mongoose/mip/driver_stm32.c

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C
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#include "mip.h"
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#if MG_ENABLE_MIP
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struct stm32_eth {
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volatile uint32_t MACCR, MACFFR, MACHTHR, MACHTLR, MACMIIAR, MACMIIDR, MACFCR,
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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;
};
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#define ETH ((struct stm32_eth *) (uintptr_t) 0x40028000)
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#define BIT(x) ((uint32_t) 1 << (x))
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#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 void (*s_rx)(void *, size_t, void *); // Recv callback
static void *s_rxdata; // Recv callback data
enum { PHY_ADDR = 0, PHY_BCR = 0, PHY_BSR = 1 }; // PHY constants
static inline void spin(volatile uint32_t count) {
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while (count--) (void) 0;
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}
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static uint32_t eth_read_phy(uint8_t addr, uint8_t reg) {
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ETH->MACMIIAR &= (7 << 2);
ETH->MACMIIAR |= ((uint32_t) addr << 11) | ((uint32_t) reg << 6);
ETH->MACMIIAR |= BIT(0);
while (ETH->MACMIIAR & BIT(0)) spin(1);
return ETH->MACMIIDR;
}
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static void eth_write_phy(uint8_t addr, uint8_t reg, uint32_t val) {
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ETH->MACMIIDR = val;
ETH->MACMIIAR &= (7 << 2);
ETH->MACMIIAR |= ((uint32_t) addr << 11) | ((uint32_t) reg << 6) | BIT(1);
ETH->MACMIIAR |= BIT(0);
while (ETH->MACMIIAR & BIT(0)) spin(1);
}
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;
}
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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 mip_driver_stm32_init(uint8_t *mac, void *userdata) {
struct mip_driver_stm32 *d = (struct mip_driver_stm32 *) userdata;
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// Init RX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
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s_rxdesc[i][0] = BIT(31); // Own
s_rxdesc[i][1] = sizeof(s_rxbuf[i]) | 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
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}
// Init TX descriptors
for (int i = 0; i < ETH_DESC_CNT; i++) {
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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
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}
ETH->DMABMR |= BIT(0); // Software reset
while ((ETH->DMABMR & BIT(0)) != 0) spin(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;
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ETH->MACMIIAR = ((uint32_t)cr & 7) << 2;
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// 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 = BIT(13) | BIT(16) | BIT(22) | BIT(23) | BIT(25);
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ETH->MACIMR = BIT(3) | BIT(9); // Mask timestamp & PMT IT
ETH->MACFCR = BIT(7); // Disable zero quarta pause
ETH->MACFFR = BIT(31); // Receive all
eth_write_phy(PHY_ADDR, PHY_BCR, BIT(15)); // Reset PHY
eth_write_phy(PHY_ADDR, PHY_BCR, 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 = BIT(6) | BIT(16); // RIE, NISE
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ETH->MACCR = BIT(2) | BIT(3) | BIT(11) | BIT(14); // RE, TE, Duplex, Fast
ETH->DMAOMR = BIT(1) | BIT(13) | BIT(21) | BIT(25); // SR, ST, TSF, RSF
// MAC address filtering
ETH->MACA0HR = ((uint32_t) mac[5] << 8U) | mac[4];
ETH->MACA0LR = (uint32_t) (mac[3] << 24) | ((uint32_t) mac[2] << 16) |
((uint32_t) mac[1] << 8) | mac[0];
return true;
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}
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static void mip_driver_stm32_setrx(void (*rx)(void *, size_t, void *),
void *rxdata) {
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s_rx = rx;
s_rxdata = rxdata;
}
static uint32_t s_txno;
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static size_t mip_driver_stm32_tx(const void *buf, size_t len, void *userdata) {
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if (len > sizeof(s_txbuf[s_txno])) {
printf("%s: frame too big, %ld\n", __func__, (long) len);
len = 0; // Frame is too big
} else if ((s_txdesc[s_txno][0] & BIT(31))) {
printf("%s: no free descr\n", __func__);
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] = BIT(20) | BIT(28) | BIT(29) | BIT(30); // Chain,FS,LS
s_txdesc[s_txno][0] |= BIT(31); // Set OWN bit - let DMA take over
if (++s_txno >= ETH_DESC_CNT) s_txno = 0;
}
uint32_t sr = ETH->DMASR;
if (sr & BIT(2)) ETH->DMASR = BIT(2), ETH->DMATPDR = 0; // Resume
if (sr & BIT(5)) ETH->DMASR = BIT(5), ETH->DMATPDR = 0; // if busy
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if (len == 0) printf("E: D0 %lx SR %lx\n", (long) s_txdesc[0][0], (long) sr);
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return len;
(void) userdata;
}
static bool mip_driver_stm32_up(void *userdata) {
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uint32_t bsr = eth_read_phy(PHY_ADDR, PHY_BSR);
(void) userdata;
return bsr & BIT(2) ? 1 : 0;
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}
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void ETH_IRQHandler(void);
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void ETH_IRQHandler(void) {
qp_mark(QP_IRQTRIGGERED, 0);
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volatile uint32_t sr = ETH->DMASR;
if (sr & BIT(6)) { // Frame received, loop
for (uint32_t i = 0; i < ETH_DESC_CNT; i++) {
if (s_rxdesc[i][0] & BIT(31)) continue;
uint32_t len = ((s_rxdesc[i][0] >> 16) & (BIT(14) - 1));
// printf("%lx %lu %lx %lx\n", i, len, s_rxdesc[i][0], sr);
if (s_rx != NULL) s_rx(s_rxbuf[i], len > 4 ? len - 4 : len, s_rxdata);
s_rxdesc[i][0] = BIT(31);
}
}
if (sr & BIT(7)) ETH->DMARPDR = 0; // Resume RX
ETH->DMASR = sr & ~(BIT(2) | BIT(7)); // Clear status
}
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struct mip_driver mip_driver_stm32 = {
mip_driver_stm32_init, mip_driver_stm32_tx, NULL, mip_driver_stm32_up,
mip_driver_stm32_setrx};
#endif