x1 */
uECC_vli_modSquare_fast(t5, t5, curve); /* t5 = (x2 - x1)^2 = A */
uECC_vli_modMult_fast(X1, X1, t5, curve); /* t1 = x1*A = B */
uECC_vli_modMult_fast(X2, X2, t5, curve); /* t3 = x2*A = C */
uECC_vli_modSub(Y2, Y2, Y1, curve->p, num_words); /* t4 = y2 - y1 */
uECC_vli_modSquare_fast(t5, Y2, curve); /* t5 = (y2 - y1)^2 = D */
uECC_vli_modSub(t5, t5, X1, curve->p, num_words); /* t5 = D - B */
uECC_vli_modSub(t5, t5, X2, curve->p, num_words); /* t5 = D - B - C = x3 */
uECC_vli_modSub(X2, X2, X1, curve->p, num_words); /* t3 = C - B */
uECC_vli_modMult_fast(Y1, Y1, X2, curve); /* t2 = y1*(C - B) */
uECC_vli_modSub(X2, X1, t5, curve->p, num_words); /* t3 = B - x3 */
uECC_vli_modMult_fast(Y2, Y2, X2, curve); /* t4 = (y2 - y1)*(B - x3) */
uECC_vli_modSub(Y2, Y2, Y1, curve->p, num_words); /* t4 = y3 */
uECC_vli_set(X2, t5, num_words);
}
/* Input P = (x1, y1, Z), Q = (x2, y2, Z)
Output P + Q = (x3, y3, Z3), P - Q = (x3', y3', Z3)
or P => P - Q, Q => P + Q
*/
static void XYcZ_addC(uECC_word_t *X1, uECC_word_t *Y1, uECC_word_t *X2,
uECC_word_t *Y2, uECC_Curve curve) {
/* t1 = X1, t2 = Y1, t3 = X2, t4 = Y2 */
uECC_word_t t5[uECC_MAX_WORDS] = {0};
uECC_word_t t6[uECC_MAX_WORDS];
uECC_word_t t7[uECC_MAX_WORDS];
wordcount_t num_words = curve->num_words;
uECC_vli_modSub(t5, X2, X1, curve->p, num_words); /* t5 = x2 - x1 */
uECC_vli_modSquare_fast(t5, t5, curve); /* t5 = (x2 - x1)^2 = A */
uECC_vli_modMult_fast(X1, X1, t5, curve); /* t1 = x1*A = B */
uECC_vli_modMult_fast(X2, X2, t5, curve); /* t3 = x2*A = C */
uECC_vli_modAdd(t5, Y2, Y1, curve->p, num_words); /* t5 = y2 + y1 */
uECC_vli_modSub(Y2, Y2, Y1, curve->p, num_words); /* t4 = y2 - y1 */
uECC_vli_modSub(t6, X2, X1, curve->p, num_words); /* t6 = C - B */
uECC_vli_modMult_fast(Y1, Y1, t6, curve); /* t2 = y1 * (C - B) = E */
uECC_vli_modAdd(t6, X1, X2, curve->p, num_words); /* t6 = B + C */
uECC_vli_modSquare_fast(X2, Y2, curve); /* t3 = (y2 - y1)^2 = D */
uECC_vli_modSub(X2, X2, t6, curve->p, num_words); /* t3 = D - (B + C) = x3 */
uECC_vli_modSub(t7, X1, X2, curve->p, num_words); /* t7 = B - x3 */
uECC_vli_modMult_fast(Y2, Y2, t7, curve); /* t4 = (y2 - y1)*(B - x3) */
uECC_vli_modSub(Y2, Y2, Y1, curve->p,
num_words); /* t4 = (y2 - y1)*(B - x3) - E = y3 */
uECC_vli_modSquare_fast(t7, t5, curve); /* t7 = (y2 + y1)^2 = F */
uECC_vli_modSub(t7, t7, t6, curve->p, num_words); /* t7 = F - (B + C) = x3' */
uECC_vli_modSub(t6, t7, X1, curve->p, num_words); /* t6 = x3' - B */
uECC_vli_modMult_fast(t6, t6, t5, curve); /* t6 = (y2+y1)*(x3' - B) */
uECC_vli_modSub(Y1, t6, Y1, curve->p,
num_words); /* t2 = (y2+y1)*(x3' - B) - E = y3' */
uECC_vli_set(X1, t7, num_words);
}
/* result may overlap point. */
static void EccPoint_mult(uECC_word_t *result, const uECC_word_t *point,
const uECC_word_t *scalar,
const uECC_word_t *initial_Z, bitcount_t num_bits,
uECC_Curve curve) {
/* R0 and R1 */
uECC_word_t Rx[2][uECC_MAX_WORDS];
uECC_word_t Ry[2][uECC_MAX_WORDS];
uECC_word_t z[uECC_MAX_WORDS];
bitcount_t i;
uECC_word_t nb;
wordcount_t num_words = curve->num_words;
uECC_vli_set(Rx[1], point, num_words);
uECC_vli_set(Ry[1], point + num_words, num_words);
XYcZ_initial_double(Rx[1], Ry[1], Rx[0], Ry[0], initial_Z, curve);
for (i = num_bits - 2; i > 0; --i) {
nb = !uECC_vli_testBit(scalar, i);
XYcZ_addC(Rx[1 - nb], Ry[1 - nb], Rx[nb], Ry[nb], curve);
XYcZ_add(Rx[nb], Ry[nb], Rx[1 - nb], Ry[1 - nb], curve);
}
nb = !uECC_vli_testBit(scalar, 0);
XYcZ_addC(Rx[1 - nb], Ry[1 - nb], Rx[nb], Ry[nb], curve);
/* Find final 1/Z value. */
uECC_vli_modSub(z, Rx[1], Rx[0], curve->p, num_words); /* X1 - X0 */
uECC_vli_modMult_fast(z, z, Ry[1 - nb], curve); /* Yb * (X1 - X0) */
uECC_vli_modMult_fast(z, z, point, curve); /* xP * Yb * (X1 - X0) */
uECC_vli_modInv(z, z, curve->p, num_words); /* 1 / (xP * Yb * (X1 - X0)) */
/* yP / (xP * Yb * (X1 - X0)) */
uECC_vli_modMult_fast(z, z, point + num_words, curve);
uECC_vli_modMult_fast(z, z, Rx[1 - nb],
curve); /* Xb * yP / (xP * Yb * (X1 - X0)) */
/* End 1/Z calculation */
XYcZ_add(Rx[nb], Ry[nb], Rx[1 - nb], Ry[1 - nb], curve);
apply_z(Rx[0], Ry[0], z, curve);
uECC_vli_set(result, Rx[0], num_words);
uECC_vli_set(result + num_words, Ry[0], num_words);
}
static uECC_word_t regularize_k(const uECC_word_t *const k, uECC_word_t *k0,
uECC_word_t *k1, uECC_Curve curve) {
wordcount_t num_n_words = BITS_TO_WORDS(curve->num_n_bits);
bitcount_t num_n_bits = curve->num_n_bits;
uECC_word_t carry =
uECC_vli_add(k0, k, curve->n, num_n_words) ||
(num_n_bits < ((bitcount_t) num_n_words * uECC_WORD_SIZE * 8) &&
uECC_vli_testBit(k0, num_n_bits));
uECC_vli_add(k1, k0, curve->n, num_n_words);
return carry;
}
/* Generates a random integer in the range 0 < random < top.
Both random and top have num_words words. */
uECC_VLI_API int uECC_generate_random_int(uECC_word_t *random,
const uECC_word_t *top,
wordcount_t num_words) {
uECC_word_t mask = (uECC_word_t) -1;
uECC_word_t tries;
bitcount_t num_bits = uECC_vli_numBits(top, num_words);
if (!g_rng_function) {
return 0;
}
for (tries = 0; tries < uECC_RNG_MAX_TRIES; ++tries) {
if (!g_rng_function((uint8_t *) random,
(unsigned int) (num_words * uECC_WORD_SIZE))) {
return 0;
}
random[num_words - 1] &=
mask >> ((bitcount_t) (num_words * uECC_WORD_SIZE * 8 - num_bits));
if (!uECC_vli_isZero(random, num_words) &&
uECC_vli_cmp(top, random, num_words) == 1) {
return 1;
}
}
return 0;
}
static uECC_word_t EccPoint_compute_public_key(uECC_word_t *result,
uECC_word_t *private_key,
uECC_Curve curve) {
uECC_word_t tmp1[uECC_MAX_WORDS];
uECC_word_t tmp2[uECC_MAX_WORDS];
uECC_word_t *p2[2] = {tmp1, tmp2};
uECC_word_t *initial_Z = 0;
uECC_word_t carry;
/* Regularize the bitcount for the private key so that attackers cannot use a
side channel attack to learn the number of leading zeros. */
carry = regularize_k(private_key, tmp1, tmp2, curve);
/* If an RNG function was specified, try to get a random initial Z value to
improve protection against side-channel attacks. */
if (g_rng_function) {
if (!uECC_generate_random_int(p2[carry], curve->p, curve->num_words)) {
return 0;
}
initial_Z = p2[carry];
}
EccPoint_mult(result, curve->G, p2[!carry], initial_Z,
(bitcount_t) (curve->num_n_bits + 1), curve);
if (EccPoint_isZero(result, curve)) {
return 0;
}
return 1;
}
#if uECC_WORD_SIZE == 1
uECC_VLI_API void uECC_vli_nativeToBytes(uint8_t *bytes, int num_bytes,
const uint8_t *native) {
wordcount_t i;
for (i = 0; i < num_bytes; ++i) {
bytes[i] = native[(num_bytes - 1) - i];
}
}
uECC_VLI_API void uECC_vli_bytesToNative(uint8_t *native, const uint8_t *bytes,
int num_bytes) {
uECC_vli_nativeToBytes(native, num_bytes, bytes);
}
#else
uECC_VLI_API void uECC_vli_nativeToBytes(uint8_t *bytes, int num_bytes,
const uECC_word_t *native) {
int i;
for (i = 0; i < num_bytes; ++i) {
unsigned b = (unsigned) (num_bytes - 1 - i);
bytes[i] =
(uint8_t) (native[b / uECC_WORD_SIZE] >> (8 * (b % uECC_WORD_SIZE)));
}
}
uECC_VLI_API void uECC_vli_bytesToNative(uECC_word_t *native,
const uint8_t *bytes, int num_bytes) {
int i;
uECC_vli_clear(native, (wordcount_t) ((num_bytes + (uECC_WORD_SIZE - 1)) /
uECC_WORD_SIZE));
for (i = 0; i < num_bytes; ++i) {
unsigned b = (unsigned) (num_bytes - 1 - i);
native[b / uECC_WORD_SIZE] |= (uECC_word_t) bytes[i]
<< (8 * (b % uECC_WORD_SIZE));
}
}
#endif /* uECC_WORD_SIZE */
int uECC_make_key(uint8_t *public_key, uint8_t *private_key, uECC_Curve curve) {
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
uECC_word_t *_private = (uECC_word_t *) private_key;
uECC_word_t *_public = (uECC_word_t *) public_key;
#else
uECC_word_t _private[uECC_MAX_WORDS];
uECC_word_t _public[uECC_MAX_WORDS * 2];
#endif
uECC_word_t tries;
for (tries = 0; tries < uECC_RNG_MAX_TRIES; ++tries) {
if (!uECC_generate_random_int(_private, curve->n,
BITS_TO_WORDS(curve->num_n_bits))) {
return 0;
}
if (EccPoint_compute_public_key(_public, _private, curve)) {
#if uECC_VLI_NATIVE_LITTLE_ENDIAN == 0
uECC_vli_nativeToBytes(private_key, BITS_TO_BYTES(curve->num_n_bits),
_private);
uECC_vli_nativeToBytes(public_key, curve->num_bytes, _public);
uECC_vli_nativeToBytes(public_key + curve->num_bytes, curve->num_bytes,
_public + curve->num_words);
#endif
return 1;
}
}
return 0;
}
int uECC_shared_secret(const uint8_t *public_key, const uint8_t *private_key,
uint8_t *secret, uECC_Curve curve) {
uECC_word_t _public[uECC_MAX_WORDS * 2];
uECC_word_t _private[uECC_MAX_WORDS];
uECC_word_t tmp[uECC_MAX_WORDS];
uECC_word_t *p2[2] = {_private, tmp};
uECC_word_t *initial_Z = 0;
uECC_word_t carry;
wordcount_t num_words = curve->num_words;
wordcount_t num_bytes = curve->num_bytes;
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
bcopy((uint8_t *) _private, private_key, num_bytes);
bcopy((uint8_t *) _public, public_key, num_bytes * 2);
#else
uECC_vli_bytesToNative(_private, private_key,
BITS_TO_BYTES(curve->num_n_bits));
uECC_vli_bytesToNative(_public, public_key, num_bytes);
uECC_vli_bytesToNative(_public + num_words, public_key + num_bytes,
num_bytes);
#endif
/* Regularize the bitcount for the private key so that attackers cannot use a
side channel attack to learn the number of leading zeros. */
carry = regularize_k(_private, _private, tmp, curve);
/* If an RNG function was specified, try to get a random initial Z value to
improve protection against side-channel attacks. */
if (g_rng_function) {
if (!uECC_generate_random_int(p2[carry], curve->p, num_words)) {
return 0;
}
initial_Z = p2[carry];
}
EccPoint_mult(_public, _public, p2[!carry], initial_Z,
(bitcount_t) (curve->num_n_bits + 1), curve);
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
bcopy((uint8_t *) secret, (uint8_t *) _public, num_bytes);
#else
uECC_vli_nativeToBytes(secret, num_bytes, _public);
#endif
return !EccPoint_isZero(_public, curve);
}
#if uECC_SUPPORT_COMPRESSED_POINT
void uECC_compress(const uint8_t *public_key, uint8_t *compressed,
uECC_Curve curve) {
wordcount_t i;
for (i = 0; i < curve->num_bytes; ++i) {
compressed[i + 1] = public_key[i];
}
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
compressed[0] = 2 + (public_key[curve->num_bytes] & 0x01);
#else
compressed[0] = 2 + (public_key[curve->num_bytes * 2 - 1] & 0x01);
#endif
}
void uECC_decompress(const uint8_t *compressed, uint8_t *public_key,
uECC_Curve curve) {
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
uECC_word_t *point = (uECC_word_t *) public_key;
#else
uECC_word_t point[uECC_MAX_WORDS * 2];
#endif
uECC_word_t *y = point + curve->num_words;
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
bcopy(public_key, compressed + 1, curve->num_bytes);
#else
uECC_vli_bytesToNative(point, compressed + 1, curve->num_bytes);
#endif
curve->x_side(y, point, curve);
curve->mod_sqrt(y, curve);
if ((uint8_t) (y[0] & 0x01) != (compressed[0] & 0x01)) {
uECC_vli_sub(y, curve->p, y, curve->num_words);
}
#if uECC_VLI_NATIVE_LITTLE_ENDIAN == 0
uECC_vli_nativeToBytes(public_key, curve->num_bytes, point);
uECC_vli_nativeToBytes(public_key + curve->num_bytes, curve->num_bytes, y);
#endif
}
#endif /* uECC_SUPPORT_COMPRESSED_POINT */
uECC_VLI_API int uECC_valid_point(const uECC_word_t *point, uECC_Curve curve) {
uECC_word_t tmp1[uECC_MAX_WORDS];
uECC_word_t tmp2[uECC_MAX_WORDS];
wordcount_t num_words = curve->num_words;
/* The point at infinity is invalid. */
if (EccPoint_isZero(point, curve)) {
return 0;
}
/* x and y must be smaller than p. */
if (uECC_vli_cmp_unsafe(curve->p, point, num_words) != 1 ||
uECC_vli_cmp_unsafe(curve->p, point + num_words, num_words) != 1) {
return 0;
}
uECC_vli_modSquare_fast(tmp1, point + num_words, curve);
curve->x_side(tmp2, point, curve); /* tmp2 = x^3 + ax + b */
/* Make sure that y^2 == x^3 + ax + b */
return (int) (uECC_vli_equal(tmp1, tmp2, num_words));
}
int uECC_valid_public_key(const uint8_t *public_key, uECC_Curve curve) {
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
uECC_word_t *_public = (uECC_word_t *) public_key;
#else
uECC_word_t _public[uECC_MAX_WORDS * 2];
#endif
#if uECC_VLI_NATIVE_LITTLE_ENDIAN == 0
uECC_vli_bytesToNative(_public, public_key, curve->num_bytes);
uECC_vli_bytesToNative(_public + curve->num_words,
public_key + curve->num_bytes, curve->num_bytes);
#endif
return uECC_valid_point(_public, curve);
}
int uECC_compute_public_key(const uint8_t *private_key, uint8_t *public_key,
uECC_Curve curve) {
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
uECC_word_t *_private = (uECC_word_t *) private_key;
uECC_word_t *_public = (uECC_word_t *) public_key;
#else
uECC_word_t _private[uECC_MAX_WORDS];
uECC_word_t _public[uECC_MAX_WORDS * 2];
#endif
#if uECC_VLI_NATIVE_LITTLE_ENDIAN == 0
uECC_vli_bytesToNative(_private, private_key,
BITS_TO_BYTES(curve->num_n_bits));
#endif
/* Make sure the private key is in the range [1, n-1]. */
if (uECC_vli_isZero(_private, BITS_TO_WORDS(curve->num_n_bits))) {
return 0;
}
if (uECC_vli_cmp(curve->n, _private, BITS_TO_WORDS(curve->num_n_bits)) != 1) {
return 0;
}
/* Compute public key. */
if (!EccPoint_compute_public_key(_public, _private, curve)) {
return 0;
}
#if uECC_VLI_NATIVE_LITTLE_ENDIAN == 0
uECC_vli_nativeToBytes(public_key, curve->num_bytes, _public);
uECC_vli_nativeToBytes(public_key + curve->num_bytes, curve->num_bytes,
_public + curve->num_words);
#endif
return 1;
}
/* -------- ECDSA code -------- */
static void bits2int(uECC_word_t *native, const uint8_t *bits,
unsigned bits_size, uECC_Curve curve) {
unsigned num_n_bytes = (unsigned) BITS_TO_BYTES(curve->num_n_bits);
unsigned num_n_words = (unsigned) BITS_TO_WORDS(curve->num_n_bits);
int shift;
uECC_word_t carry;
uECC_word_t *ptr;
if (bits_size > num_n_bytes) {
bits_size = num_n_bytes;
}
uECC_vli_clear(native, (wordcount_t) num_n_words);
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
bcopy((uint8_t *) native, bits, bits_size);
#else
uECC_vli_bytesToNative(native, bits, (int) bits_size);
#endif
if (bits_size * 8 <= (unsigned) curve->num_n_bits) {
return;
}
shift = (int) bits_size * 8 - curve->num_n_bits;
carry = 0;
ptr = native + num_n_words;
while (ptr-- > native) {
uECC_word_t temp = *ptr;
*ptr = (temp >> shift) | carry;
carry = temp << (uECC_WORD_BITS - shift);
}
/* Reduce mod curve_n */
if (uECC_vli_cmp_unsafe(curve->n, native, (wordcount_t) num_n_words) != 1) {
uECC_vli_sub(native, native, curve->n, (wordcount_t) num_n_words);
}
}
static int uECC_sign_with_k_internal(const uint8_t *private_key,
const uint8_t *message_hash,
unsigned hash_size, uECC_word_t *k,
uint8_t *signature, uECC_Curve curve) {
uECC_word_t tmp[uECC_MAX_WORDS];
uECC_word_t s[uECC_MAX_WORDS];
uECC_word_t *k2[2] = {tmp, s};
uECC_word_t *initial_Z = 0;
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
uECC_word_t *p = (uECC_word_t *) signature;
#else
uECC_word_t p[uECC_MAX_WORDS * 2];
#endif
uECC_word_t carry;
wordcount_t num_words = curve->num_words;
wordcount_t num_n_words = BITS_TO_WORDS(curve->num_n_bits);
bitcount_t num_n_bits = curve->num_n_bits;
/* Make sure 0 < k < curve_n */
if (uECC_vli_isZero(k, num_words) ||
uECC_vli_cmp(curve->n, k, num_n_words) != 1) {
return 0;
}
carry = regularize_k(k, tmp, s, curve);
/* If an RNG function was specified, try to get a random initial Z value to
improve protection against side-channel attacks. */
if (g_rng_function) {
if (!uECC_generate_random_int(k2[carry], curve->p, num_words)) {
return 0;
}
initial_Z = k2[carry];
}
EccPoint_mult(p, curve->G, k2[!carry], initial_Z,
(bitcount_t) (num_n_bits + 1), curve);
if (uECC_vli_isZero(p, num_words)) {
return 0;
}
/* If an RNG function was specified, get a random number
to prevent side channel analysis of k. */
if (!g_rng_function) {
uECC_vli_clear(tmp, num_n_words);
tmp[0] = 1;
} else if (!uECC_generate_random_int(tmp, curve->n, num_n_words)) {
return 0;
}
/* Prevent side channel analysis of uECC_vli_modInv() to determine
bits of k / the private key by premultiplying by a random number */
uECC_vli_modMult(k, k, tmp, curve->n, num_n_words); /* k' = rand * k */
uECC_vli_modInv(k, k, curve->n, num_n_words); /* k = 1 / k' */
uECC_vli_modMult(k, k, tmp, curve->n, num_n_words); /* k = 1 / k */
#if uECC_VLI_NATIVE_LITTLE_ENDIAN == 0
uECC_vli_nativeToBytes(signature, curve->num_bytes, p); /* store r */
#endif
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
bcopy((uint8_t *) tmp, private_key, BITS_TO_BYTES(curve->num_n_bits));
#else
uECC_vli_bytesToNative(tmp, private_key,
BITS_TO_BYTES(curve->num_n_bits)); /* tmp = d */
#endif
s[num_n_words - 1] = 0;
uECC_vli_set(s, p, num_words);
uECC_vli_modMult(s, tmp, s, curve->n, num_n_words); /* s = r*d */
bits2int(tmp, message_hash, hash_size, curve);
uECC_vli_modAdd(s, tmp, s, curve->n, num_n_words); /* s = e + r*d */
uECC_vli_modMult(s, s, k, curve->n, num_n_words); /* s = (e + r*d) / k */
if (uECC_vli_numBits(s, num_n_words) > (bitcount_t) curve->num_bytes * 8) {
return 0;
}
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
bcopy((uint8_t *) signature + curve->num_bytes, (uint8_t *) s,
curve->num_bytes);
#else
uECC_vli_nativeToBytes(signature + curve->num_bytes, curve->num_bytes, s);
#endif
return 1;
}
#if 0
/* For testing - sign with an explicitly specified k value */
int uECC_sign_with_k(const uint8_t *private_key, const uint8_t *message_hash,
unsigned hash_size, const uint8_t *k, uint8_t *signature,
uECC_Curve curve) {
uECC_word_t k2[uECC_MAX_WORDS];
bits2int(k2, k, (unsigned) BITS_TO_BYTES(curve->num_n_bits), curve);
return uECC_sign_with_k_internal(private_key, message_hash, hash_size, k2,
signature, curve);
}
#endif
int uECC_sign(const uint8_t *private_key, const uint8_t *message_hash,
unsigned hash_size, uint8_t *signature, uECC_Curve curve) {
uECC_word_t k[uECC_MAX_WORDS];
uECC_word_t tries;
for (tries = 0; tries < uECC_RNG_MAX_TRIES; ++tries) {
if (!uECC_generate_random_int(k, curve->n,
BITS_TO_WORDS(curve->num_n_bits))) {
return 0;
}
if (uECC_sign_with_k_internal(private_key, message_hash, hash_size, k,
signature, curve)) {
return 1;
}
}
return 0;
}
/* Compute an HMAC using K as a key (as in RFC 6979). Note that K is always
the same size as the hash result size. */
static void HMAC_init(const uECC_HashContext *hash_context, const uint8_t *K) {
uint8_t *pad = hash_context->tmp + 2 * hash_context->result_size;
unsigned i;
for (i = 0; i < hash_context->result_size; ++i) pad[i] = K[i] ^ 0x36;
for (; i < hash_context->block_size; ++i) pad[i] = 0x36;
hash_context->init_hash(hash_context);
hash_context->update_hash(hash_context, pad, hash_context->block_size);
}
static void HMAC_update(const uECC_HashContext *hash_context,
const uint8_t *message, unsigned message_size) {
hash_context->update_hash(hash_context, message, message_size);
}
static void HMAC_finish(const uECC_HashContext *hash_context, const uint8_t *K,
uint8_t *result) {
uint8_t *pad = hash_context->tmp + 2 * hash_context->result_size;
unsigned i;
for (i = 0; i < hash_context->result_size; ++i) pad[i] = K[i] ^ 0x5c;
for (; i < hash_context->block_size; ++i) pad[i] = 0x5c;
hash_context->finish_hash(hash_context, result);
hash_context->init_hash(hash_context);
hash_context->update_hash(hash_context, pad, hash_context->block_size);
hash_context->update_hash(hash_context, result, hash_context->result_size);
hash_context->finish_hash(hash_context, result);
}
/* V = HMAC_K(V) */
static void update_V(const uECC_HashContext *hash_context, uint8_t *K,
uint8_t *V) {
HMAC_init(hash_context, K);
HMAC_update(hash_context, V, hash_context->result_size);
HMAC_finish(hash_context, K, V);
}
/* Deterministic signing, similar to RFC 6979. Differences are:
* We just use H(m) directly rather than bits2octets(H(m))
(it is not reduced modulo curve_n).
* We generate a value for k (aka T) directly rather than converting
endianness.
Layout of hash_context->tmp: <K> | <V> | (1 byte overlapped 0x00 or 0x01) /
<HMAC pad> */
int uECC_sign_deterministic(const uint8_t *private_key,
const uint8_t *message_hash, unsigned hash_size,
const uECC_HashContext *hash_context,
uint8_t *signature, uECC_Curve curve) {
uint8_t *K = hash_context->tmp;
uint8_t *V = K + hash_context->result_size;
wordcount_t num_bytes = curve->num_bytes;
wordcount_t num_n_words = BITS_TO_WORDS(curve->num_n_bits);
bitcount_t num_n_bits = curve->num_n_bits;
uECC_word_t tries;
unsigned i;
for (i = 0; i < hash_context->result_size; ++i) {
V[i] = 0x01;
K[i] = 0;
}
/* K = HMAC_K(V || 0x00 || int2octets(x) || h(m)) */
HMAC_init(hash_context, K);
V[hash_context->result_size] = 0x00;
HMAC_update(hash_context, V, hash_context->result_size + 1);
HMAC_update(hash_context, private_key, (unsigned int) num_bytes);
HMAC_update(hash_context, message_hash, hash_size);
HMAC_finish(hash_context, K, K);
update_V(hash_context, K, V);
/* K = HMAC_K(V || 0x01 || int2octets(x) || h(m)) */
HMAC_init(hash_context, K);
V[hash_context->result_size] = 0x01;
HMAC_update(hash_context, V, hash_context->result_size + 1);
HMAC_update(hash_context, private_key, (unsigned int) num_bytes);
HMAC_update(hash_context, message_hash, hash_size);
HMAC_finish(hash_context, K, K);
update_V(hash_context, K, V);
for (tries = 0; tries < uECC_RNG_MAX_TRIES; ++tries) {
uECC_word_t T[uECC_MAX_WORDS];
uint8_t *T_ptr = (uint8_t *) T;
wordcount_t T_bytes = 0;
for (;;) {
update_V(hash_context, K, V);
for (i = 0; i < hash_context->result_size; ++i) {
T_ptr[T_bytes++] = V[i];
if (T_bytes >= num_n_words * uECC_WORD_SIZE) {
goto filled;
}
}
}
filled:
if ((bitcount_t) num_n_words * uECC_WORD_SIZE * 8 > num_n_bits) {
uECC_word_t mask = (uECC_word_t) -1;
T[num_n_words - 1] &=
mask >>
((bitcount_t) (num_n_words * uECC_WORD_SIZE * 8 - num_n_bits));
}
if (uECC_sign_with_k_internal(private_key, message_hash, hash_size, T,
signature, curve)) {
return 1;
}
/* K = HMAC_K(V || 0x00) */
HMAC_init(hash_context, K);
V[hash_context->result_size] = 0x00;
HMAC_update(hash_context, V, hash_context->result_size + 1);
HMAC_finish(hash_context, K, K);
update_V(hash_context, K, V);
}
return 0;
}
static bitcount_t smax(bitcount_t a, bitcount_t b) {
return (a > b ? a : b);
}
int uECC_verify(const uint8_t *public_key, const uint8_t *message_hash,
unsigned hash_size, const uint8_t *signature,
uECC_Curve curve) {
uECC_word_t u1[uECC_MAX_WORDS], u2[uECC_MAX_WORDS];
uECC_word_t z[uECC_MAX_WORDS];
uECC_word_t sum[uECC_MAX_WORDS * 2];
uECC_word_t rx[uECC_MAX_WORDS];
uECC_word_t ry[uECC_MAX_WORDS];
uECC_word_t tx[uECC_MAX_WORDS];
uECC_word_t ty[uECC_MAX_WORDS];
uECC_word_t tz[uECC_MAX_WORDS];
const uECC_word_t *points[4];
const uECC_word_t *point;
bitcount_t num_bits;
bitcount_t i;
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
uECC_word_t *_public = (uECC_word_t *) public_key;
#else
uECC_word_t _public[uECC_MAX_WORDS * 2];
#endif
uECC_word_t r[uECC_MAX_WORDS], s[uECC_MAX_WORDS];
wordcount_t num_words = curve->num_words;
wordcount_t num_n_words = BITS_TO_WORDS(curve->num_n_bits);
rx[num_n_words - 1] = 0;
r[num_n_words - 1] = 0;
s[num_n_words - 1] = 0;
#if uECC_VLI_NATIVE_LITTLE_ENDIAN
bcopy((uint8_t *) r, signature, curve->num_bytes);
bcopy((uint8_t *) s, signature + curve->num_bytes, curve->num_bytes);
#else
uECC_vli_bytesToNative(_public, public_key, curve->num_bytes);
uECC_vli_bytesToNative(_public + num_words, public_key + curve->num_bytes,
curve->num_bytes);
uECC_vli_bytesToNative(r, signature, curve->num_bytes);
uECC_vli_bytesToNative(s, signature + curve->num_bytes, curve->num_bytes);
#endif
/* r, s must not be 0. */
if (uECC_vli_isZero(r, num_words) || uECC_vli_isZero(s, num_words)) {
return 0;
}
/* r, s must be < n. */
if (uECC_vli_cmp_unsafe(curve->n, r, num_n_words) != 1 ||
uECC_vli_cmp_unsafe(curve->n, s, num_n_words) != 1) {
return 0;
}
/* Calculate u1 and u2. */
uECC_vli_modInv(z, s, curve->n, num_n_words); /* z = 1/s */
u1[num_n_words - 1] = 0;
bits2int(u1, message_hash, hash_size, curve);
uECC_vli_modMult(u1, u1, z, curve->n, num_n_words); /* u1 = e/s */
uECC_vli_modMult(u2, r, z, curve->n, num_n_words); /* u2 = r/s */
/* Calculate sum = G + Q. */
uECC_vli_set(sum, _public, num_words);
uECC_vli_set(sum + num_words, _public + num_words, num_words);
uECC_vli_set(tx, curve->G, num_words);
uECC_vli_set(ty, curve->G + num_words, num_words);
uECC_vli_modSub(z, sum, tx, curve->p, num_words); /* z = x2 - x1 */
XYcZ_add(tx, ty, sum, sum + num_words, curve);
uECC_vli_modInv(z, z, curve->p, num_words); /* z = 1/z */
apply_z(sum, sum + num_words, z, curve);
/* Use Shamir's trick to calculate u1*G + u2*Q */
points[0] = 0;
points[1] = curve->G;
points[2] = _public;
points[3] = sum;
num_bits = smax(uECC_vli_numBits(u1, num_n_words),
uECC_vli_numBits(u2, num_n_words));
point = points[(!!uECC_vli_testBit(u1, (bitcount_t) (num_bits - 1))) |
((!!uECC_vli_testBit(u2, (bitcount_t) (num_bits - 1))) << 1)];
uECC_vli_set(rx, point, num_words);
uECC_vli_set(ry, point + num_words, num_words);
uECC_vli_clear(z, num_words);
z[0] = 1;
for (i = num_bits - 2; i >= 0; --i) {
uECC_word_t index;
curve->double_jacobian(rx, ry, z, curve);
index = (!!uECC_vli_testBit(u1, i)) |
(uECC_word_t) ((!!uECC_vli_testBit(u2, i)) << 1);
point = points[index];
if (point) {
uECC_vli_set(tx, point, num_words);
uECC_vli_set(ty, point + num_words, num_words);
apply_z(tx, ty, z, curve);
uECC_vli_modSub(tz, rx, tx, curve->p, num_words); /* Z = x2 - x1 */
XYcZ_add(tx, ty, rx, ry, curve);
uECC_vli_modMult_fast(z, z, tz, curve);
}
}
uECC_vli_modInv(z, z, curve->p, num_words); /* Z = 1/Z */
apply_z(rx, ry, z, curve);
/* v = x1 (mod n) */
if (uECC_vli_cmp_unsafe(curve->n, rx, num_n_words) != 1) {
uECC_vli_sub(rx, rx, curve->n, num_n_words);
}
/* Accept only if v == r. */
return (int) (uECC_vli_equal(rx, r, num_words));
}
#if uECC_ENABLE_VLI_API
unsigned uECC_curve_num_words(uECC_Curve curve) {
return curve->num_words;
}
unsigned uECC_curve_num_bytes(uECC_Curve curve) {
return curve->num_bytes;
}
unsigned uECC_curve_num_bits(uECC_Curve curve) {
return curve->num_bytes * 8;
}
unsigned uECC_curve_num_n_words(uECC_Curve curve) {
return BITS_TO_WORDS(curve->num_n_bits);
}
unsigned uECC_curve_num_n_bytes(uECC_Curve curve) {
return BITS_TO_BYTES(curve->num_n_bits);
}
unsigned uECC_curve_num_n_bits(uECC_Curve curve) {
return curve->num_n_bits;
}
const uECC_word_t *uECC_curve_p(uECC_Curve curve) {
return curve->p;
}
const uECC_word_t *uECC_curve_n(uECC_Curve curve) {
return curve->n;
}
const uECC_word_t *uECC_curve_G(uECC_Curve curve) {
return curve->G;
}
const uECC_word_t *uECC_curve_b(uECC_Curve curve) {
return curve->b;
}
#if uECC_SUPPORT_COMPRESSED_POINT
void uECC_vli_mod_sqrt(uECC_word_t *a, uECC_Curve curve) {
curve->mod_sqrt(a, curve);
}
#endif
void uECC_vli_mmod_fast(uECC_word_t *result, uECC_word_t *product,
uECC_Curve curve) {
#if (uECC_OPTIMIZATION_LEVEL > 0)
curve->mmod_fast(result, product);
#else
uECC_vli_mmod(result, product, curve->p, curve->num_words);
#endif
}
void uECC_point_mult(uECC_word_t *result, const uECC_word_t *point,
const uECC_word_t *scalar, uECC_Curve curve) {
uECC_word_t tmp1[uECC_MAX_WORDS];
uECC_word_t tmp2[uECC_MAX_WORDS];
uECC_word_t *p2[2] = {tmp1, tmp2};
uECC_word_t carry = regularize_k(scalar, tmp1, tmp2, curve);
EccPoint_mult(result, point, p2[!carry], 0, curve->num_n_bits + 1, curve);
}
#endif /* uECC_ENABLE_VLI_API */
#endif // MG_TLS_BUILTIN
// End of uecc BSD-2
#ifdef MG_ENABLE_LINES
#line 1 "src/url.c"
#endif
struct url {
size_t key, user, pass, host, port, uri, end;
};
int mg_url_is_ssl(const char *url) {
return strncmp(url, "wss:", 4) == 0 || strncmp(url, "https:", 6) == 0 ||
strncmp(url, "mqtts:", 6) == 0 || strncmp(url, "ssl:", 4) == 0 ||
strncmp(url, "tls:", 4) == 0 || strncmp(url, "tcps:", 5) == 0;
}
static struct url urlparse(const char *url) {
size_t i;
struct url u;
memset(&u, 0, sizeof(u));
for (i = 0; url[i] != '\0'; i++) {
if (url[i] == '/' && i > 0 && u.host == 0 && url[i - 1] == '/') {
u.host = i + 1;
u.port = 0;
} else if (url[i] == ']') {
u.port = 0; // IPv6 URLs, like http://[::1]/bar
} else if (url[i] == ':' && u.port == 0 && u.uri == 0) {
u.port = i + 1;
} else if (url[i] == '@' && u.user == 0 && u.pass == 0 && u.uri == 0) {
u.user = u.host;
u.pass = u.port;
u.host = i + 1;
u.port = 0;
} else if (url[i] == '/' && u.host && u.uri == 0) {
u.uri = i;
}
}
u.end = i;
#if 0
printf("[%s] %d %d %d %d %d\n", url, u.user, u.pass, u.host, u.port, u.uri);
#endif
return u;
}
struct mg_str mg_url_host(const char *url) {
struct url u = urlparse(url);
size_t n = u.port ? u.port - u.host - 1
: u.uri ? u.uri - u.host
: u.end - u.host;
struct mg_str s = mg_str_n(url + u.host, n);
return s;
}
const char *mg_url_uri(const char *url) {
struct url u = urlparse(url);
return u.uri ? url + u.uri : "/";
}
unsigned short mg_url_port(const char *url) {
struct url u = urlparse(url);
unsigned short port = 0;
if (strncmp(url, "http:", 5) == 0 || strncmp(url, "ws:", 3) == 0) port = 80;
if (strncmp(url, "wss:", 4) == 0 || strncmp(url, "https:", 6) == 0)
port = 443;
if (strncmp(url, "mqtt:", 5) == 0) port = 1883;
if (strncmp(url, "mqtts:", 6) == 0) port = 8883;
if (u.port) port = (unsigned short) atoi(url + u.port);
return port;
}
struct mg_str mg_url_user(const char *url) {
struct url u = urlparse(url);
struct mg_str s = mg_str("");
if (u.user && (u.pass || u.host)) {
size_t n = u.pass ? u.pass - u.user - 1 : u.host - u.user - 1;
s = mg_str_n(url + u.user, n);
}
return s;
}
struct mg_str mg_url_pass(const char *url) {
struct url u = urlparse(url);
struct mg_str s = mg_str_n("", 0UL);
if (u.pass && u.host) {
size_t n = u.host - u.pass - 1;
s = mg_str_n(url + u.pass, n);
}
return s;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/util.c"
#endif
// Not using memset for zeroing memory, cause it can be dropped by compiler
// See https://github.com/cesanta/mongoose/pull/1265
void mg_bzero(volatile unsigned char *buf, size_t len) {
if (buf != NULL) {
while (len--) *buf++ = 0;
}
}
#if MG_ENABLE_CUSTOM_RANDOM
#else
void mg_random(void *buf, size_t len) {
bool done = false;
unsigned char *p = (unsigned char *) buf;
#if MG_ARCH == MG_ARCH_ESP32
while (len--) *p++ = (unsigned char) (esp_random() & 255);
done = true;
#elif MG_ARCH == MG_ARCH_WIN32
#elif MG_ARCH == MG_ARCH_UNIX
FILE *fp = fopen("/dev/urandom", "rb");
if (fp != NULL) {
if (fread(buf, 1, len, fp) == len) done = true;
fclose(fp);
}
#endif
// If everything above did not work, fallback to a pseudo random generator
while (!done && len--) *p++ = (unsigned char) (rand() & 255);
}
#endif
char *mg_random_str(char *buf, size_t len) {
size_t i;
mg_random(buf, len);
for (i = 0; i < len; i++) {
uint8_t c = ((uint8_t *) buf)[i] % 62U;
buf[i] = i == len - 1 ? (char) '\0' // 0-terminate last byte
: c < 26 ? (char) ('a' + c) // lowercase
: c < 52 ? (char) ('A' + c - 26) // uppercase
: (char) ('0' + c - 52); // numeric
}
return buf;
}
uint32_t mg_ntohl(uint32_t net) {
uint8_t data[4] = {0, 0, 0, 0};
memcpy(&data, &net, sizeof(data));
return (((uint32_t) data[3]) << 0) | (((uint32_t) data[2]) << 8) |
(((uint32_t) data[1]) << 16) | (((uint32_t) data[0]) << 24);
}
uint16_t mg_ntohs(uint16_t net) {
uint8_t data[2] = {0, 0};
memcpy(&data, &net, sizeof(data));
return (uint16_t) ((uint16_t) data[1] | (((uint16_t) data[0]) << 8));
}
uint32_t mg_crc32(uint32_t crc, const char *buf, size_t len) {
static const uint32_t crclut[16] = {
// table for polynomial 0xEDB88320 (reflected)
0x00000000, 0x1DB71064, 0x3B6E20C8, 0x26D930AC, 0x76DC4190, 0x6B6B51F4,
0x4DB26158, 0x5005713C, 0xEDB88320, 0xF00F9344, 0xD6D6A3E8, 0xCB61B38C,
0x9B64C2B0, 0x86D3D2D4, 0xA00AE278, 0xBDBDF21C};
crc = ~crc;
while (len--) {
uint8_t byte = *(uint8_t *) buf++;
crc = crclut[(crc ^ byte) & 0x0F] ^ (crc >> 4);
crc = crclut[(crc ^ (byte >> 4)) & 0x0F] ^ (crc >> 4);
}
return ~crc;
}
static int isbyte(int n) {
return n >= 0 && n <= 255;
}
static int parse_net(const char *spec, uint32_t *net, uint32_t *mask) {
int n, a, b, c, d, slash = 32, len = 0;
if ((sscanf(spec, "%d.%d.%d.%d/%d%n", &a, &b, &c, &d, &slash, &n) == 5 ||
sscanf(spec, "%d.%d.%d.%d%n", &a, &b, &c, &d, &n) == 4) &&
isbyte(a) && isbyte(b) && isbyte(c) && isbyte(d) && slash >= 0 &&
slash < 33) {
len = n;
*net = ((uint32_t) a << 24) | ((uint32_t) b << 16) | ((uint32_t) c << 8) |
(uint32_t) d;
*mask = slash ? (uint32_t) (0xffffffffU << (32 - slash)) : (uint32_t) 0;
}
return len;
}
int mg_check_ip_acl(struct mg_str acl, struct mg_addr *remote_ip) {
struct mg_str k, v;
int allowed = acl.len == 0 ? '+' : '-'; // If any ACL is set, deny by default
uint32_t remote_ip4;
if (remote_ip->is_ip6) {
return -1; // TODO(): handle IPv6 ACL and addresses
} else { // IPv4
memcpy((void *) &remote_ip4, remote_ip->ip, sizeof(remote_ip4));
while (mg_commalist(&acl, &k, &v)) {
uint32_t net, mask;
if (k.ptr[0] != '+' && k.ptr[0] != '-') return -1;
if (parse_net(&k.ptr[1], &net, &mask) == 0) return -2;
if ((mg_ntohl(remote_ip4) & mask) == net) allowed = k.ptr[0];
}
}
return allowed == '+';
}
#if MG_ENABLE_CUSTOM_MILLIS
#else
uint64_t mg_millis(void) {
#if MG_ARCH == MG_ARCH_WIN32
return GetTickCount();
#elif MG_ARCH == MG_ARCH_RP2040
return time_us_64() / 1000;
#elif MG_ARCH == MG_ARCH_ESP8266 || MG_ARCH == MG_ARCH_ESP32 || \
MG_ARCH == MG_ARCH_FREERTOS
return xTaskGetTickCount() * portTICK_PERIOD_MS;
#elif MG_ARCH == MG_ARCH_AZURERTOS
return tx_time_get() * (1000 /* MS per SEC */ / TX_TIMER_TICKS_PER_SECOND);
#elif MG_ARCH == MG_ARCH_TIRTOS
return (uint64_t) Clock_getTicks();
#elif MG_ARCH == MG_ARCH_ZEPHYR
return (uint64_t) k_uptime_get();
#elif MG_ARCH == MG_ARCH_CMSIS_RTOS1
return (uint64_t) rt_time_get();
#elif MG_ARCH == MG_ARCH_CMSIS_RTOS2
return (uint64_t) ((osKernelGetTickCount() * 1000) / osKernelGetTickFreq());
#elif MG_ARCH == MG_ARCH_RTTHREAD
return (uint64_t) ((rt_tick_get() * 1000) / RT_TICK_PER_SECOND);
#elif MG_ARCH == MG_ARCH_UNIX && defined(__APPLE__)
// Apple CLOCK_MONOTONIC_RAW is equivalent to CLOCK_BOOTTIME on linux
// Apple CLOCK_UPTIME_RAW is equivalent to CLOCK_MONOTONIC_RAW on linux
return clock_gettime_nsec_np(CLOCK_UPTIME_RAW) / 1000000;
#elif MG_ARCH == MG_ARCH_UNIX
struct timespec ts = {0, 0};
// See #1615 - prefer monotonic clock
#if defined(CLOCK_MONOTONIC_RAW)
// Raw hardware-based time that is not subject to NTP adjustment
clock_gettime(CLOCK_MONOTONIC_RAW, &ts);
#elif defined(CLOCK_MONOTONIC)
// Affected by the incremental adjustments performed by adjtime and NTP
clock_gettime(CLOCK_MONOTONIC, &ts);
#else
// Affected by discontinuous jumps in the system time and by the incremental
// adjustments performed by adjtime and NTP
clock_gettime(CLOCK_REALTIME, &ts);
#endif
return ((uint64_t) ts.tv_sec * 1000 + (uint64_t) ts.tv_nsec / 1000000);
#elif defined(ARDUINO)
return (uint64_t) millis();
#else
return (uint64_t) (time(NULL) * 1000);
#endif
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/ws.c"
#endif
struct ws_msg {
uint8_t flags;
size_t header_len;
size_t data_len;
};
size_t mg_ws_vprintf(struct mg_connection *c, int op, const char *fmt,
va_list *ap) {
size_t len = c->send.len;
size_t n = mg_vxprintf(mg_pfn_iobuf, &c->send, fmt, ap);
mg_ws_wrap(c, c->send.len - len, op);
return n;
}
size_t mg_ws_printf(struct mg_connection *c, int op, const char *fmt, ...) {
size_t len = 0;
va_list ap;
va_start(ap, fmt);
len = mg_ws_vprintf(c, op, fmt, &ap);
va_end(ap);
return len;
}
static void ws_handshake(struct mg_connection *c, const struct mg_str *wskey,
const struct mg_str *wsproto, const char *fmt,
va_list *ap) {
const char *magic = "258EAFA5-E914-47DA-95CA-C5AB0DC85B11";
unsigned char sha[20], b64_sha[30];
mg_sha1_ctx sha_ctx;
mg_sha1_init(&sha_ctx);
mg_sha1_update(&sha_ctx, (unsigned char *) wskey->ptr, wskey->len);
mg_sha1_update(&sha_ctx, (unsigned char *) magic, 36);
mg_sha1_final(sha, &sha_ctx);
mg_base64_encode(sha, sizeof(sha), (char *) b64_sha, sizeof(b64_sha));
mg_xprintf(mg_pfn_iobuf, &c->send,
"HTTP/1.1 101 Switching Protocols\r\n"
"Upgrade: websocket\r\n"
"Connection: Upgrade\r\n"
"Sec-WebSocket-Accept: %s\r\n",
b64_sha);
if (fmt != NULL) mg_vxprintf(mg_pfn_iobuf, &c->send, fmt, ap);
if (wsproto != NULL) {
mg_printf(c, "Sec-WebSocket-Protocol: %.*s\r\n", (int) wsproto->len,
wsproto->ptr);
}
mg_send(c, "\r\n", 2);
}
static uint32_t be32(const uint8_t *p) {
return (((uint32_t) p[3]) << 0) | (((uint32_t) p[2]) << 8) |
(((uint32_t) p[1]) << 16) | (((uint32_t) p[0]) << 24);
}
static size_t ws_process(uint8_t *buf, size_t len, struct ws_msg *msg) {
size_t i, n = 0, mask_len = 0;
memset(msg, 0, sizeof(*msg));
if (len >= 2) {
n = buf[1] & 0x7f; // Frame length
mask_len = buf[1] & 128 ? 4 : 0; // last bit is a mask bit
msg->flags = buf[0];
if (n < 126 && len >= mask_len) {
msg->data_len = n;
msg->header_len = 2 + mask_len;
} else if (n == 126 && len >= 4 + mask_len) {
msg->header_len = 4 + mask_len;
msg->data_len = (((size_t) buf[2]) << 8) | buf[3];
} else if (len >= 10 + mask_len) {
msg->header_len = 10 + mask_len;
msg->data_len =
(size_t) (((uint64_t) be32(buf + 2) << 32) + be32(buf + 6));
}
}
// Sanity check, and integer overflow protection for the boundary check below
// data_len should not be larger than 1 Gb
if (msg->data_len > 1024 * 1024 * 1024) return 0;
if (msg->header_len + msg->data_len > len) return 0;
if (mask_len > 0) {
uint8_t *p = buf + msg->header_len, *m = p - mask_len;
for (i = 0; i < msg->data_len; i++) p[i] ^= m[i & 3];
}
return msg->header_len + msg->data_len;
}
static size_t mkhdr(size_t len, int op, bool is_client, uint8_t *buf) {
size_t n = 0;
buf[0] = (uint8_t) (op | 128);
if (len < 126) {
buf[1] = (unsigned char) len;
n = 2;
} else if (len < 65536) {
uint16_t tmp = mg_htons((uint16_t) len);
buf[1] = 126;
memcpy(&buf[2], &tmp, sizeof(tmp));
n = 4;
} else {
uint32_t tmp;
buf[1] = 127;
tmp = mg_htonl((uint32_t) (((uint64_t) len) >> 32));
memcpy(&buf[2], &tmp, sizeof(tmp));
tmp = mg_htonl((uint32_t) (len & 0xffffffffU));
memcpy(&buf[6], &tmp, sizeof(tmp));
n = 10;
}
if (is_client) {
buf[1] |= 1 << 7; // Set masking flag
mg_random(&buf[n], 4);
n += 4;
}
return n;
}
static void mg_ws_mask(struct mg_connection *c, size_t len) {
if (c->is_client && c->send.buf != NULL) {
size_t i;
uint8_t *p = c->send.buf + c->send.len - len, *mask = p - 4;
for (i = 0; i < len; i++) p[i] ^= mask[i & 3];
}
}
size_t mg_ws_send(struct mg_connection *c, const void *buf, size_t len,
int op) {
uint8_t header[14];
size_t header_len = mkhdr(len, op, c->is_client, header);
mg_send(c, header, header_len);
MG_VERBOSE(("WS out: %d [%.*s]", (int) len, (int) len, buf));
mg_send(c, buf, len);
mg_ws_mask(c, len);
return header_len + len;
}
static bool mg_ws_client_handshake(struct mg_connection *c) {
int n = mg_http_get_request_len(c->recv.buf, c->recv.len);
if (n < 0) {
mg_error(c, "not http"); // Some just, not an HTTP request
} else if (n > 0) {
if (n < 15 || memcmp(c->recv.buf + 9, "101", 3) != 0) {
mg_error(c, "ws handshake error");
} else {
struct mg_http_message hm;
if (mg_http_parse((char *) c->recv.buf, c->recv.len, &hm)) {
c->is_websocket = 1;
mg_call(c, MG_EV_WS_OPEN, &hm);
} else {
mg_error(c, "ws handshake error");
}
}
mg_iobuf_del(&c->recv, 0, (size_t) n);
} else {
return true; // Request is not yet received, quit event handler
}
return false; // Continue event handler
}
static void mg_ws_cb(struct mg_connection *c, int ev, void *ev_data) {
struct ws_msg msg;
size_t ofs = (size_t) c->pfn_data;
// assert(ofs < c->recv.len);
if (ev == MG_EV_READ) {
if (c->is_client && !c->is_websocket && mg_ws_client_handshake(c)) return;
while (ws_process(c->recv.buf + ofs, c->recv.len - ofs, &msg) > 0) {
char *s = (char *) c->recv.buf + ofs + msg.header_len;
struct mg_ws_message m = {{s, msg.data_len}, msg.flags};
size_t len = msg.header_len + msg.data_len;
uint8_t final = msg.flags & 128, op = msg.flags & 15;
// MG_VERBOSE ("fin %d op %d len %d [%.*s]", final, op,
// (int) m.data.len, (int) m.data.len, m.data.ptr));
switch (op) {
case WEBSOCKET_OP_CONTINUE:
mg_call(c, MG_EV_WS_CTL, &m);
break;
case WEBSOCKET_OP_PING:
MG_DEBUG(("%s", "WS PONG"));
mg_ws_send(c, s, msg.data_len, WEBSOCKET_OP_PONG);
mg_call(c, MG_EV_WS_CTL, &m);
break;
case WEBSOCKET_OP_PONG:
mg_call(c, MG_EV_WS_CTL, &m);
break;
case WEBSOCKET_OP_TEXT:
case WEBSOCKET_OP_BINARY:
if (final) mg_call(c, MG_EV_WS_MSG, &m);
break;
case WEBSOCKET_OP_CLOSE:
MG_DEBUG(("%lu WS CLOSE", c->id));
mg_call(c, MG_EV_WS_CTL, &m);
// Echo the payload of the received CLOSE message back to the sender
mg_ws_send(c, m.data.ptr, m.data.len, WEBSOCKET_OP_CLOSE);
c->is_draining = 1;
break;
default:
// Per RFC6455, close conn when an unknown op is recvd
mg_error(c, "unknown WS op %d", op);
break;
}
// Handle fragmented frames: strip header, keep in c->recv
if (final == 0 || op == 0) {
if (op) ofs++, len--, msg.header_len--; // First frame
mg_iobuf_del(&c->recv, ofs, msg.header_len); // Strip header
len -= msg.header_len;
ofs += len;
c->pfn_data = (void *) ofs;
// MG_INFO(("FRAG %d [%.*s]", (int) ofs, (int) ofs, c->recv.buf));
}
// Remove non-fragmented frame
if (final && op) mg_iobuf_del(&c->recv, ofs, len);
// Last chunk of the fragmented frame
if (final && !op) {
m.flags = c->recv.buf[0];
m.data = mg_str_n((char *) &c->recv.buf[1], (size_t) (ofs - 1));
mg_call(c, MG_EV_WS_MSG, &m);
mg_iobuf_del(&c->recv, 0, ofs);
ofs = 0;
c->pfn_data = NULL;
}
}
}
(void) ev_data;
}
struct mg_connection *mg_ws_connect(struct mg_mgr *mgr, const char *url,
mg_event_handler_t fn, void *fn_data,
const char *fmt, ...) {
struct mg_connection *c = mg_connect(mgr, url, fn, fn_data);
if (c != NULL) {
char nonce[16], key[30];
struct mg_str host = mg_url_host(url);
mg_random(nonce, sizeof(nonce));
mg_base64_encode((unsigned char *) nonce, sizeof(nonce), key, sizeof(key));
mg_xprintf(mg_pfn_iobuf, &c->send,
"GET %s HTTP/1.1\r\n"
"Upgrade: websocket\r\n"
"Host: %.*s\r\n"
"Connection: Upgrade\r\n"
"Sec-WebSocket-Version: 13\r\n"
"Sec-WebSocket-Key: %s\r\n",
mg_url_uri(url), (int) host.len, host.ptr, key);
if (fmt != NULL) {
va_list ap;
va_start(ap, fmt);
mg_vxprintf(mg_pfn_iobuf, &c->send, fmt, &ap);
va_end(ap);
}
mg_xprintf(mg_pfn_iobuf, &c->send, "\r\n");
c->pfn = mg_ws_cb;
c->pfn_data = NULL;
}
return c;
}
void mg_ws_upgrade(struct mg_connection *c, struct mg_http_message *hm,
const char *fmt, ...) {
struct mg_str *wskey = mg_http_get_header(hm, "Sec-WebSocket-Key");
c->pfn = mg_ws_cb;
c->pfn_data = NULL;
if (wskey == NULL) {
mg_http_reply(c, 426, "", "WS upgrade expected\n");
c->is_draining = 1;
} else {
struct mg_str *wsproto = mg_http_get_header(hm, "Sec-WebSocket-Protocol");
va_list ap;
va_start(ap, fmt);
ws_handshake(c, wskey, wsproto, fmt, &ap);
va_end(ap);
c->is_websocket = 1;
c->is_resp = 0;
mg_call(c, MG_EV_WS_OPEN, hm);
}
}
size_t mg_ws_wrap(struct mg_connection *c, size_t len, int op) {
uint8_t header[14], *p;
size_t header_len = mkhdr(len, op, c->is_client, header);
// NOTE: order of operations is important!
mg_iobuf_add(&c->send, c->send.len, NULL, header_len);
p = &c->send.buf[c->send.len - len]; // p points to data
memmove(p, p - header_len, len); // Shift data
memcpy(p - header_len, header, header_len); // Prepend header
mg_ws_mask(c, len); // Mask data
return c->send.len;
}
#ifdef MG_ENABLE_LINES
#line 1 "src/drivers/cmsis.c"
#endif
// https://arm-software.github.io/CMSIS_5/Driver/html/index.html
#if MG_ENABLE_TCPIP && defined(MG_ENABLE_DRIVER_CMSIS) && MG_ENABLE_DRIVER_CMSIS
extern ARM_DRIVER_ETH_MAC Driver_ETH_MAC0;
extern ARM_DRIVER_ETH_PHY Driver_ETH_PHY0;
static struct mg_tcpip_if *s_ifp;
static void mac_cb(uint32_t);
static bool cmsis_init(struct mg_tcpip_if *);
static bool cmsis_up(struct mg_tcpip_if *);
static size_t cmsis_tx(const void *, size_t, struct mg_tcpip_if *);
static size_t cmsis_rx(void *, size_t, struct mg_tcpip_if *);
struct mg_tcpip_driver mg_tcpip_driver_cmsis = {cmsis_init, cmsis_tx, NULL,
cmsis_up};
static bool cmsis_init(struct mg_tcpip_if *ifp) {
ARM_ETH_MAC_ADDR addr;
s_ifp = ifp;
ARM_DRIVER_ETH_MAC *mac = &Driver_ETH_MAC0;
ARM_DRIVER_ETH_PHY *phy = &Driver_ETH_PHY0;
ARM_ETH_MAC_CAPABILITIES cap = mac->GetCapabilities();
if (mac->Initialize(mac_cb) != ARM_DRIVER_OK) return false;
if (phy->Initialize(mac->PHY_Read, mac->PHY_Write) != ARM_DRIVER_OK)
return false;
if (cap.event_rx_frame == 0) // polled mode driver
mg_tcpip_driver_cmsis.rx = cmsis_rx;
mac->PowerControl(ARM_POWER_FULL);
if (cap.mac_address) { // driver provides MAC address
mac->GetMacAddress(&addr);
memcpy(ifp->mac, &addr, sizeof(ifp->mac));
} else { // we provide MAC address
memcpy(&addr, ifp->mac, sizeof(addr));
mac->SetMacAddress(&addr);
}
phy->PowerControl(ARM_POWER_FULL);
phy->SetInterface(cap.media_interface);
phy->SetMode(ARM_ETH_PHY_AUTO_NEGOTIATE);
return true;
}
static size_t cmsis_tx(const void *buf, size_t len, struct mg_tcpip_if *ifp) {
ARM_DRIVER_ETH_MAC *mac = &Driver_ETH_MAC0;
if (mac->SendFrame(buf, (uint32_t) len, 0) != ARM_DRIVER_OK) {
ifp->nerr++;
return 0;
}
ifp->nsent++;
return len;
}
static bool cmsis_up(struct mg_tcpip_if *ifp) {
ARM_DRIVER_ETH_PHY *phy = &Driver_ETH_PHY0;
ARM_DRIVER_ETH_MAC *mac = &Driver_ETH_MAC0;
bool up = (phy->GetLinkState() == ARM_ETH_LINK_UP) ? 1 : 0; // link state
if ((ifp->state == MG_TCPIP_STATE_DOWN) && up) { // just went up
ARM_ETH_LINK_INFO st = phy->GetLinkInfo();
mac->Control(ARM_ETH_MAC_CONFIGURE,
(st.speed << ARM_ETH_MAC_SPEED_Pos) |
(st.duplex << ARM_ETH_MAC_DUPLEX_Pos) |
ARM_ETH_MAC_ADDRESS_BROADCAST);
MG_DEBUG(("Link is %uM %s-duplex",
(st.speed == 2) ? 1000
: st.speed ? 100
: 10,
st.duplex ? "full" : "half"));
mac->Control(ARM_ETH_MAC_CONTROL_TX, 1);
mac->Control(ARM_ETH_MAC_CONTROL_RX, 1);
} else if ((ifp->state != MG_TCPIP_STATE_DOWN) && !up) { // just went down
mac->Control(ARM_ETH_MAC_FLUSH,
ARM_ETH_MAC_FLUSH_TX | ARM_ETH_MAC_FLUSH_RX);
mac->Control(ARM_ETH_MAC_CONTROL_TX, 0);
mac->Control(ARM_ETH_MAC_CONTROL_RX, 0);
}
return up;
}
static void mac_cb(uint32_t ev) {
if ((ev & ARM_ETH_MAC_EVENT_RX_FRAME) == 0) return;
ARM_DRIVER_ETH_MAC *mac = &Driver_ETH_MAC0;
uint32_t len = mac->GetRxFrameSize(); // CRC already stripped
if (len >= 60 && len <= 1518) { // proper frame
char *p;
if (mg_queue_book(&s_ifp->recv_queue, &p, len) >= len) { // have room
if ((len = mac->ReadFrame((uint8_t *) p, len)) > 0) { // copy succeeds
mg_queue_add(&s_ifp->recv_queue, len);
s_ifp->nrecv++;
}
return;
}
s_ifp->ndrop++;
}
mac->ReadFrame(NULL, 0); // otherwise, discard
}
static size_t cmsis_rx(void *buf, size_t buflen, struct mg_tcpip_if *ifp) {
ARM_DRIVER_ETH_MAC *mac = &Driver_ETH_MAC0;
uint32_t len = mac->GetRxFrameSize(); // CRC already stripped
if (len >= 60 && len <= 1518 &&
((len = mac->ReadFrame(buf, (uint32_t) buflen)) > 0))
return len;
if (len > 0) mac->ReadFrame(NULL, 0); // discard bad frames
(void) ifp;
return 0;
}
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/drivers/imxrt.c"
#endif
#if MG_ENABLE_TCPIP && defined(MG_ENABLE_DRIVER_IMXRT) && MG_ENABLE_DRIVER_IMXRT
struct imxrt_enet {
volatile uint32_t RESERVED0, EIR, EIMR, RESERVED1, RDAR, TDAR, RESERVED2[3],
ECR, RESERVED3[6], MMFR, MSCR, RESERVED4[7], MIBC, RESERVED5[7], RCR,
RESERVED6[15], TCR, RESERVED7[7], PALR, PAUR, OPD, TXIC0, TXIC1, TXIC2,
RESERVED8, RXIC0, RXIC1, RXIC2, RESERVED9[3], IAUR, IALR, GAUR, GALR,
RESERVED10[7], TFWR, RESERVED11[14], RDSR, TDSR, MRBR[2], RSFL, RSEM,
RAEM, RAFL, TSEM, TAEM, TAFL, TIPG, FTRL, RESERVED12[3], TACC, RACC,
RESERVED13[15], RMON_T_PACKETS, RMON_T_BC_PKT, RMON_T_MC_PKT,
RMON_T_CRC_ALIGN, RMON_T_UNDERSIZE, RMON_T_OVERSIZE, RMON_T_FRAG,
RMON_T_JAB, RMON_T_COL, RMON_T_P64, RMON_T_P65TO127, RMON_T_P128TO255,
RMON_T_P256TO511, RMON_T_P512TO1023, RMON_T_P1024TO2048, RMON_T_GTE2048,
RMON_T_OCTETS, IEEE_T_DROP, IEEE_T_FRAME_OK, IEEE_T_1COL, IEEE_T_MCOL,
IEEE_T_DEF, IEEE_T_LCOL, IEEE_T_EXCOL, IEEE_T_MACERR, IEEE_T_CSERR,
IEEE_T_SQE, IEEE_T_FDXFC, IEEE_T_OCTETS_OK, RESERVED14[3], RMON_R_PACKETS,
RMON_R_BC_PKT, RMON_R_MC_PKT, RMON_R_CRC_ALIGN, RMON_R_UNDERSIZE,
RMON_R_OVERSIZE, RMON_R_FRAG, RMON_R_JAB, RESERVED15, RMON_R_P64,
RMON_R_P65TO127, RMON_R_P128TO255, RMON_R_P256TO511, RMON_R_P512TO1023,
RMON_R_P1024TO2047, RMON_R_GTE2048, RMON_R_OCTETS, IEEE_R_DROP,
IEEE_R_FRAME_OK, IEEE_R_CRC, IEEE_R_ALIGN, IEEE_R_MACERR, IEEE_R_FDXFC,
IEEE_R_OCTETS_OK, RESERVED16[71], ATCR, ATVR, ATOFF, ATPER, ATCOR, ATINC,
ATSTMP, RESERVED17[122], TGSR, TCSR0, TCCR0, TCSR1, TCCR1, TCSR2, TCCR2,
TCSR3;
};
#undef ENET
#define ENET ((struct imxrt_enet *) (uintptr_t) 0x402D8000U)
#define ETH_PKT_SIZE 1536 // Max frame size, 64-bit aligned
#define ETH_DESC_CNT 4 // Descriptors count
struct enet_desc {
uint16_t length; // Data length
uint16_t control; // Control and status
uint32_t *buffer; // Data ptr
};
// TODO(): handle these in a portable compiler-independent CMSIS-friendly way
#define MG_64BIT_ALIGNED __attribute__((aligned((64U))))
// Descriptors: in non-cached area (TODO(scaprile)), 64-bit aligned
// Buffers: 64-bit aligned
static volatile struct enet_desc s_rxdesc[ETH_DESC_CNT] MG_64BIT_ALIGNED;
static volatile struct enet_desc s_txdesc[ETH_DESC_CNT] MG_64BIT_ALIGNED;
static uint8_t s_rxbuf[ETH_DESC_CNT][ETH_PKT_SIZE] MG_64BIT_ALIGNED;
static uint8_t s_txbuf[ETH_DESC_CNT][ETH_PKT_SIZE] MG_64BIT_ALIGNED;
static struct mg_tcpip_if *s_ifp; // MIP interface
enum {
MG_PHYREG_BCR = 0,
MG_PHYREG_BSR = 1,
MG_PHYREG_ID1 = 2,
MG_PHYREG_ID2 = 3
};
static uint16_t enet_phy_read(uint8_t addr, uint8_t reg) {
ENET->EIR |= MG_BIT(23); // MII interrupt clear
ENET->MMFR = (1 << 30) | (2 << 28) | (addr << 23) | (reg << 18) | (2 << 16);
while ((ENET->EIR & MG_BIT(23)) == 0) (void) 0;
return ENET->MMFR & 0xffff;
}
static void enet_phy_write(uint8_t addr, uint8_t reg, uint16_t val) {
ENET->EIR |= MG_BIT(23); // MII interrupt clear
ENET->MMFR =
(1 << 30) | (1 << 28) | (addr << 23) | (reg << 18) | (2 << 16) | val;
while ((ENET->EIR & MG_BIT(23)) == 0) (void) 0;
}
static uint32_t enet_phy_id(uint8_t addr) {
uint16_t phy_id1 = enet_phy_read(addr, MG_PHYREG_ID1);
uint16_t phy_id2 = enet_phy_read(addr, MG_PHYREG_ID2);
return (uint32_t) phy_id1 << 16 | phy_id2;
}
// MDC clock is generated from IPS Bus clock (ipg_clk); as per 802.3,
// it must not exceed 2.5MHz
// The PHY receives the PLL6-generated 50MHz clock
static bool mg_tcpip_driver_imxrt_init(struct mg_tcpip_if *ifp) {
struct mg_tcpip_driver_imxrt_data *d =
(struct mg_tcpip_driver_imxrt_data *) ifp->driver_data;
s_ifp = ifp;
// Init RX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
s_rxdesc[i].control = MG_BIT(15); // Own (E)
s_rxdesc[i].buffer = (uint32_t *) s_rxbuf[i]; // Point to data buffer
}
s_rxdesc[ETH_DESC_CNT - 1].control |= MG_BIT(13); // Wrap last descriptor
// Init TX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
// s_txdesc[i].control = MG_BIT(10); // Own (TC)
s_txdesc[i].buffer = (uint32_t *) s_txbuf[i];
}
s_txdesc[ETH_DESC_CNT - 1].control |= MG_BIT(13); // Wrap last descriptor
ENET->ECR = MG_BIT(0); // Software reset, disable
while ((ENET->ECR & MG_BIT(0))) (void) 0; // Wait until done
// Set MDC clock divider. If user told us the value, use it.
// TODO(): Otherwise, guess (currently assuming max freq)
int cr = (d == NULL || d->mdc_cr < 0) ? 24 : d->mdc_cr;
ENET->MSCR = (1 << 8) | ((cr & 0x3f) << 1); // HOLDTIME 2 clks
enet_phy_write(d->phy_addr, MG_PHYREG_BCR, MG_BIT(15)); // Reset PHY
enet_phy_write(d->phy_addr, MG_PHYREG_BCR,
MG_BIT(12)); // Set autonegotiation
// PHY: Enable 50 MHz external ref clock at XI (preserve defaults)
uint32_t id = enet_phy_id(d->phy_addr);
MG_INFO(("PHY ID: %#04x %#04x", (uint16_t) (id >> 16), (uint16_t) id));
// 2000 a140 - TI DP83825I
// 0007 c0fx - LAN8720
// 0022 1561 - KSZ8081RNB
if ((id & 0xffff0000) == 0x220000) { // KSZ8081RNB, like EVK-RTxxxx boards
enet_phy_write(d->phy_addr, 31,
MG_BIT(15) | MG_BIT(8) | MG_BIT(7)); // PC2R
} else if ((id & 0xffff0000) == 0x20000000) { // DP83825I, like Teensy4.1
enet_phy_write(d->phy_addr, 23, 0x81); // 50MHz clock input
enet_phy_write(d->phy_addr, 24, 0x280); // LED status, active high
} else { // Default to LAN8720
MG_INFO(("Defaulting to LAN8720 PHY...")); // TODO()
}
// Select RMII mode, 100M, keep CRC, set max rx length, disable loop
ENET->RCR = (1518 << 16) | MG_BIT(8) | MG_BIT(2);
// ENET->RCR |= MG_BIT(3); // Receive all
ENET->TCR = MG_BIT(2); // Full-duplex
ENET->RDSR = (uint32_t) (uintptr_t) s_rxdesc;
ENET->TDSR = (uint32_t) (uintptr_t) s_txdesc;
ENET->MRBR[0] = ETH_PKT_SIZE; // Same size for RX/TX buffers
// MAC address filtering (bytes in reversed order)
ENET->PAUR = ((uint32_t) ifp->mac[4] << 24U) | (uint32_t) ifp->mac[5] << 16U;
ENET->PALR = (uint32_t) (ifp->mac[0] << 24U) |
((uint32_t) ifp->mac[1] << 16U) |
((uint32_t) ifp->mac[2] << 8U) | ifp->mac[3];
ENET->ECR = MG_BIT(8) | MG_BIT(1); // Little-endian CPU, Enable
ENET->EIMR = MG_BIT(25); // Set interrupt mask
ENET->RDAR = MG_BIT(24); // Receive Descriptors have changed
ENET->TDAR = MG_BIT(24); // Transmit Descriptors have changed
// ENET->OPD = 0x10014;
return true;
}
// Transmit frame
static size_t mg_tcpip_driver_imxrt_tx(const void *buf, size_t len,
struct mg_tcpip_if *ifp) {
static int s_txno; // Current descriptor index
if (len > sizeof(s_txbuf[ETH_DESC_CNT])) {
ifp->nerr++;
MG_ERROR(("Frame too big, %ld", (long) len));
len = (size_t) -1; // fail
} else if ((s_txdesc[s_txno].control & MG_BIT(15))) {
MG_ERROR(("No descriptors available"));
len = 0; // retry later
} else {
memcpy(s_txbuf[s_txno], buf, len); // Copy data
s_txdesc[s_txno].length = (uint16_t) len; // Set data len
// Table 37-34, R, L, TC (Ready, last, transmit CRC after frame
s_txdesc[s_txno].control |=
(uint16_t) (MG_BIT(15) | MG_BIT(11) | MG_BIT(10));
ENET->TDAR = MG_BIT(24); // Descriptor ring updated
if (++s_txno >= ETH_DESC_CNT) s_txno = 0;
}
(void) ifp;
return len;
}
static bool mg_tcpip_driver_imxrt_up(struct mg_tcpip_if *ifp) {
struct mg_tcpip_driver_imxrt_data *d =
(struct mg_tcpip_driver_imxrt_data *) ifp->driver_data;
uint32_t bsr = enet_phy_read(d->phy_addr, MG_PHYREG_BSR);
bool up = bsr & MG_BIT(2) ? 1 : 0;
if ((ifp->state == MG_TCPIP_STATE_DOWN) && up) { // link state just went up
// tmp = reg with flags set to the most likely situation: 100M full-duplex
// if(link is slow or half) set flags otherwise
// reg = tmp
uint32_t tcr = ENET->TCR | MG_BIT(2); // Full-duplex
uint32_t rcr = ENET->RCR & ~MG_BIT(9); // 100M
uint32_t phy_id = enet_phy_id(d->phy_addr);
if ((phy_id & 0xffff0000) == 0x220000) { // KSZ8081RNB
uint16_t pc1r = enet_phy_read(d->phy_addr, 30); // Read PC1R
if ((pc1r & 3) == 1) rcr |= MG_BIT(9); // 10M
if ((pc1r & MG_BIT(2)) == 0) tcr &= ~MG_BIT(2); // Half-duplex
} else if ((phy_id & 0xffff0000) == 0x20000000) { // DP83825I
uint16_t physts = enet_phy_read(d->phy_addr, 16); // Read PHYSTS
if (physts & MG_BIT(1)) rcr |= MG_BIT(9); // 10M
if ((physts & MG_BIT(2)) == 0) tcr &= ~MG_BIT(2); // Half-duplex
} else { // Default to LAN8720
uint16_t scsr = enet_phy_read(d->phy_addr, 31); // Read CSCR
if ((scsr & MG_BIT(3)) == 0) rcr |= MG_BIT(9); // 10M
if ((scsr & MG_BIT(4)) == 0) tcr &= ~MG_BIT(2); // Half-duplex
}
ENET->TCR = tcr; // IRQ handler does not fiddle with these registers
ENET->RCR = rcr;
MG_DEBUG(("Link is %uM %s-duplex", rcr & MG_BIT(9) ? 10 : 100,
tcr & MG_BIT(2) ? "full" : "half"));
}
return up;
}
void ENET_IRQHandler(void);
static uint32_t s_rxno;
void ENET_IRQHandler(void) {
ENET->EIR = MG_BIT(25); // Ack IRQ
// Frame received, loop
for (uint32_t i = 0; i < 10; i++) { // read as they arrive but not forever
uint32_t r = s_rxdesc[s_rxno].control;
if (r & MG_BIT(15)) break; // exit when done
// skip partial/errored frames (Table 37-32)
if ((r & MG_BIT(11)) &&
!(r & (MG_BIT(5) | MG_BIT(4) | MG_BIT(2) | MG_BIT(1) | MG_BIT(0)))) {
size_t len = s_rxdesc[s_rxno].length;
mg_tcpip_qwrite(s_rxbuf[s_rxno], len > 4 ? len - 4 : len, s_ifp);
}
s_rxdesc[s_rxno].control |= MG_BIT(15);
if (++s_rxno >= ETH_DESC_CNT) s_rxno = 0;
}
ENET->RDAR = MG_BIT(24); // Receive Descriptors have changed
// If b24 == 0, descriptors were exhausted and probably frames were dropped
}
struct mg_tcpip_driver mg_tcpip_driver_imxrt = {mg_tcpip_driver_imxrt_init,
mg_tcpip_driver_imxrt_tx, NULL,
mg_tcpip_driver_imxrt_up};
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/drivers/same54.c"
#endif
#if defined(MG_ENABLE_DRIVER_SAME54) && MG_ENABLE_DRIVER_SAME54
#include <sam.h>
#define ETH_PKT_SIZE 1536 // Max frame size
#define ETH_DESC_CNT 4 // Descriptors count
#define ETH_DS 2 // Descriptor size (words)
static uint8_t s_rxbuf[ETH_DESC_CNT][ETH_PKT_SIZE];
static uint8_t s_txbuf[ETH_DESC_CNT][ETH_PKT_SIZE];
static uint32_t s_rxdesc[ETH_DESC_CNT][ETH_DS]; // RX descriptors
static uint32_t s_txdesc[ETH_DESC_CNT][ETH_DS]; // TX descriptors
static uint8_t s_txno; // Current TX descriptor
static uint8_t s_rxno; // Current RX descriptor
static struct mg_tcpip_if *s_ifp; // MIP interface
enum { MG_PHY_ADDR = 0, MG_PHYREG_BCR = 0, MG_PHYREG_BSR = 1 };
#define MG_PHYREGBIT_BCR_DUPLEX_MODE MG_BIT(8)
#define MG_PHYREGBIT_BCR_SPEED MG_BIT(13)
#define MG_PHYREGBIT_BSR_LINK_STATUS MG_BIT(2)
static uint16_t eth_read_phy(uint8_t addr, uint8_t reg) {
GMAC_REGS->GMAC_MAN = GMAC_MAN_CLTTO_Msk |
GMAC_MAN_OP(2) | // Setting the read operation
GMAC_MAN_WTN(2) | GMAC_MAN_PHYA(addr) | // PHY address
GMAC_MAN_REGA(reg); // Setting the register
while (!(GMAC_REGS->GMAC_NSR & GMAC_NSR_IDLE_Msk)) (void) 0;
return GMAC_REGS->GMAC_MAN & GMAC_MAN_DATA_Msk; // Getting the read value
}
#if 0
static void eth_write_phy(uint8_t addr, uint8_t reg, uint16_t val) {
GMAC_REGS->GMAC_MAN = GMAC_MAN_CLTTO_Msk | GMAC_MAN_OP(1) | // Setting the write operation
GMAC_MAN_WTN(2) | GMAC_MAN_PHYA(addr) | // PHY address
GMAC_MAN_REGA(reg) | GMAC_MAN_DATA(val); // Setting the register
while (!(GMAC_REGS->GMAC_NSR & GMAC_NSR_IDLE_Msk)); // Waiting until the write op is complete
}
#endif
int get_clock_rate(struct mg_tcpip_driver_same54_data *d) {
if (d && d->mdc_cr >= 0 && d->mdc_cr <= 5) {
return d->mdc_cr;
} else {
// get MCLK from GCLK_GENERATOR 0
uint32_t div = 512;
uint32_t mclk;
if (!(GCLK_REGS->GCLK_GENCTRL[0] & GCLK_GENCTRL_DIVSEL_Msk)) {
div = ((GCLK_REGS->GCLK_GENCTRL[0] & 0x00FF0000) >> 16);
if (div == 0) div = 1;
}
switch (GCLK_REGS->GCLK_GENCTRL[0] & GCLK_GENCTRL_SRC_Msk) {
case GCLK_GENCTRL_SRC_XOSC0_Val:
mclk = 32000000UL; /* 32MHz */
break;
case GCLK_GENCTRL_SRC_XOSC1_Val:
mclk = 32000000UL; /* 32MHz */
break;
case GCLK_GENCTRL_SRC_OSCULP32K_Val:
mclk = 32000UL;
break;
case GCLK_GENCTRL_SRC_XOSC32K_Val:
mclk = 32000UL;
break;
case GCLK_GENCTRL_SRC_DFLL_Val:
mclk = 48000000UL; /* 48MHz */
break;
case GCLK_GENCTRL_SRC_DPLL0_Val:
mclk = 200000000UL; /* 200MHz */
break;
case GCLK_GENCTRL_SRC_DPLL1_Val:
mclk = 200000000UL; /* 200MHz */
break;
default:
mclk = 200000000UL; /* 200MHz */
}
mclk /= div;
uint8_t crs[] = {0, 1, 2, 3, 4, 5}; // GMAC->NCFGR::CLK values
uint8_t dividers[] = {8, 16, 32, 48, 64, 96}; // Respective CLK dividers
for (int i = 0; i < 6; i++) {
if (mclk / dividers[i] <= 2375000UL /* 2.5MHz - 5% */) {
return crs[i];
}
}
return 5;
}
}
static bool mg_tcpip_driver_same54_init(struct mg_tcpip_if *ifp) {
struct mg_tcpip_driver_same54_data *d =
(struct mg_tcpip_driver_same54_data *) ifp->driver_data;
s_ifp = ifp;
MCLK_REGS->MCLK_APBCMASK |= MCLK_APBCMASK_GMAC_Msk;
MCLK_REGS->MCLK_AHBMASK |= MCLK_AHBMASK_GMAC_Msk;
GMAC_REGS->GMAC_NCFGR = GMAC_NCFGR_CLK(get_clock_rate(d)); // Set MDC divider
GMAC_REGS->GMAC_NCR = 0; // Disable RX & TX
GMAC_REGS->GMAC_NCR |= GMAC_NCR_MPE_Msk; // Enable MDC & MDIO
for (int i = 0; i < ETH_DESC_CNT; i++) { // Init TX descriptors
s_txdesc[i][0] = (uint32_t) s_txbuf[i]; // Point to data buffer
s_txdesc[i][1] = MG_BIT(31); // OWN bit
}
s_txdesc[ETH_DESC_CNT - 1][1] |= MG_BIT(30); // Last tx descriptor - wrap
GMAC_REGS->GMAC_DCFGR = GMAC_DCFGR_DRBS(0x18) // DMA recv buf 1536
| GMAC_DCFGR_RXBMS(GMAC_DCFGR_RXBMS_FULL_Val) |
GMAC_DCFGR_TXPBMS(1); // See #2487
for (int i = 0; i < ETH_DESC_CNT; i++) { // Init RX descriptors
s_rxdesc[i][0] = (uint32_t) s_rxbuf[i]; // Address of the data buffer
s_rxdesc[i][1] = 0; // Clear status
}
s_rxdesc[ETH_DESC_CNT - 1][0] |= MG_BIT(1); // Last rx descriptor - wrap
GMAC_REGS->GMAC_TBQB = (uint32_t) s_txdesc; // about the descriptor addresses
GMAC_REGS->GMAC_RBQB = (uint32_t) s_rxdesc; // Let the controller know
GMAC_REGS->SA[0].GMAC_SAB =
MG_U32(ifp->mac[3], ifp->mac[2], ifp->mac[1], ifp->mac[0]);
GMAC_REGS->SA[0].GMAC_SAT = MG_U32(0, 0, ifp->mac[5], ifp->mac[4]);
GMAC_REGS->GMAC_UR &= ~GMAC_UR_MII_Msk; // Disable MII, use RMII
GMAC_REGS->GMAC_NCFGR |= GMAC_NCFGR_MAXFS_Msk | GMAC_NCFGR_MTIHEN_Msk |
GMAC_NCFGR_EFRHD_Msk | GMAC_NCFGR_CAF_Msk;
GMAC_REGS->GMAC_TSR = GMAC_TSR_HRESP_Msk | GMAC_TSR_UND_Msk |
GMAC_TSR_TXCOMP_Msk | GMAC_TSR_TFC_Msk |
GMAC_TSR_TXGO_Msk | GMAC_TSR_RLE_Msk |
GMAC_TSR_COL_Msk | GMAC_TSR_UBR_Msk;
GMAC_REGS->GMAC_RSR = GMAC_RSR_HNO_Msk | GMAC_RSR_RXOVR_Msk |
GMAC_RSR_REC_Msk | GMAC_RSR_BNA_Msk;
GMAC_REGS->GMAC_IDR = ~0U; // Disable interrupts, then enable required
GMAC_REGS->GMAC_IER = GMAC_IER_HRESP_Msk | GMAC_IER_ROVR_Msk |
GMAC_IER_TCOMP_Msk | GMAC_IER_TFC_Msk |
GMAC_IER_RLEX_Msk | GMAC_IER_TUR_Msk |
GMAC_IER_RXUBR_Msk | GMAC_IER_RCOMP_Msk;
GMAC_REGS->GMAC_NCR |= GMAC_NCR_TXEN_Msk | GMAC_NCR_RXEN_Msk;
NVIC_EnableIRQ(GMAC_IRQn);
return true;
}
static size_t mg_tcpip_driver_same54_tx(const void *buf, size_t len,
struct mg_tcpip_if *ifp) {
if (len > sizeof(s_txbuf[s_txno])) {
MG_ERROR(("Frame too big, %ld", (long) len));
len = 0; // Frame is too big
} else if ((s_txdesc[s_txno][1] & MG_BIT(31)) == 0) {
ifp->nerr++;
MG_ERROR(("No free descriptors"));
len = 0; // All descriptors are busy, fail
} else {
uint32_t status = len | MG_BIT(15); // Frame length, last chunk
if (s_txno == ETH_DESC_CNT - 1) status |= MG_BIT(30); // wrap
memcpy(s_txbuf[s_txno], buf, len); // Copy data
s_txdesc[s_txno][1] = status;
if (++s_txno >= ETH_DESC_CNT) s_txno = 0;
}
__DSB(); // Ensure descriptors have been written
GMAC_REGS->GMAC_NCR |= GMAC_NCR_TSTART_Msk; // Enable transmission
return len;
}
static bool mg_tcpip_driver_same54_up(struct mg_tcpip_if *ifp) {
uint16_t bsr = eth_read_phy(MG_PHY_ADDR, MG_PHYREG_BSR);
bool up = bsr & MG_PHYREGBIT_BSR_LINK_STATUS ? 1 : 0;
// If PHY is ready, update NCFGR accordingly
if (ifp->state == MG_TCPIP_STATE_DOWN && up) {
uint16_t bcr = eth_read_phy(MG_PHY_ADDR, MG_PHYREG_BCR);
bool fd = bcr & MG_PHYREGBIT_BCR_DUPLEX_MODE ? 1 : 0;
bool spd = bcr & MG_PHYREGBIT_BCR_SPEED ? 1 : 0;
GMAC_REGS->GMAC_NCFGR = (GMAC_REGS->GMAC_NCFGR &
~(GMAC_NCFGR_SPD_Msk | MG_PHYREGBIT_BCR_SPEED)) |
GMAC_NCFGR_SPD(spd) | GMAC_NCFGR_FD(fd);
}
return up;
}
void GMAC_Handler(void);
void GMAC_Handler(void) {
uint32_t isr = GMAC_REGS->GMAC_ISR;
uint32_t rsr = GMAC_REGS->GMAC_RSR;
uint32_t tsr = GMAC_REGS->GMAC_TSR;
if (isr & GMAC_ISR_RCOMP_Msk) {
if (rsr & GMAC_ISR_RCOMP_Msk) {
for (uint8_t i = 0; i < ETH_DESC_CNT; i++) {
if ((s_rxdesc[s_rxno][0] & MG_BIT(0)) == 0) break;
size_t len = s_rxdesc[s_rxno][1] & (MG_BIT(13) - 1);
mg_tcpip_qwrite(s_rxbuf[s_rxno], len, s_ifp);
s_rxdesc[s_rxno][0] &= ~MG_BIT(0); // Disown
if (++s_rxno >= ETH_DESC_CNT) s_rxno = 0;
}
}
}
if ((tsr & (GMAC_TSR_HRESP_Msk | GMAC_TSR_UND_Msk | GMAC_TSR_TXCOMP_Msk |
GMAC_TSR_TFC_Msk | GMAC_TSR_TXGO_Msk | GMAC_TSR_RLE_Msk |
GMAC_TSR_COL_Msk | GMAC_TSR_UBR_Msk)) != 0) {
// MG_INFO((" --> %#x %#x", s_txdesc[s_txno][1], tsr));
if (!(s_txdesc[s_txno][1] & MG_BIT(31))) s_txdesc[s_txno][1] |= MG_BIT(31);
}
GMAC_REGS->GMAC_RSR = rsr;
GMAC_REGS->GMAC_TSR = tsr;
}
struct mg_tcpip_driver mg_tcpip_driver_same54 = {
mg_tcpip_driver_same54_init, mg_tcpip_driver_same54_tx, NULL,
mg_tcpip_driver_same54_up};
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/drivers/stm32f.c"
#endif
#if MG_ENABLE_TCPIP && defined(MG_ENABLE_DRIVER_STM32F) && \
MG_ENABLE_DRIVER_STM32F
struct stm32f_eth {
volatile uint32_t MACCR, MACFFR, MACHTHR, MACHTLR, MACMIIAR, MACMIIDR, MACFCR,
MACVLANTR, RESERVED0[2], MACRWUFFR, MACPMTCSR, RESERVED1, MACDBGR, MACSR,
MACIMR, MACA0HR, MACA0LR, MACA1HR, MACA1LR, MACA2HR, MACA2LR, MACA3HR,
MACA3LR, RESERVED2[40], MMCCR, MMCRIR, MMCTIR, MMCRIMR, MMCTIMR,
RESERVED3[14], MMCTGFSCCR, MMCTGFMSCCR, RESERVED4[5], MMCTGFCR,
RESERVED5[10], MMCRFCECR, MMCRFAECR, RESERVED6[10], MMCRGUFCR,
RESERVED7[334], PTPTSCR, PTPSSIR, PTPTSHR, PTPTSLR, PTPTSHUR, PTPTSLUR,
PTPTSAR, PTPTTHR, PTPTTLR, RESERVED8, PTPTSSR, PTPPPSCR, RESERVED9[564],
DMABMR, DMATPDR, DMARPDR, DMARDLAR, DMATDLAR, DMASR, DMAOMR, DMAIER,
DMAMFBOCR, DMARSWTR, RESERVED10[8], DMACHTDR, DMACHRDR, DMACHTBAR,
DMACHRBAR;
};
#undef ETH
#define ETH ((struct stm32f_eth *) (uintptr_t) 0x40028000)
#define ETH_PKT_SIZE 1540 // Max frame size
#define ETH_DESC_CNT 4 // Descriptors count
#define ETH_DS 4 // Descriptor size (words)
static uint32_t s_rxdesc[ETH_DESC_CNT][ETH_DS]; // RX descriptors
static uint32_t s_txdesc[ETH_DESC_CNT][ETH_DS]; // TX descriptors
static uint8_t s_rxbuf[ETH_DESC_CNT][ETH_PKT_SIZE]; // RX ethernet buffers
static uint8_t s_txbuf[ETH_DESC_CNT][ETH_PKT_SIZE]; // TX ethernet buffers
static uint8_t s_txno; // Current TX descriptor
static uint8_t s_rxno; // Current RX descriptor
static struct mg_tcpip_if *s_ifp; // MIP interface
enum {
MG_PHYREG_BCR = 0,
MG_PHYREG_BSR = 1,
MG_PHYREG_ID1 = 2,
MG_PHYREG_ID2 = 3,
MG_PHYREG_CSCR = 31
};
static uint32_t eth_read_phy(uint8_t addr, uint8_t reg) {
ETH->MACMIIAR &= (7 << 2);
ETH->MACMIIAR |= ((uint32_t) addr << 11) | ((uint32_t) reg << 6);
ETH->MACMIIAR |= MG_BIT(0);
while (ETH->MACMIIAR & MG_BIT(0)) (void) 0;
return ETH->MACMIIDR;
}
static void eth_write_phy(uint8_t addr, uint8_t reg, uint32_t val) {
ETH->MACMIIDR = val;
ETH->MACMIIAR &= (7 << 2);
ETH->MACMIIAR |= ((uint32_t) addr << 11) | ((uint32_t) reg << 6) | MG_BIT(1);
ETH->MACMIIAR |= MG_BIT(0);
while (ETH->MACMIIAR & MG_BIT(0)) (void) 0;
}
static uint32_t get_hclk(void) {
struct rcc {
volatile uint32_t CR, PLLCFGR, CFGR;
} *rcc = (struct rcc *) 0x40023800;
uint32_t clk = 0, hsi = 16000000 /* 16 MHz */, hse = 8000000 /* 8MHz */;
if (rcc->CFGR & (1 << 2)) {
clk = hse;
} else if (rcc->CFGR & (1 << 3)) {
uint32_t vco, m, n, p;
m = (rcc->PLLCFGR & (0x3f << 0)) >> 0;
n = (rcc->PLLCFGR & (0x1ff << 6)) >> 6;
p = (((rcc->PLLCFGR & (3 << 16)) >> 16) + 1) * 2;
clk = (rcc->PLLCFGR & (1 << 22)) ? hse : hsi;
vco = (uint32_t) ((uint64_t) clk * n / m);
clk = vco / p;
} else {
clk = hsi;
}
uint32_t hpre = (rcc->CFGR & (15 << 4)) >> 4;
if (hpre < 8) return clk;
uint8_t ahbptab[8] = {1, 2, 3, 4, 6, 7, 8, 9}; // log2(div)
return ((uint32_t) clk) >> ahbptab[hpre - 8];
}
// Guess CR from HCLK. MDC clock is generated from HCLK (AHB); as per 802.3,
// it must not exceed 2.5MHz As the AHB clock can be (and usually is) derived
// from the HSI (internal RC), and it can go above specs, the datasheets
// specify a range of frequencies and activate one of a series of dividers to
// keep the MDC clock safely below 2.5MHz. We guess a divider setting based on
// HCLK with a +5% drift. If the user uses a different clock from our
// defaults, needs to set the macros on top Valid for STM32F74xxx/75xxx
// (38.8.1) and STM32F42xxx/43xxx (33.8.1) (both 4.5% worst case drift)
static int guess_mdc_cr(void) {
uint8_t crs[] = {2, 3, 0, 1, 4, 5}; // ETH->MACMIIAR::CR values
uint8_t div[] = {16, 26, 42, 62, 102, 124}; // Respective HCLK dividers
uint32_t hclk = get_hclk(); // Guess system HCLK
int result = -1; // Invalid CR value
if (hclk < 25000000) {
MG_ERROR(("HCLK too low"));
} else {
for (int i = 0; i < 6; i++) {
if (hclk / div[i] <= 2375000UL /* 2.5MHz - 5% */) {
result = crs[i];
break;
}
}
if (result < 0) MG_ERROR(("HCLK too high"));
}
MG_DEBUG(("HCLK: %u, CR: %d", hclk, result));
return result;
}
static bool mg_tcpip_driver_stm32f_init(struct mg_tcpip_if *ifp) {
struct mg_tcpip_driver_stm32f_data *d =
(struct mg_tcpip_driver_stm32f_data *) ifp->driver_data;
uint8_t phy_addr = d == NULL ? 0 : d->phy_addr;
s_ifp = ifp;
// Init RX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
s_rxdesc[i][0] = MG_BIT(31); // Own
s_rxdesc[i][1] = sizeof(s_rxbuf[i]) | MG_BIT(14); // 2nd address chained
s_rxdesc[i][2] = (uint32_t) (uintptr_t) s_rxbuf[i]; // Point to data buffer
s_rxdesc[i][3] =
(uint32_t) (uintptr_t) s_rxdesc[(i + 1) % ETH_DESC_CNT]; // Chain
}
// Init TX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
s_txdesc[i][2] = (uint32_t) (uintptr_t) s_txbuf[i]; // Buf pointer
s_txdesc[i][3] =
(uint32_t) (uintptr_t) s_txdesc[(i + 1) % ETH_DESC_CNT]; // Chain
}
ETH->DMABMR |= MG_BIT(0); // Software reset
while ((ETH->DMABMR & MG_BIT(0)) != 0) (void) 0; // Wait until done
// Set MDC clock divider. If user told us the value, use it. Otherwise, guess
int cr = (d == NULL || d->mdc_cr < 0) ? guess_mdc_cr() : d->mdc_cr;
ETH->MACMIIAR = ((uint32_t) cr & 7) << 2;
// NOTE(cpq): we do not use extended descriptor bit 7, and do not use
// hardware checksum. Therefore, descriptor size is 4, not 8
// ETH->DMABMR = MG_BIT(13) | MG_BIT(16) | MG_BIT(22) | MG_BIT(23) |
// MG_BIT(25);
ETH->MACIMR = MG_BIT(3) | MG_BIT(9); // Mask timestamp & PMT IT
ETH->MACFCR = MG_BIT(7); // Disable zero quarta pause
// ETH->MACFFR = MG_BIT(31); // Receive all
eth_write_phy(phy_addr, MG_PHYREG_BCR, MG_BIT(15)); // Reset PHY
eth_write_phy(phy_addr, MG_PHYREG_BCR, MG_BIT(12)); // Set autonegotiation
ETH->DMARDLAR = (uint32_t) (uintptr_t) s_rxdesc; // RX descriptors
ETH->DMATDLAR = (uint32_t) (uintptr_t) s_txdesc; // RX descriptors
ETH->DMAIER = MG_BIT(6) | MG_BIT(16); // RIE, NISE
ETH->MACCR =
MG_BIT(2) | MG_BIT(3) | MG_BIT(11) | MG_BIT(14); // RE, TE, Duplex, Fast
ETH->DMAOMR =
MG_BIT(1) | MG_BIT(13) | MG_BIT(21) | MG_BIT(25); // SR, ST, TSF, RSF
MG_DEBUG(("PHY ID: %#04hx %#04hx", eth_read_phy(phy_addr, MG_PHYREG_ID1),
eth_read_phy(phy_addr, MG_PHYREG_ID2)));
// MAC address filtering
ETH->MACA0HR = ((uint32_t) ifp->mac[5] << 8U) | ifp->mac[4];
ETH->MACA0LR = (uint32_t) (ifp->mac[3] << 24) |
((uint32_t) ifp->mac[2] << 16) |
((uint32_t) ifp->mac[1] << 8) | ifp->mac[0];
return true;
}
static size_t mg_tcpip_driver_stm32f_tx(const void *buf, size_t len,
struct mg_tcpip_if *ifp) {
if (len > sizeof(s_txbuf[s_txno])) {
MG_ERROR(("Frame too big, %ld", (long) len));
len = 0; // Frame is too big
} else if ((s_txdesc[s_txno][0] & MG_BIT(31))) {
ifp->nerr++;
MG_ERROR(("No free descriptors"));
// printf("D0 %lx SR %lx\n", (long) s_txdesc[0][0], (long) ETH->DMASR);
len = 0; // All descriptors are busy, fail
} else {
memcpy(s_txbuf[s_txno], buf, len); // Copy data
s_txdesc[s_txno][1] = (uint32_t) len; // Set data len
s_txdesc[s_txno][0] = MG_BIT(20) | MG_BIT(28) | MG_BIT(29); // Chain,FS,LS
s_txdesc[s_txno][0] |= MG_BIT(31); // Set OWN bit - let DMA take over
if (++s_txno >= ETH_DESC_CNT) s_txno = 0;
}
MG_DSB(); // ensure descriptors have been written
ETH->DMASR = MG_BIT(2) | MG_BIT(5); // Clear any prior TBUS/TUS
ETH->DMATPDR = 0; // and resume
return len;
}
static bool mg_tcpip_driver_stm32f_up(struct mg_tcpip_if *ifp) {
struct mg_tcpip_driver_stm32f_data *d =
(struct mg_tcpip_driver_stm32f_data *) ifp->driver_data;
uint8_t phy_addr = d == NULL ? 0 : d->phy_addr;
uint32_t bsr = eth_read_phy(phy_addr, MG_PHYREG_BSR);
bool up = bsr & MG_BIT(2) ? 1 : 0;
if ((ifp->state == MG_TCPIP_STATE_DOWN) && up) { // link state just went up
uint32_t scsr = eth_read_phy(phy_addr, MG_PHYREG_CSCR);
// tmp = reg with flags set to the most likely situation: 100M full-duplex
// if(link is slow or half) set flags otherwise
// reg = tmp
uint32_t maccr = ETH->MACCR | MG_BIT(14) | MG_BIT(11); // 100M, Full-duplex
if ((scsr & MG_BIT(3)) == 0) maccr &= ~MG_BIT(14); // 10M
if ((scsr & MG_BIT(4)) == 0) maccr &= ~MG_BIT(11); // Half-duplex
ETH->MACCR = maccr; // IRQ handler does not fiddle with this register
MG_DEBUG(("Link is %uM %s-duplex", maccr & MG_BIT(14) ? 100 : 10,
maccr & MG_BIT(11) ? "full" : "half"));
}
return up;
}
#ifdef __riscv
__attribute__((interrupt())) // For RISCV CH32V307, which share the same MAC
#endif
void ETH_IRQHandler(void);
void ETH_IRQHandler(void) {
if (ETH->DMASR & MG_BIT(6)) { // Frame received, loop
ETH->DMASR = MG_BIT(16) | MG_BIT(6); // Clear flag
for (uint32_t i = 0; i < 10; i++) { // read as they arrive but not forever
if (s_rxdesc[s_rxno][0] & MG_BIT(31)) break; // exit when done
if (((s_rxdesc[s_rxno][0] & (MG_BIT(8) | MG_BIT(9))) ==
(MG_BIT(8) | MG_BIT(9))) &&
!(s_rxdesc[s_rxno][0] & MG_BIT(15))) { // skip partial/errored frames
uint32_t len = ((s_rxdesc[s_rxno][0] >> 16) & (MG_BIT(14) - 1));
// printf("%lx %lu %lx %.8lx\n", s_rxno, len, s_rxdesc[s_rxno][0],
// ETH->DMASR);
mg_tcpip_qwrite(s_rxbuf[s_rxno], len > 4 ? len - 4 : len, s_ifp);
}
s_rxdesc[s_rxno][0] = MG_BIT(31);
if (++s_rxno >= ETH_DESC_CNT) s_rxno = 0;
}
}
// Cleanup flags
ETH->DMASR = MG_BIT(16) // NIS, normal interrupt summary
| MG_BIT(7); // Clear possible RBUS while processing
ETH->DMARPDR = 0; // and resume RX
}
struct mg_tcpip_driver mg_tcpip_driver_stm32f = {
mg_tcpip_driver_stm32f_init, mg_tcpip_driver_stm32f_tx, NULL,
mg_tcpip_driver_stm32f_up};
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/drivers/stm32h.c"
#endif
#if MG_ENABLE_TCPIP && defined(MG_ENABLE_DRIVER_STM32H) && \
MG_ENABLE_DRIVER_STM32H
struct stm32h_eth {
volatile uint32_t MACCR, MACECR, MACPFR, MACWTR, MACHT0R, MACHT1R,
RESERVED1[14], MACVTR, RESERVED2, MACVHTR, RESERVED3, MACVIR, MACIVIR,
RESERVED4[2], MACTFCR, RESERVED5[7], MACRFCR, RESERVED6[7], MACISR,
MACIER, MACRXTXSR, RESERVED7, MACPCSR, MACRWKPFR, RESERVED8[2], MACLCSR,
MACLTCR, MACLETR, MAC1USTCR, RESERVED9[12], MACVR, MACDR, RESERVED10,
MACHWF0R, MACHWF1R, MACHWF2R, RESERVED11[54], MACMDIOAR, MACMDIODR,
RESERVED12[2], MACARPAR, RESERVED13[59], MACA0HR, MACA0LR, MACA1HR,
MACA1LR, MACA2HR, MACA2LR, MACA3HR, MACA3LR, RESERVED14[248], MMCCR,
MMCRIR, MMCTIR, MMCRIMR, MMCTIMR, RESERVED15[14], MMCTSCGPR, MMCTMCGPR,
RESERVED16[5], MMCTPCGR, RESERVED17[10], MMCRCRCEPR, MMCRAEPR,
RESERVED18[10], MMCRUPGR, RESERVED19[9], MMCTLPIMSTR, MMCTLPITCR,
MMCRLPIMSTR, MMCRLPITCR, RESERVED20[65], MACL3L4C0R, MACL4A0R,
RESERVED21[2], MACL3A0R0R, MACL3A1R0R, MACL3A2R0R, MACL3A3R0R,
RESERVED22[4], MACL3L4C1R, MACL4A1R, RESERVED23[2], MACL3A0R1R,
MACL3A1R1R, MACL3A2R1R, MACL3A3R1R, RESERVED24[108], MACTSCR, MACSSIR,
MACSTSR, MACSTNR, MACSTSUR, MACSTNUR, MACTSAR, RESERVED25, MACTSSR,
RESERVED26[3], MACTTSSNR, MACTTSSSR, RESERVED27[2], MACACR, RESERVED28,
MACATSNR, MACATSSR, MACTSIACR, MACTSEACR, MACTSICNR, MACTSECNR,
RESERVED29[4], MACPPSCR, RESERVED30[3], MACPPSTTSR, MACPPSTTNR, MACPPSIR,
MACPPSWR, RESERVED31[12], MACPOCR, MACSPI0R, MACSPI1R, MACSPI2R, MACLMIR,
RESERVED32[11], MTLOMR, RESERVED33[7], MTLISR, RESERVED34[55], MTLTQOMR,
MTLTQUR, MTLTQDR, RESERVED35[8], MTLQICSR, MTLRQOMR, MTLRQMPOCR, MTLRQDR,
RESERVED36[177], DMAMR, DMASBMR, DMAISR, DMADSR, RESERVED37[60], DMACCR,
DMACTCR, DMACRCR, RESERVED38[2], DMACTDLAR, RESERVED39, DMACRDLAR,
DMACTDTPR, RESERVED40, DMACRDTPR, DMACTDRLR, DMACRDRLR, DMACIER,
DMACRIWTR, DMACSFCSR, RESERVED41, DMACCATDR, RESERVED42, DMACCARDR,
RESERVED43, DMACCATBR, RESERVED44, DMACCARBR, DMACSR, RESERVED45[2],
DMACMFCR;
};
#undef ETH
#define ETH \
((struct stm32h_eth *) (uintptr_t) (0x40000000UL + 0x00020000UL + 0x8000UL))
#define ETH_PKT_SIZE 1540 // Max frame size
#define ETH_DESC_CNT 4 // Descriptors count
#define ETH_DS 4 // Descriptor size (words)
static volatile uint32_t s_rxdesc[ETH_DESC_CNT][ETH_DS]; // RX descriptors
static volatile uint32_t s_txdesc[ETH_DESC_CNT][ETH_DS]; // TX descriptors
static uint8_t s_rxbuf[ETH_DESC_CNT][ETH_PKT_SIZE]; // RX ethernet buffers
static uint8_t s_txbuf[ETH_DESC_CNT][ETH_PKT_SIZE]; // TX ethernet buffers
static struct mg_tcpip_if *s_ifp; // MIP interface
enum {
MG_PHY_ADDR = 0,
MG_PHYREG_BCR = 0,
MG_PHYREG_BSR = 1,
MG_PHYREG_CSCR = 31
}; // PHY constants
static uint32_t eth_read_phy(uint8_t addr, uint8_t reg) {
ETH->MACMDIOAR &= (0xF << 8);
ETH->MACMDIOAR |= ((uint32_t) addr << 21) | ((uint32_t) reg << 16) | 3 << 2;
ETH->MACMDIOAR |= MG_BIT(0);
while (ETH->MACMDIOAR & MG_BIT(0)) (void) 0;
return ETH->MACMDIODR;
}
static void eth_write_phy(uint8_t addr, uint8_t reg, uint32_t val) {
ETH->MACMDIODR = val;
ETH->MACMDIOAR &= (0xF << 8);
ETH->MACMDIOAR |= ((uint32_t) addr << 21) | ((uint32_t) reg << 16) | 1 << 2;
ETH->MACMDIOAR |= MG_BIT(0);
while (ETH->MACMDIOAR & MG_BIT(0)) (void) 0;
}
static uint32_t get_hclk(void) {
struct rcc {
volatile uint32_t CR, HSICFGR, CRRCR, CSICFGR, CFGR, RESERVED1, D1CFGR,
D2CFGR, D3CFGR, RESERVED2, PLLCKSELR, PLLCFGR, PLL1DIVR, PLL1FRACR,
PLL2DIVR, PLL2FRACR, PLL3DIVR, PLL3FRACR, RESERVED3, D1CCIPR, D2CCIP1R,
D2CCIP2R, D3CCIPR, RESERVED4, CIER, CIFR, CICR, RESERVED5, BDCR, CSR,
RESERVED6, AHB3RSTR, AHB1RSTR, AHB2RSTR, AHB4RSTR, APB3RSTR, APB1LRSTR,
APB1HRSTR, APB2RSTR, APB4RSTR, GCR, RESERVED8, D3AMR, RESERVED11[9],
RSR, AHB3ENR, AHB1ENR, AHB2ENR, AHB4ENR, APB3ENR, APB1LENR, APB1HENR,
APB2ENR, APB4ENR, RESERVED12, AHB3LPENR, AHB1LPENR, AHB2LPENR,
AHB4LPENR, APB3LPENR, APB1LLPENR, APB1HLPENR, APB2LPENR, APB4LPENR,
RESERVED13[4];
} *rcc = ((struct rcc *) (0x40000000 + 0x18020000 + 0x4400));
uint32_t clk = 0, hsi = 64000000 /* 64 MHz */, hse = 8000000 /* 8MHz */,
csi = 4000000 /* 4MHz */;
unsigned int sel = (rcc->CFGR & (7 << 3)) >> 3;
if (sel == 1) {
clk = csi;
} else if (sel == 2) {
clk = hse;
} else if (sel == 3) {
uint32_t vco, m, n, p;
unsigned int src = (rcc->PLLCKSELR & (3 << 0)) >> 0;
m = ((rcc->PLLCKSELR & (0x3F << 4)) >> 4);
n = ((rcc->PLL1DIVR & (0x1FF << 0)) >> 0) + 1 +
((rcc->PLLCFGR & MG_BIT(0)) ? 1 : 0); // round-up in fractional mode
p = ((rcc->PLL1DIVR & (0x7F << 9)) >> 9) + 1;
if (src == 1) {
clk = csi;
} else if (src == 2) {
clk = hse;
} else {
clk = hsi;
clk >>= ((rcc->CR & 3) >> 3);
}
vco = (uint32_t) ((uint64_t) clk * n / m);
clk = vco / p;
} else {
clk = hsi;
clk >>= ((rcc->CR & 3) >> 3);
}
const uint8_t cptab[12] = {1, 2, 3, 4, 6, 7, 8, 9}; // log2(div)
uint32_t d1cpre = (rcc->D1CFGR & (0x0F << 8)) >> 8;
if (d1cpre >= 8) clk >>= cptab[d1cpre - 8];
MG_DEBUG(("D1 CLK: %u", clk));
uint32_t hpre = (rcc->D1CFGR & (0x0F << 0)) >> 0;
if (hpre < 8) return clk;
return ((uint32_t) clk) >> cptab[hpre - 8];
}
// Guess CR from AHB1 clock. MDC clock is generated from the ETH peripheral
// clock (AHB1); as per 802.3, it must not exceed 2. As the AHB clock can
// be derived from HSI or CSI (internal RC) clocks, and those can go above
// specs, the datasheets specify a range of frequencies and activate one of a
// series of dividers to keep the MDC clock safely below 2.5MHz. We guess a
// divider setting based on HCLK with some drift. If the user uses a different
// clock from our defaults, needs to set the macros on top. Valid for
// STM32H74xxx/75xxx (58.11.4)(4.5% worst case drift)(CSI clock has a 7.5 %
// worst case drift @ max temp)
static int guess_mdc_cr(void) {
const uint8_t crs[] = {2, 3, 0, 1, 4, 5}; // ETH->MACMDIOAR::CR values
const uint8_t div[] = {16, 26, 42, 62, 102, 124}; // Respective HCLK dividers
uint32_t hclk = get_hclk(); // Guess system HCLK
int result = -1; // Invalid CR value
for (int i = 0; i < 6; i++) {
if (hclk / div[i] <= 2375000UL /* 2.5MHz - 5% */) {
result = crs[i];
break;
}
}
if (result < 0) MG_ERROR(("HCLK too high"));
MG_DEBUG(("HCLK: %u, CR: %d", hclk, result));
return result;
}
static bool mg_tcpip_driver_stm32h_init(struct mg_tcpip_if *ifp) {
struct mg_tcpip_driver_stm32h_data *d =
(struct mg_tcpip_driver_stm32h_data *) ifp->driver_data;
s_ifp = ifp;
// Init RX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
s_rxdesc[i][0] = (uint32_t) (uintptr_t) s_rxbuf[i]; // Point to data buffer
s_rxdesc[i][3] = MG_BIT(31) | MG_BIT(30) | MG_BIT(24); // OWN, IOC, BUF1V
}
// Init TX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
s_txdesc[i][0] = (uint32_t) (uintptr_t) s_txbuf[i]; // Buf pointer
}
ETH->DMAMR |= MG_BIT(0); // Software reset
while ((ETH->DMAMR & MG_BIT(0)) != 0) (void) 0; // Wait until done
// Set MDC clock divider. If user told us the value, use it. Otherwise, guess
int cr = (d == NULL || d->mdc_cr < 0) ? guess_mdc_cr() : d->mdc_cr;
ETH->MACMDIOAR = ((uint32_t) cr & 0xF) << 8;
// NOTE(scaprile): We do not use timing facilities so the DMA engine does not
// re-write buffer address
ETH->DMAMR = 0 << 16; // use interrupt mode 0 (58.8.1) (reset value)
ETH->DMASBMR |= MG_BIT(12); // AAL NOTE(scaprile): is this actually needed
ETH->MACIER = 0; // Do not enable additional irq sources (reset value)
ETH->MACTFCR = MG_BIT(7); // Disable zero-quanta pause
// ETH->MACPFR = MG_BIT(31); // Receive all
eth_write_phy(MG_PHY_ADDR, MG_PHYREG_BCR, MG_BIT(15)); // Reset PHY
eth_write_phy(MG_PHY_ADDR, MG_PHYREG_BCR,
MG_BIT(12)); // Set autonegotiation
ETH->DMACRDLAR =
(uint32_t) (uintptr_t) s_rxdesc; // RX descriptors start address
ETH->DMACRDRLR = ETH_DESC_CNT - 1; // ring length
ETH->DMACRDTPR =
(uint32_t) (uintptr_t) &s_rxdesc[ETH_DESC_CNT -
1]; // last valid descriptor address
ETH->DMACTDLAR =
(uint32_t) (uintptr_t) s_txdesc; // TX descriptors start address
ETH->DMACTDRLR = ETH_DESC_CNT - 1; // ring length
ETH->DMACTDTPR =
(uint32_t) (uintptr_t) s_txdesc; // first available descriptor address
ETH->DMACCR = 0; // DSL = 0 (contiguous descriptor table) (reset value)
ETH->DMACIER = MG_BIT(6) | MG_BIT(15); // RIE, NIE
ETH->MACCR = MG_BIT(0) | MG_BIT(1) | MG_BIT(13) | MG_BIT(14) |
MG_BIT(15); // RE, TE, Duplex, Fast, Reserved
ETH->MTLTQOMR |= MG_BIT(1); // TSF
ETH->MTLRQOMR |= MG_BIT(5); // RSF
ETH->DMACTCR |= MG_BIT(0); // ST
ETH->DMACRCR |= MG_BIT(0); // SR
// MAC address filtering
ETH->MACA0HR = ((uint32_t) ifp->mac[5] << 8U) | ifp->mac[4];
ETH->MACA0LR = (uint32_t) (ifp->mac[3] << 24) |
((uint32_t) ifp->mac[2] << 16) |
((uint32_t) ifp->mac[1] << 8) | ifp->mac[0];
return true;
}
static uint32_t s_txno;
static size_t mg_tcpip_driver_stm32h_tx(const void *buf, size_t len,
struct mg_tcpip_if *ifp) {
if (len > sizeof(s_txbuf[s_txno])) {
MG_ERROR(("Frame too big, %ld", (long) len));
len = 0; // Frame is too big
} else if ((s_txdesc[s_txno][3] & MG_BIT(31))) {
ifp->nerr++;
MG_ERROR(("No free descriptors: %u %08X %08X %08X", s_txno,
s_txdesc[s_txno][3], ETH->DMACSR, ETH->DMACTCR));
for (int i = 0; i < ETH_DESC_CNT; i++) MG_ERROR(("%08X", s_txdesc[i][3]));
len = 0; // All descriptors are busy, fail
} else {
memcpy(s_txbuf[s_txno], buf, len); // Copy data
s_txdesc[s_txno][2] = (uint32_t) len; // Set data len
s_txdesc[s_txno][3] = MG_BIT(28) | MG_BIT(29); // FD, LD
s_txdesc[s_txno][3] |= MG_BIT(31); // Set OWN bit - let DMA take over
if (++s_txno >= ETH_DESC_CNT) s_txno = 0;
}
ETH->DMACSR |= MG_BIT(2) | MG_BIT(1); // Clear any prior TBU, TPS
ETH->DMACTDTPR = (uint32_t) (uintptr_t) &s_txdesc[s_txno]; // and resume
return len;
(void) ifp;
}
static bool mg_tcpip_driver_stm32h_up(struct mg_tcpip_if *ifp) {
uint32_t bsr = eth_read_phy(MG_PHY_ADDR, MG_PHYREG_BSR);
bool up = bsr & MG_BIT(2) ? 1 : 0;
if ((ifp->state == MG_TCPIP_STATE_DOWN) && up) { // link state just went up
uint32_t scsr = eth_read_phy(MG_PHY_ADDR, MG_PHYREG_CSCR);
// tmp = reg with flags set to the most likely situation: 100M full-duplex
// if(link is slow or half) set flags otherwise
// reg = tmp
uint32_t maccr = ETH->MACCR | MG_BIT(14) | MG_BIT(13); // 100M, Full-duplex
if ((scsr & MG_BIT(3)) == 0) maccr &= ~MG_BIT(14); // 10M
if ((scsr & MG_BIT(4)) == 0) maccr &= ~MG_BIT(13); // Half-duplex
ETH->MACCR = maccr; // IRQ handler does not fiddle with this register
MG_DEBUG(("Link is %uM %s-duplex", maccr & MG_BIT(14) ? 100 : 10,
maccr & MG_BIT(13) ? "full" : "half"));
}
return up;
}
void ETH_IRQHandler(void);
static uint32_t s_rxno;
void ETH_IRQHandler(void) {
if (ETH->DMACSR & MG_BIT(6)) { // Frame received, loop
ETH->DMACSR = MG_BIT(15) | MG_BIT(6); // Clear flag
for (uint32_t i = 0; i < 10; i++) { // read as they arrive but not forever
if (s_rxdesc[s_rxno][3] & MG_BIT(31)) break; // exit when done
if (((s_rxdesc[s_rxno][3] & (MG_BIT(28) | MG_BIT(29))) ==
(MG_BIT(28) | MG_BIT(29))) &&
!(s_rxdesc[s_rxno][3] & MG_BIT(15))) { // skip partial/errored frames
uint32_t len = s_rxdesc[s_rxno][3] & (MG_BIT(15) - 1);
// MG_DEBUG(("%lx %lu %lx %08lx", s_rxno, len, s_rxdesc[s_rxno][3],
// ETH->DMACSR));
mg_tcpip_qwrite(s_rxbuf[s_rxno], len > 4 ? len - 4 : len, s_ifp);
}
s_rxdesc[s_rxno][3] =
MG_BIT(31) | MG_BIT(30) | MG_BIT(24); // OWN, IOC, BUF1V
if (++s_rxno >= ETH_DESC_CNT) s_rxno = 0;
}
}
ETH->DMACSR =
MG_BIT(7) | MG_BIT(8); // Clear possible RBU RPS while processing
ETH->DMACRDTPR =
(uint32_t) (uintptr_t) &s_rxdesc[ETH_DESC_CNT - 1]; // and resume RX
}
struct mg_tcpip_driver mg_tcpip_driver_stm32h = {
mg_tcpip_driver_stm32h_init, mg_tcpip_driver_stm32h_tx, NULL,
mg_tcpip_driver_stm32h_up};
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/drivers/tm4c.c"
#endif
#if MG_ENABLE_TCPIP && defined(MG_ENABLE_DRIVER_TM4C) && MG_ENABLE_DRIVER_TM4C
struct tm4c_emac {
volatile uint32_t EMACCFG, EMACFRAMEFLTR, EMACHASHTBLH, EMACHASHTBLL,
EMACMIIADDR, EMACMIIDATA, EMACFLOWCTL, EMACVLANTG, RESERVED0, EMACSTATUS,
EMACRWUFF, EMACPMTCTLSTAT, RESERVED1[2], EMACRIS, EMACIM, EMACADDR0H,
EMACADDR0L, EMACADDR1H, EMACADDR1L, EMACADDR2H, EMACADDR2L, EMACADDR3H,
EMACADDR3L, RESERVED2[31], EMACWDOGTO, RESERVED3[8], EMACMMCCTRL,
EMACMMCRXRIS, EMACMMCTXRIS, EMACMMCRXIM, EMACMMCTXIM, RESERVED4,
EMACTXCNTGB, RESERVED5[12], EMACTXCNTSCOL, EMACTXCNTMCOL, RESERVED6[4],
EMACTXOCTCNTG, RESERVED7[6], EMACRXCNTGB, RESERVED8[4], EMACRXCNTCRCERR,
EMACRXCNTALGNERR, RESERVED9[10], EMACRXCNTGUNI, RESERVED10[239],
EMACVLNINCREP, EMACVLANHASH, RESERVED11[93], EMACTIMSTCTRL, EMACSUBSECINC,
EMACTIMSEC, EMACTIMNANO, EMACTIMSECU, EMACTIMNANOU, EMACTIMADD,
EMACTARGSEC, EMACTARGNANO, EMACHWORDSEC, EMACTIMSTAT, EMACPPSCTRL,
RESERVED12[12], EMACPPS0INTVL, EMACPPS0WIDTH, RESERVED13[294],
EMACDMABUSMOD, EMACTXPOLLD, EMACRXPOLLD, EMACRXDLADDR, EMACTXDLADDR,
EMACDMARIS, EMACDMAOPMODE, EMACDMAIM, EMACMFBOC, EMACRXINTWDT,
RESERVED14[8], EMACHOSTXDESC, EMACHOSRXDESC, EMACHOSTXBA, EMACHOSRXBA,
RESERVED15[218], EMACPP, EMACPC, EMACCC, RESERVED16, EMACEPHYRIS,
EMACEPHYIM, EMACEPHYIMSC;
};
#undef EMAC
#define EMAC ((struct tm4c_emac *) (uintptr_t) 0x400EC000)
#define ETH_PKT_SIZE 1540 // Max frame size
#define ETH_DESC_CNT 4 // Descriptors count
#define ETH_DS 4 // Descriptor size (words)
static uint32_t s_rxdesc[ETH_DESC_CNT][ETH_DS]; // RX descriptors
static uint32_t s_txdesc[ETH_DESC_CNT][ETH_DS]; // TX descriptors
static uint8_t s_rxbuf[ETH_DESC_CNT][ETH_PKT_SIZE]; // RX ethernet buffers
static uint8_t s_txbuf[ETH_DESC_CNT][ETH_PKT_SIZE]; // TX ethernet buffers
static struct mg_tcpip_if *s_ifp; // MIP interface
enum {
EPHY_ADDR = 0,
EPHYBMCR = 0,
EPHYBMSR = 1,
EPHYSTS = 16
}; // PHY constants
static inline void tm4cspin(volatile uint32_t count) {
while (count--) (void) 0;
}
static uint32_t emac_read_phy(uint8_t addr, uint8_t reg) {
EMAC->EMACMIIADDR &= (0xf << 2);
EMAC->EMACMIIADDR |= ((uint32_t) addr << 11) | ((uint32_t) reg << 6);
EMAC->EMACMIIADDR |= MG_BIT(0);
while (EMAC->EMACMIIADDR & MG_BIT(0)) tm4cspin(1);
return EMAC->EMACMIIDATA;
}
static void emac_write_phy(uint8_t addr, uint8_t reg, uint32_t val) {
EMAC->EMACMIIDATA = val;
EMAC->EMACMIIADDR &= (0xf << 2);
EMAC->EMACMIIADDR |= ((uint32_t) addr << 11) | ((uint32_t) reg << 6) | MG_BIT(1);
EMAC->EMACMIIADDR |= MG_BIT(0);
while (EMAC->EMACMIIADDR & MG_BIT(0)) tm4cspin(1);
}
static uint32_t get_sysclk(void) {
struct sysctl {
volatile uint32_t DONTCARE0[44], RSCLKCFG, DONTCARE1[43], PLLFREQ0,
PLLFREQ1;
} *sysctl = (struct sysctl *) 0x400FE000;
uint32_t clk = 0, piosc = 16000000 /* 16 MHz */, mosc = 25000000 /* 25MHz */;
if (sysctl->RSCLKCFG & (1 << 28)) { // USEPLL
uint32_t fin, vco, mdiv, n, q, psysdiv;
uint32_t pllsrc = (sysctl->RSCLKCFG & (0xf << 24)) >> 24;
if (pllsrc == 0) {
clk = piosc;
} else if (pllsrc == 3) {
clk = mosc;
} else {
MG_ERROR(("Unsupported clock source"));
}
q = (sysctl->PLLFREQ1 & (0x1f << 8)) >> 8;
n = (sysctl->PLLFREQ1 & (0x1f << 0)) >> 0;
fin = clk / ((q + 1) * (n + 1));
mdiv = (sysctl->PLLFREQ0 & (0x3ff << 0)) >>
0; // mint + (mfrac / 1024); MFRAC not supported
psysdiv = (sysctl->RSCLKCFG & (0x3f << 0)) >> 0;
vco = (uint32_t) ((uint64_t) fin * mdiv);
return vco / (psysdiv + 1);
}
uint32_t oscsrc = (sysctl->RSCLKCFG & (0xf << 20)) >> 20;
if (oscsrc == 0) {
clk = piosc;
} else if (oscsrc == 3) {
clk = mosc;
} else {
MG_ERROR(("Unsupported clock source"));
}
uint32_t osysdiv = (sysctl->RSCLKCFG & (0xf << 16)) >> 16;
return clk / (osysdiv + 1);
}
// Guess CR from SYSCLK. MDC clock is generated from SYSCLK (AHB); as per
// 802.3, it must not exceed 2.5MHz (also 20.4.2.6) As the AHB clock can be
// derived from the PIOSC (internal RC), and it can go above specs, the
// datasheets specify a range of frequencies and activate one of a series of
// dividers to keep the MDC clock safely below 2.5MHz. We guess a divider
// setting based on SYSCLK with a +5% drift. If the user uses a different clock
// from our defaults, needs to set the macros on top Valid for TM4C129x (20.7)
// (4.5% worst case drift)
// The PHY receives the main oscillator (MOSC) (20.3.1)
static int guess_mdc_cr(void) {
uint8_t crs[] = {2, 3, 0, 1}; // EMAC->MACMIIAR::CR values
uint8_t div[] = {16, 26, 42, 62}; // Respective HCLK dividers
uint32_t sysclk = get_sysclk(); // Guess system SYSCLK
int result = -1; // Invalid CR value
if (sysclk < 25000000) {
MG_ERROR(("SYSCLK too low"));
} else {
for (int i = 0; i < 4; i++) {
if (sysclk / div[i] <= 2375000UL /* 2.5MHz - 5% */) {
result = crs[i];
break;
}
}
if (result < 0) MG_ERROR(("SYSCLK too high"));
}
MG_DEBUG(("SYSCLK: %u, CR: %d", sysclk, result));
return result;
}
static bool mg_tcpip_driver_tm4c_init(struct mg_tcpip_if *ifp) {
struct mg_tcpip_driver_tm4c_data *d =
(struct mg_tcpip_driver_tm4c_data *) ifp->driver_data;
s_ifp = ifp;
// Init RX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
s_rxdesc[i][0] = MG_BIT(31); // Own
s_rxdesc[i][1] = sizeof(s_rxbuf[i]) | MG_BIT(14); // 2nd address chained
s_rxdesc[i][2] = (uint32_t) (uintptr_t) s_rxbuf[i]; // Point to data buffer
s_rxdesc[i][3] =
(uint32_t) (uintptr_t) s_rxdesc[(i + 1) % ETH_DESC_CNT]; // Chain
// MG_DEBUG(("%d %p", i, s_rxdesc[i]));
}
// Init TX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
s_txdesc[i][2] = (uint32_t) (uintptr_t) s_txbuf[i]; // Buf pointer
s_txdesc[i][3] =
(uint32_t) (uintptr_t) s_txdesc[(i + 1) % ETH_DESC_CNT]; // Chain
}
EMAC->EMACDMABUSMOD |= MG_BIT(0); // Software reset
while ((EMAC->EMACDMABUSMOD & MG_BIT(0)) != 0) tm4cspin(1); // Wait until done
// Set MDC clock divider. If user told us the value, use it. Otherwise, guess
int cr = (d == NULL || d->mdc_cr < 0) ? guess_mdc_cr() : d->mdc_cr;
EMAC->EMACMIIADDR = ((uint32_t) cr & 0xf) << 2;
// NOTE(cpq): we do not use extended descriptor bit 7, and do not use
// hardware checksum. Therefore, descriptor size is 4, not 8
// EMAC->EMACDMABUSMOD = MG_BIT(13) | MG_BIT(16) | MG_BIT(22) | MG_BIT(23) | MG_BIT(25);
EMAC->EMACIM = MG_BIT(3) | MG_BIT(9); // Mask timestamp & PMT IT
EMAC->EMACFLOWCTL = MG_BIT(7); // Disable zero-quanta pause
// EMAC->EMACFRAMEFLTR = MG_BIT(31); // Receive all
// EMAC->EMACPC defaults to internal PHY (EPHY) in MMI mode
emac_write_phy(EPHY_ADDR, EPHYBMCR, MG_BIT(15)); // Reset internal PHY (EPHY)
emac_write_phy(EPHY_ADDR, EPHYBMCR, MG_BIT(12)); // Set autonegotiation
EMAC->EMACRXDLADDR = (uint32_t) (uintptr_t) s_rxdesc; // RX descriptors
EMAC->EMACTXDLADDR = (uint32_t) (uintptr_t) s_txdesc; // TX descriptors
EMAC->EMACDMAIM = MG_BIT(6) | MG_BIT(16); // RIE, NIE
EMAC->EMACCFG = MG_BIT(2) | MG_BIT(3) | MG_BIT(11) | MG_BIT(14); // RE, TE, Duplex, Fast
EMAC->EMACDMAOPMODE =
MG_BIT(1) | MG_BIT(13) | MG_BIT(21) | MG_BIT(25); // SR, ST, TSF, RSF
EMAC->EMACADDR0H = ((uint32_t) ifp->mac[5] << 8U) | ifp->mac[4];
EMAC->EMACADDR0L = (uint32_t) (ifp->mac[3] << 24) |
((uint32_t) ifp->mac[2] << 16) |
((uint32_t) ifp->mac[1] << 8) | ifp->mac[0];
// NOTE(scaprile) There are 3 additional slots for filtering, disabled by
// default. This also applies to the STM32 driver (at least for F7)
return true;
}
static uint32_t s_txno;
static size_t mg_tcpip_driver_tm4c_tx(const void *buf, size_t len,
struct mg_tcpip_if *ifp) {
if (len > sizeof(s_txbuf[s_txno])) {
MG_ERROR(("Frame too big, %ld", (long) len));
len = 0; // fail
} else if ((s_txdesc[s_txno][0] & MG_BIT(31))) {
ifp->nerr++;
MG_ERROR(("No descriptors available"));
// printf("D0 %lx SR %lx\n", (long) s_txdesc[0][0], (long)
// EMAC->EMACDMARIS);
len = 0; // fail
} else {
memcpy(s_txbuf[s_txno], buf, len); // Copy data
s_txdesc[s_txno][1] = (uint32_t) len; // Set data len
s_txdesc[s_txno][0] =
MG_BIT(20) | MG_BIT(28) | MG_BIT(29) | MG_BIT(30); // Chain,FS,LS,IC
s_txdesc[s_txno][0] |= MG_BIT(31); // Set OWN bit - let DMA take over
if (++s_txno >= ETH_DESC_CNT) s_txno = 0;
}
EMAC->EMACDMARIS = MG_BIT(2) | MG_BIT(5); // Clear any prior TU/UNF
EMAC->EMACTXPOLLD = 0; // and resume
return len;
(void) ifp;
}
static bool mg_tcpip_driver_tm4c_up(struct mg_tcpip_if *ifp) {
uint32_t bmsr = emac_read_phy(EPHY_ADDR, EPHYBMSR);
bool up = (bmsr & MG_BIT(2)) ? 1 : 0;
if ((ifp->state == MG_TCPIP_STATE_DOWN) && up) { // link state just went up
uint32_t sts = emac_read_phy(EPHY_ADDR, EPHYSTS);
// tmp = reg with flags set to the most likely situation: 100M full-duplex
// if(link is slow or half) set flags otherwise
// reg = tmp
uint32_t emaccfg = EMAC->EMACCFG | MG_BIT(14) | MG_BIT(11); // 100M, Full-duplex
if (sts & MG_BIT(1)) emaccfg &= ~MG_BIT(14); // 10M
if ((sts & MG_BIT(2)) == 0) emaccfg &= ~MG_BIT(11); // Half-duplex
EMAC->EMACCFG = emaccfg; // IRQ handler does not fiddle with this register
MG_DEBUG(("Link is %uM %s-duplex", emaccfg & MG_BIT(14) ? 100 : 10,
emaccfg & MG_BIT(11) ? "full" : "half"));
}
return up;
}
void EMAC0_IRQHandler(void);
static uint32_t s_rxno;
void EMAC0_IRQHandler(void) {
if (EMAC->EMACDMARIS & MG_BIT(6)) { // Frame received, loop
EMAC->EMACDMARIS = MG_BIT(16) | MG_BIT(6); // Clear flag
for (uint32_t i = 0; i < 10; i++) { // read as they arrive but not forever
if (s_rxdesc[s_rxno][0] & MG_BIT(31)) break; // exit when done
if (((s_rxdesc[s_rxno][0] & (MG_BIT(8) | MG_BIT(9))) == (MG_BIT(8) | MG_BIT(9))) &&
!(s_rxdesc[s_rxno][0] & MG_BIT(15))) { // skip partial/errored frames
uint32_t len = ((s_rxdesc[s_rxno][0] >> 16) & (MG_BIT(14) - 1));
// printf("%lx %lu %lx %.8lx\n", s_rxno, len, s_rxdesc[s_rxno][0],
// EMAC->EMACDMARIS);
mg_tcpip_qwrite(s_rxbuf[s_rxno], len > 4 ? len - 4 : len, s_ifp);
}
s_rxdesc[s_rxno][0] = MG_BIT(31);
if (++s_rxno >= ETH_DESC_CNT) s_rxno = 0;
}
}
EMAC->EMACDMARIS = MG_BIT(7); // Clear possible RU while processing
EMAC->EMACRXPOLLD = 0; // and resume RX
}
struct mg_tcpip_driver mg_tcpip_driver_tm4c = {mg_tcpip_driver_tm4c_init,
mg_tcpip_driver_tm4c_tx, NULL,
mg_tcpip_driver_tm4c_up};
#endif
#ifdef MG_ENABLE_LINES
#line 1 "src/drivers/w5500.c"
#endif
#if MG_ENABLE_TCPIP
enum { W5500_CR = 0, W5500_S0 = 1, W5500_TX0 = 2, W5500_RX0 = 3 };
static void w5500_txn(struct mg_tcpip_spi *s, uint8_t block, uint16_t addr, bool wr,
void *buf, size_t len) {
uint8_t *p = (uint8_t *) buf;
uint8_t cmd[] = {(uint8_t) (addr >> 8), (uint8_t) (addr & 255),
(uint8_t) ((block << 3) | (wr ? 4 : 0))};
s->begin(s->spi);
for (size_t i = 0; i < sizeof(cmd); i++) s->txn(s->spi, cmd[i]);
for (size_t i = 0; i < len; i++) {
uint8_t r = s->txn(s->spi, p[i]);
if (!wr) p[i] = r;
}
s->end(s->spi);
}
// clang-format off
static void w5500_wn(struct mg_tcpip_spi *s, uint8_t block, uint16_t addr, void *buf, size_t len) { w5500_txn(s, block, addr, true, buf, len); }
static void w5500_w1(struct mg_tcpip_spi *s, uint8_t block, uint16_t addr, uint8_t val) { w5500_wn(s, block, addr, &val, 1); }
static void w5500_w2(struct mg_tcpip_spi *s, uint8_t block, uint16_t addr, uint16_t val) { uint8_t buf[2] = {(uint8_t) (val >> 8), (uint8_t) (val & 255)}; w5500_wn(s, block, addr, buf, sizeof(buf)); }
static void w5500_rn(struct mg_tcpip_spi *s, uint8_t block, uint16_t addr, void *buf, size_t len) { w5500_txn(s, block, addr, false, buf, len); }
static uint8_t w5500_r1(struct mg_tcpip_spi *s, uint8_t block, uint16_t addr) { uint8_t r = 0; w5500_rn(s, block, addr, &r, 1); return r; }
static uint16_t w5500_r2(struct mg_tcpip_spi *s, uint8_t block, uint16_t addr) { uint8_t buf[2] = {0, 0}; w5500_rn(s, block, addr, buf, sizeof(buf)); return (uint16_t) ((buf[0] << 8) | buf[1]); }
// clang-format on
static size_t w5500_rx(void *buf, size_t buflen, struct mg_tcpip_if *ifp) {
struct mg_tcpip_spi *s = (struct mg_tcpip_spi *) ifp->driver_data;
uint16_t r = 0, n = 0, len = (uint16_t) buflen, n2; // Read recv len
while ((n2 = w5500_r2(s, W5500_S0, 0x26)) > n) n = n2; // Until it is stable
// printf("RSR: %d\n", (int) n);
if (n > 0) {
uint16_t ptr = w5500_r2(s, W5500_S0, 0x28); // Get read pointer
n = w5500_r2(s, W5500_RX0, ptr); // Read frame length
if (n <= len + 2 && n > 1) {
r = (uint16_t) (n - 2);
w5500_rn(s, W5500_RX0, (uint16_t) (ptr + 2), buf, r);
}
w5500_w2(s, W5500_S0, 0x28, (uint16_t) (ptr + n)); // Advance read pointer
w5500_w1(s, W5500_S0, 1, 0x40); // Sock0 CR -> RECV
// printf(" RX_RD: tot=%u n=%u r=%u\n", n2, n, r);
}
return r;
}
static size_t w5500_tx(const void *buf, size_t buflen, struct mg_tcpip_if *ifp) {
struct mg_tcpip_spi *s = (struct mg_tcpip_spi *) ifp->driver_data;
uint16_t n = 0, len = (uint16_t) buflen;
while (n < len) n = w5500_r2(s, W5500_S0, 0x20); // Wait for space
uint16_t ptr = w5500_r2(s, W5500_S0, 0x24); // Get write pointer
w5500_wn(s, W5500_TX0, ptr, (void *) buf, len); // Write data
w5500_w2(s, W5500_S0, 0x24, (uint16_t) (ptr + len)); // Advance write pointer
w5500_w1(s, W5500_S0, 1, 0x20); // Sock0 CR -> SEND
for (int i = 0; i < 40; i++) {
uint8_t ir = w5500_r1(s, W5500_S0, 2); // Read S0 IR
if (ir == 0) continue;
// printf("IR %d, len=%d, free=%d, ptr %d\n", ir, (int) len, (int) n, ptr);
w5500_w1(s, W5500_S0, 2, ir); // Write S0 IR: clear it!
if (ir & 8) len = 0; // Timeout. Report error
if (ir & (16 | 8)) break; // Stop on SEND_OK or timeout
}
return len;
}
static bool w5500_init(struct mg_tcpip_if *ifp) {
struct mg_tcpip_spi *s = (struct mg_tcpip_spi *) ifp->driver_data;
s->end(s->spi);
w5500_w1(s, W5500_CR, 0, 0x80); // Reset chip: CR -> 0x80
w5500_w1(s, W5500_CR, 0x2e, 0); // CR PHYCFGR -> reset
w5500_w1(s, W5500_CR, 0x2e, 0xf8); // CR PHYCFGR -> set
// w5500_wn(s, W5500_CR, 9, s->mac, 6); // Set source MAC
w5500_w1(s, W5500_S0, 0x1e, 16); // Sock0 RX buf size
w5500_w1(s, W5500_S0, 0x1f, 16); // Sock0 TX buf size
w5500_w1(s, W5500_S0, 0, 4); // Sock0 MR -> MACRAW
w5500_w1(s, W5500_S0, 1, 1); // Sock0 CR -> OPEN
return w5500_r1(s, W5500_S0, 3) == 0x42; // Sock0 SR == MACRAW
}
static bool w5500_up(struct mg_tcpip_if *ifp) {
struct mg_tcpip_spi *spi = (struct mg_tcpip_spi *) ifp->driver_data;
uint8_t phycfgr = w5500_r1(spi, W5500_CR, 0x2e);
return phycfgr & 1; // Bit 0 of PHYCFGR is LNK (0 - down, 1 - up)
}
struct mg_tcpip_driver mg_tcpip_driver_w5500 = {w5500_init, w5500_tx, w5500_rx, w5500_up};
#endif