PowerToys/src/common/two_way_pipe_message_ipc.cpp
Josh Soref c2c163ac4e
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* spelling: exiting

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2020-05-27 16:58:47 +02:00

498 lines
15 KiB
C++

#include "pch.h"
#include "two_way_pipe_message_ipc_impl.h"
#pragma comment(lib, "advapi32.lib")
TwoWayPipeMessageIPC::TwoWayPipeMessageIPC(
std::wstring _input_pipe_name,
std::wstring _output_pipe_name,
callback_function p_func) :
impl(new TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl(
_input_pipe_name,
_output_pipe_name,
p_func))
{
}
TwoWayPipeMessageIPC::~TwoWayPipeMessageIPC()
{
delete impl;
}
void TwoWayPipeMessageIPC::send(std::wstring msg)
{
impl->send(msg);
}
void TwoWayPipeMessageIPC::start(HANDLE _restricted_pipe_token)
{
impl->start(_restricted_pipe_token);
}
void TwoWayPipeMessageIPC::end()
{
impl->end();
}
TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::TwoWayPipeMessageIPCImpl(
std::wstring _input_pipe_name,
std::wstring _output_pipe_name,
callback_function p_func)
{
input_pipe_name = _input_pipe_name;
output_pipe_name = _output_pipe_name;
dispatch_inc_message_function = p_func;
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::send(std::wstring msg)
{
output_queue.queue_message(msg);
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::start(HANDLE _restricted_pipe_token)
{
output_queue_thread = std::thread(&TwoWayPipeMessageIPCImpl::consume_output_queue_thread, this);
input_queue_thread = std::thread(&TwoWayPipeMessageIPCImpl::consume_input_queue_thread, this);
input_pipe_thread = std::thread(&TwoWayPipeMessageIPCImpl::start_named_pipe_server, this, _restricted_pipe_token);
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::end()
{
closed = true;
input_queue.interrupt();
input_queue_thread.join();
output_queue.interrupt();
output_queue_thread.join();
pipe_connect_handle_mutex.lock();
if (current_connect_pipe_handle != NULL)
{
//Cancels the Pipe currently waiting for a connection.
CancelIoEx(current_connect_pipe_handle, NULL);
}
pipe_connect_handle_mutex.unlock();
input_pipe_thread.join();
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::send_pipe_message(std::wstring message)
{
// Adapted from https://docs.microsoft.com/en-us/windows/win32/ipc/named-pipe-client
HANDLE output_pipe_handle;
const wchar_t* message_send = message.c_str();
BOOL fSuccess = FALSE;
DWORD cbToWrite, cbWritten, dwMode;
const wchar_t* lpszPipename = output_pipe_name.c_str();
// Try to open a named pipe; wait for it, if necessary.
while (1)
{
output_pipe_handle = CreateFile(
lpszPipename, // pipe name
GENERIC_READ | // read and write access
GENERIC_WRITE,
0, // no sharing
NULL, // default security attributes
OPEN_EXISTING, // opens existing pipe
0, // default attributes
NULL); // no template file
// Break if the pipe handle is valid.
if (output_pipe_handle != INVALID_HANDLE_VALUE)
break;
// Exit if an error other than ERROR_PIPE_BUSY occurs.
DWORD curr_error = 0;
if ((curr_error = GetLastError()) != ERROR_PIPE_BUSY)
{
return;
}
// All pipe instances are busy, so wait for 20 seconds.
if (!WaitNamedPipe(lpszPipename, 20000))
{
return;
}
}
dwMode = PIPE_READMODE_MESSAGE;
fSuccess = SetNamedPipeHandleState(
output_pipe_handle, // pipe handle
&dwMode, // new pipe mode
NULL, // don't set maximum bytes
NULL); // don't set maximum time
if (!fSuccess)
{
return;
}
// Send a message to the pipe server.
cbToWrite = (lstrlen(message_send)) * sizeof(WCHAR); // no need to send final '\0'. Pipe is in message mode.
fSuccess = WriteFile(
output_pipe_handle, // pipe handle
message_send, // message
cbToWrite, // message length
&cbWritten, // bytes written
NULL); // not overlapped
if (!fSuccess)
{
return;
}
CloseHandle(output_pipe_handle);
return;
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::consume_output_queue_thread()
{
while (!closed)
{
std::wstring message = output_queue.pop_message();
if (message.length() == 0)
{
break;
}
send_pipe_message(message);
}
}
BOOL TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::GetLogonSID(HANDLE hToken, PSID* ppsid)
{
// From https://docs.microsoft.com/en-us/previous-versions/aa446670(v=vs.85)
BOOL bSuccess = FALSE;
DWORD dwIndex;
DWORD dwLength = 0;
PTOKEN_GROUPS ptg = NULL;
// Verify the parameter passed in is not NULL.
if (NULL == ppsid)
goto Cleanup;
// Get required buffer size and allocate the TOKEN_GROUPS buffer.
if (!GetTokenInformation(
hToken, // handle to the access token
TokenGroups, // get information about the token's groups
(LPVOID)ptg, // pointer to TOKEN_GROUPS buffer
0, // size of buffer
&dwLength // receives required buffer size
))
{
if (GetLastError() != ERROR_INSUFFICIENT_BUFFER)
goto Cleanup;
ptg = (PTOKEN_GROUPS)HeapAlloc(GetProcessHeap(),
HEAP_ZERO_MEMORY,
dwLength);
if (ptg == NULL)
goto Cleanup;
}
// Get the token group information from the access token.
if (!GetTokenInformation(
hToken, // handle to the access token
TokenGroups, // get information about the token's groups
(LPVOID)ptg, // pointer to TOKEN_GROUPS buffer
dwLength, // size of buffer
&dwLength // receives required buffer size
))
{
goto Cleanup;
}
// Loop through the groups to find the logon SID.
for (dwIndex = 0; dwIndex < ptg->GroupCount; dwIndex++)
if ((ptg->Groups[dwIndex].Attributes & SE_GROUP_LOGON_ID) == SE_GROUP_LOGON_ID)
{
// Found the logon SID; make a copy of it.
dwLength = GetLengthSid(ptg->Groups[dwIndex].Sid);
*ppsid = (PSID)HeapAlloc(GetProcessHeap(),
HEAP_ZERO_MEMORY,
dwLength);
if (*ppsid == NULL)
goto Cleanup;
if (!CopySid(dwLength, *ppsid, ptg->Groups[dwIndex].Sid))
{
HeapFree(GetProcessHeap(), 0, (LPVOID)*ppsid);
goto Cleanup;
}
break;
}
bSuccess = TRUE;
Cleanup:
// Free the buffer for the token groups.
if (ptg != NULL)
HeapFree(GetProcessHeap(), 0, (LPVOID)ptg);
return bSuccess;
}
VOID TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::FreeLogonSID(PSID* ppsid)
{
// From https://docs.microsoft.com/en-us/previous-versions/aa446670(v=vs.85)
HeapFree(GetProcessHeap(), 0, (LPVOID)*ppsid);
}
int TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::change_pipe_security_allow_restricted_token(HANDLE handle, HANDLE token)
{
PACL old_dacl, new_dacl;
PSECURITY_DESCRIPTOR sd;
EXPLICIT_ACCESS ea;
PSID user_restricted;
int error;
if (!GetLogonSID(token, &user_restricted))
{
error = 5; // No access error.
goto Ldone;
}
if (GetSecurityInfo(handle,
SE_KERNEL_OBJECT,
DACL_SECURITY_INFORMATION,
NULL,
NULL,
&old_dacl,
NULL,
&sd))
{
error = GetLastError();
goto Lclean_sid;
}
memset(&ea, 0, sizeof(EXPLICIT_ACCESS));
ea.grfAccessPermissions |= GENERIC_READ | FILE_WRITE_ATTRIBUTES;
ea.grfAccessPermissions |= GENERIC_WRITE | FILE_READ_ATTRIBUTES;
ea.grfAccessPermissions |= SYNCHRONIZE;
ea.grfAccessMode = SET_ACCESS;
ea.grfInheritance = NO_INHERITANCE;
ea.Trustee.TrusteeForm = TRUSTEE_IS_SID;
ea.Trustee.TrusteeType = TRUSTEE_IS_USER;
ea.Trustee.ptstrName = (LPTSTR)user_restricted;
if (SetEntriesInAcl(1, &ea, old_dacl, &new_dacl))
{
error = GetLastError();
goto Lclean_sd;
}
if (SetSecurityInfo(handle,
SE_KERNEL_OBJECT,
DACL_SECURITY_INFORMATION,
NULL,
NULL,
new_dacl,
NULL))
{
error = GetLastError();
goto Lclean_dacl;
}
error = 0;
Lclean_dacl:
LocalFree((HLOCAL)new_dacl);
Lclean_sd:
LocalFree((HLOCAL)sd);
Lclean_sid:
FreeLogonSID(&user_restricted);
Ldone:
return error;
}
HANDLE TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::create_medium_integrity_token()
{
HANDLE restricted_token_handle;
SAFER_LEVEL_HANDLE level_handle = NULL;
DWORD sid_size = SECURITY_MAX_SID_SIZE;
BYTE medium_sid[SECURITY_MAX_SID_SIZE];
if (!SaferCreateLevel(SAFER_SCOPEID_USER, SAFER_LEVELID_NORMALUSER, SAFER_LEVEL_OPEN, &level_handle, NULL))
{
return NULL;
}
if (!SaferComputeTokenFromLevel(level_handle, NULL, &restricted_token_handle, 0, NULL))
{
SaferCloseLevel(level_handle);
return NULL;
}
SaferCloseLevel(level_handle);
if (!CreateWellKnownSid(WinMediumLabelSid, nullptr, medium_sid, &sid_size))
{
CloseHandle(restricted_token_handle);
return NULL;
}
TOKEN_MANDATORY_LABEL integrity_level = { 0 };
integrity_level.Label.Attributes = SE_GROUP_INTEGRITY;
integrity_level.Label.Sid = reinterpret_cast<PSID>(medium_sid);
if (!SetTokenInformation(restricted_token_handle, TokenIntegrityLevel, &integrity_level, sizeof(integrity_level)))
{
CloseHandle(restricted_token_handle);
return NULL;
}
return restricted_token_handle;
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::handle_pipe_connection(HANDLE input_pipe_handle)
{
//Adapted from https://docs.microsoft.com/en-us/windows/win32/ipc/multithreaded-pipe-server
HANDLE hHeap = GetProcessHeap();
uint8_t* pchRequest = (uint8_t*)HeapAlloc(hHeap, 0, BUFSIZE * sizeof(uint8_t));
DWORD cbBytesRead = 0, cbReplyBytes = 0, cbWritten = 0;
BOOL fSuccess = FALSE;
// Do some extra error checking since the app will keep running even if this thread fails.
std::list<std::vector<uint8_t>> message_parts;
if (input_pipe_handle == NULL)
{
if (pchRequest != NULL)
HeapFree(hHeap, 0, pchRequest);
return;
}
if (pchRequest == NULL)
{
return;
}
// Loop until done reading
do
{
// Read client requests from the pipe. This simplistic code only allows messages
// up to BUFSIZE characters in length.
ZeroMemory(pchRequest, BUFSIZE * sizeof(uint8_t));
fSuccess = ReadFile(
input_pipe_handle, // handle to pipe
pchRequest, // buffer to receive data
BUFSIZE * sizeof(uint8_t), // size of buffer
&cbBytesRead, // number of bytes read
NULL); // not overlapped I/O
if (!fSuccess && GetLastError() != ERROR_MORE_DATA)
{
break;
}
std::vector<uint8_t> part_vector;
part_vector.reserve(cbBytesRead);
std::copy(pchRequest, pchRequest + cbBytesRead, std::back_inserter(part_vector));
message_parts.push_back(part_vector);
} while (!fSuccess);
if (fSuccess)
{
// Reconstruct the total_message.
std::vector<uint8_t> reconstructed_message;
size_t total_size = 0;
for (auto& part_vector : message_parts)
{
total_size += part_vector.size();
}
reconstructed_message.reserve(total_size);
for (auto& part_vector : message_parts)
{
std::move(part_vector.begin(), part_vector.end(), std::back_inserter(reconstructed_message));
}
std::wstring unicode_msg;
unicode_msg.assign(reinterpret_cast<std::wstring::const_pointer>(reconstructed_message.data()), reconstructed_message.size() / sizeof(std::wstring::value_type));
input_queue.queue_message(unicode_msg);
}
// Flush the pipe to allow the client to read the pipe's contents
// before disconnecting. Then disconnect the pipe, and close the
// handle to this pipe instance.
FlushFileBuffers(input_pipe_handle);
DisconnectNamedPipe(input_pipe_handle);
CloseHandle(input_pipe_handle);
HeapFree(hHeap, 0, pchRequest);
printf("InstanceThread exiting.\n");
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::start_named_pipe_server(HANDLE token)
{
// Adapted from https://docs.microsoft.com/en-us/windows/win32/ipc/multithreaded-pipe-server
const wchar_t* pipe_name = input_pipe_name.c_str();
BOOL connected = FALSE;
HANDLE connect_pipe_handle = INVALID_HANDLE_VALUE;
while (!closed)
{
{
std::unique_lock lock(pipe_connect_handle_mutex);
connect_pipe_handle = CreateNamedPipe(
pipe_name,
PIPE_ACCESS_DUPLEX |
WRITE_DAC,
PIPE_TYPE_MESSAGE |
PIPE_READMODE_MESSAGE |
PIPE_WAIT,
PIPE_UNLIMITED_INSTANCES,
BUFSIZE,
BUFSIZE,
0,
NULL);
if (connect_pipe_handle == INVALID_HANDLE_VALUE)
{
return;
}
if (token != NULL)
{
int err = change_pipe_security_allow_restricted_token(connect_pipe_handle, token);
}
current_connect_pipe_handle = connect_pipe_handle;
}
connected = ConnectNamedPipe(connect_pipe_handle, NULL) ? TRUE : (GetLastError() == ERROR_PIPE_CONNECTED);
{
std::unique_lock lock(pipe_connect_handle_mutex);
current_connect_pipe_handle = NULL;
}
if (connected)
{
std::thread(&TwoWayPipeMessageIPCImpl::handle_pipe_connection, this, connect_pipe_handle).detach();
}
else
{
// Client could not connect.
CloseHandle(connect_pipe_handle);
}
}
}
void TwoWayPipeMessageIPC::TwoWayPipeMessageIPCImpl::consume_input_queue_thread()
{
while (!closed)
{
outgoing_message = L"";
std::wstring message = input_queue.pop_message();
if (message.length() == 0)
{
break;
}
// Check if callback method exists first before trying to call it.
// otherwise just store the response message in a variable.
if (dispatch_inc_message_function != nullptr)
{
dispatch_inc_message_function(message);
}
outgoing_message = message;
}
}