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sdrangel/liblimesuite/srcmw/Connection_uLimeSDR/Connection_uLimeSDR.cpp

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/**
@file Connection_uLimeSDR.cpp
@author Lime Microsystems
@brief Implementation of uLimeSDR board connection.
*/
#include "Connection_uLimeSDR.h"
#include "ErrorReporting.h"
#include <cstring>
#include <iostream>
#include <thread>
#include <chrono>
#include <FPGA_common.h>
#include <LMS7002M.h>
#include <ciso646>
using namespace std;
using namespace lime;
#define __unix__
Connection_uLimeSDR::Connection_uLimeSDR(void *arg)
{
RxLoopFunction = bind(&Connection_uLimeSDR::ReceivePacketsLoop, this, std::placeholders::_1);
TxLoopFunction = bind(&Connection_uLimeSDR::TransmitPacketsLoop, this, std::placeholders::_1);
isConnected = false;
mStreamWrEndPtAddr = 0x03;
mStreamRdEndPtAddr = 0x83;
isConnected = false;
txSize = 0;
rxSize = 0;
#ifndef __unix__
mFTHandle = NULL;
#else
dev_handle = 0;
devs = 0;
mUsbCounter = 0;
ctx = (libusb_context *)arg;
#endif
}
/** @brief Initializes port type and object necessary to communicate to usb device.
*/
Connection_uLimeSDR::Connection_uLimeSDR(void *arg, const unsigned index, const int vid, const int pid)
{
RxLoopFunction = bind(&Connection_uLimeSDR::ReceivePacketsLoop, this, std::placeholders::_1);
TxLoopFunction = bind(&Connection_uLimeSDR::TransmitPacketsLoop, this, std::placeholders::_1);
mExpectedSampleRate = 0;
isConnected = false;
mStreamWrEndPtAddr = 0x03;
mStreamRdEndPtAddr = 0x83;
isConnected = false;
txSize = 0;
rxSize = 0;
#ifndef __unix__
mFTHandle = NULL;
#else
dev_handle = 0;
devs = 0;
mUsbCounter = 0;
ctx = (libusb_context *)arg;
#endif
if (this->Open(index, vid, pid) != 0)
std::cerr << GetLastErrorMessage() << std::endl;
this->SetReferenceClockRate(52e6);
GetChipVersion();
}
/** @brief Closes connection to chip and deallocates used memory.
*/
Connection_uLimeSDR::~Connection_uLimeSDR()
{
Close();
}
#ifdef __unix__
int Connection_uLimeSDR::FT_FlushPipe(unsigned char ep)
{
int actual = 0;
unsigned char wbuffer[20]={0};
mUsbCounter++;
wbuffer[0] = (mUsbCounter)&0xFF;
wbuffer[1] = (mUsbCounter>>8)&0xFF;
wbuffer[2] = (mUsbCounter>>16)&0xFF;
wbuffer[3] = (mUsbCounter>>24)&0xFF;
wbuffer[4] = ep;
libusb_bulk_transfer(dev_handle, 0x01, wbuffer, 20, &actual, 1000);
if (actual != 20)
return -1;
mUsbCounter++;
wbuffer[0] = (mUsbCounter)&0xFF;
wbuffer[1] = (mUsbCounter>>8)&0xFF;
wbuffer[2] = (mUsbCounter>>16)&0xFF;
wbuffer[3] = (mUsbCounter>>24)&0xFF;
wbuffer[4] = ep;
wbuffer[5] = 0x03;
libusb_bulk_transfer(dev_handle, 0x01, wbuffer, 20, &actual, 1000);
if (actual != 20)
return -1;
return 0;
}
int Connection_uLimeSDR::FT_SetStreamPipe(unsigned char ep, size_t size)
{
int actual = 0;
unsigned char wbuffer[20]={0};
mUsbCounter++;
wbuffer[0] = (mUsbCounter)&0xFF;
wbuffer[1] = (mUsbCounter>>8)&0xFF;
wbuffer[2] = (mUsbCounter>>16)&0xFF;
wbuffer[3] = (mUsbCounter>>24)&0xFF;
wbuffer[4] = ep;
libusb_bulk_transfer(dev_handle, 0x01, wbuffer, 20, &actual, 1000);
if (actual != 20)
return -1;
mUsbCounter++;
wbuffer[0] = (mUsbCounter)&0xFF;
wbuffer[1] = (mUsbCounter>>8)&0xFF;
wbuffer[2] = (mUsbCounter>>16)&0xFF;
wbuffer[3] = (mUsbCounter>>24)&0xFF;
wbuffer[5] = 0x02;
wbuffer[8] = (size)&0xFF;
wbuffer[9] = (size>>8)&0xFF;
wbuffer[10] = (size>>16)&0xFF;
wbuffer[11] = (size>>24)&0xFF;
libusb_bulk_transfer(dev_handle, 0x01, wbuffer, 20, &actual, 1000);
if (actual != 20)
return -1;
return 0;
}
#endif
/** @brief Tries to open connected USB device and find communication endpoints.
@return Returns 0-Success, other-EndPoints not found or device didn't connect.
*/
int Connection_uLimeSDR::Open(const unsigned index, const int vid, const int pid)
{
#ifndef __unix__
DWORD devCount;
FT_STATUS ftStatus = FT_OK;
DWORD dwNumDevices = 0;
// Open a device
ftStatus = FT_Create(0, FT_OPEN_BY_INDEX, &mFTHandle);
if (FT_FAILED(ftStatus))
{
ReportError(ENODEV, "Failed to list USB Devices");
return -1;
}
FT_AbortPipe(mFTHandle, mStreamRdEndPtAddr);
FT_AbortPipe(mFTHandle, 0x82);
FT_AbortPipe(mFTHandle, 0x02);
FT_AbortPipe(mFTHandle, mStreamWrEndPtAddr);
FT_SetStreamPipe(mFTHandle, FALSE, FALSE, 0x82, 64);
FT_SetStreamPipe(mFTHandle, FALSE, FALSE, 0x02, 64);
FT_SetPipeTimeout(mFTHandle, 0x02, 500);
FT_SetPipeTimeout(mFTHandle, 0x82, 500);
isConnected = true;
return 0;
#else
dev_handle = libusb_open_device_with_vid_pid(ctx, vid, pid);
if(dev_handle == nullptr)
return ReportError(ENODEV, "libusb_open failed");
libusb_reset_device(dev_handle);
if(libusb_kernel_driver_active(dev_handle, 1) == 1) //find out if kernel driver is attached
{
printf("Kernel Driver Active\n");
if(libusb_detach_kernel_driver(dev_handle, 1) == 0) //detach it
printf("Kernel Driver Detached!\n");
}
int r = libusb_claim_interface(dev_handle, 1); //claim interface 0 (the first) of device
if(r < 0)
{
printf("Cannot Claim Interface\n");
return ReportError(-1, "Cannot claim interface - %s", libusb_strerror(libusb_error(r)));
}
r = libusb_claim_interface(dev_handle, 1); //claim interface 0 (the first) of device
if(r < 0)
{
printf("Cannot Claim Interface\n");
return ReportError(-1, "Cannot claim interface - %s", libusb_strerror(libusb_error(r)));
}
printf("Claimed Interface\n");
FT_SetStreamPipe(0x82,64);
FT_SetStreamPipe(0x02,64);
isConnected = true;
return 0;
#endif
}
/** @brief Closes communication to device.
*/
void Connection_uLimeSDR::Close()
{
#ifndef __unix__
FT_Close(mFTHandle);
#else
if(dev_handle != 0)
{
FT_FlushPipe(mStreamRdEndPtAddr);
FT_FlushPipe(0x82);
libusb_release_interface(dev_handle, 1);
libusb_close(dev_handle);
dev_handle = 0;
}
#endif
isConnected = false;
}
/** @brief Returns connection status
@return 1-connection open, 0-connection closed.
*/
bool Connection_uLimeSDR::IsOpen()
{
return isConnected;
}
#ifndef __unix__
int Connection_uLimeSDR::ReinitPipe(unsigned char ep)
{
FT_AbortPipe(mFTHandle, ep);
FT_FlushPipe(mFTHandle, ep);
FT_SetStreamPipe(mFTHandle, FALSE, FALSE, ep, 64);
return 0;
}
#endif
/** @brief Sends given data buffer to chip through USB port.
@param buffer data buffer, must not be longer than 64 bytes.
@param length given buffer size.
@param timeout_ms timeout limit for operation in milliseconds
@return number of bytes sent.
*/
int Connection_uLimeSDR::Write(const unsigned char *buffer, const int length, int timeout_ms)
{
std::lock_guard<std::mutex> lock(mExtraUsbMutex);
long len = 0;
if (IsOpen() == false)
return 0;
#ifndef __unix__
// Write to channel 1 ep 0x02
ULONG ulBytesWrite = 0;
FT_STATUS ftStatus = FT_OK;
OVERLAPPED vOverlapped = { 0 };
FT_InitializeOverlapped(mFTHandle, &vOverlapped);
ftStatus = FT_WritePipe(mFTHandle, 0x02, (unsigned char*)buffer, length, &ulBytesWrite, &vOverlapped);
if (ftStatus != FT_IO_PENDING)
{
FT_ReleaseOverlapped(mFTHandle, &vOverlapped);
ReinitPipe(0x02);
return -1;
}
DWORD dwRet = WaitForSingleObject(vOverlapped.hEvent, timeout_ms);
if (dwRet == WAIT_OBJECT_0 || dwRet == WAIT_TIMEOUT)
{
if (GetOverlappedResult(mFTHandle, &vOverlapped, &ulBytesWrite, FALSE) == FALSE)
{
ReinitPipe(0x02);
ulBytesWrite = -1;
}
}
else
{
ReinitPipe(0x02);
ulBytesWrite = -1;
}
FT_ReleaseOverlapped(mFTHandle, &vOverlapped);
return ulBytesWrite;
#else
unsigned char* wbuffer = new unsigned char[length];
memcpy(wbuffer, buffer, length);
int actual = 0;
libusb_bulk_transfer(dev_handle, 0x02, wbuffer, length, &actual, timeout_ms);
len = actual;
delete[] wbuffer;
return len;
#endif
}
/** @brief Reads data coming from the chip through USB port.
@param buffer pointer to array where received data will be copied, array must be
big enough to fit received data.
@param length number of bytes to read from chip.
@param timeout_ms timeout limit for operation in milliseconds
@return number of bytes received.
*/
int Connection_uLimeSDR::Read(unsigned char *buffer, const int length, int timeout_ms)
{
std::lock_guard<std::mutex> lock(mExtraUsbMutex);
long len = length;
if(IsOpen() == false)
return 0;
#ifndef __unix__
//
// Read from channel 1 ep 0x82
//
ULONG ulBytesRead = 0;
FT_STATUS ftStatus = FT_OK;
OVERLAPPED vOverlapped = { 0 };
FT_InitializeOverlapped(mFTHandle, &vOverlapped);
ftStatus = FT_ReadPipe(mFTHandle, 0x82, buffer, length, &ulBytesRead, &vOverlapped);
if (ftStatus != FT_IO_PENDING)
{
FT_ReleaseOverlapped(mFTHandle, &vOverlapped);
ReinitPipe(0x82);
return -1;;
}
DWORD dwRet = WaitForSingleObject(vOverlapped.hEvent, timeout_ms);
if (dwRet == WAIT_OBJECT_0 || dwRet == WAIT_TIMEOUT)
{
if (GetOverlappedResult(mFTHandle, &vOverlapped, &ulBytesRead, FALSE)==FALSE)
{
ReinitPipe(0x82);
ulBytesRead = -1;
}
}
else
{
ReinitPipe(0x82);
ulBytesRead = -1;
}
FT_ReleaseOverlapped(mFTHandle, &vOverlapped);
return ulBytesRead;
#else
int actual = 0;
libusb_bulk_transfer(dev_handle, 0x82, buffer, len, &actual, timeout_ms);
len = actual;
#endif
return len;
}
#ifdef __unix__
/** @brief Function for handling libusb callbacks
*/
static void callback_libusbtransfer(libusb_transfer *trans)
{
Connection_uLimeSDR::USBTransferContext *context = reinterpret_cast<Connection_uLimeSDR::USBTransferContext*>(trans->user_data);
std::unique_lock<std::mutex> lck(context->transferLock);
switch(trans->status)
{
case LIBUSB_TRANSFER_CANCELLED:
//printf("Transfer %i canceled\n", context->id);
context->bytesXfered = trans->actual_length;
context->done.store(true);
//context->used = false;
//context->reset();
break;
case LIBUSB_TRANSFER_COMPLETED:
//if(trans->actual_length == context->bytesExpected)
{
context->bytesXfered = trans->actual_length;
context->done.store(true);
}
break;
case LIBUSB_TRANSFER_ERROR:
printf("TRANSFER ERRRO\n");
context->bytesXfered = trans->actual_length;
context->done.store(true);
//context->used = false;
break;
case LIBUSB_TRANSFER_TIMED_OUT:
//printf("transfer timed out %i\n", context->id);
context->bytesXfered = trans->actual_length;
context->done.store(true);
//context->used = false;
break;
case LIBUSB_TRANSFER_OVERFLOW:
printf("transfer overflow\n");
break;
case LIBUSB_TRANSFER_STALL:
printf("transfer stalled\n");
break;
case LIBUSB_TRANSFER_NO_DEVICE:
printf("transfer no device\n");
break;
}
lck.unlock();
context->cv.notify_one();
}
#endif
/**
@brief Starts asynchronous data reading from board
@param *buffer buffer where to store received data
@param length number of bytes to read
@return handle of transfer context
*/
int Connection_uLimeSDR::BeginDataReading(char *buffer, uint32_t length)
{
int i = 0;
bool contextFound = false;
//find not used context
for(i = 0; i<USB_MAX_CONTEXTS; i++)
{
if(!contexts[i].used)
{
contextFound = true;
break;
}
}
if(!contextFound)
{
printf("No contexts left for reading data\n");
return -1;
}
contexts[i].used = true;
#ifndef __unix__
if (length != rxSize)
{
rxSize = length;
FT_SetStreamPipe(mFTHandle, FALSE, FALSE, mStreamRdEndPtAddr, rxSize);
}
FT_InitializeOverlapped(mFTHandle, &contexts[i].inOvLap);
ULONG ulActual;
FT_STATUS ftStatus = FT_OK;
ftStatus = FT_ReadPipe(mFTHandle, mStreamRdEndPtAddr, (unsigned char*)buffer, length, &ulActual, &contexts[i].inOvLap);
if (ftStatus != FT_IO_PENDING)
return -1;
#else
if (length != rxSize)
{
rxSize = length;
FT_SetStreamPipe(mStreamRdEndPtAddr,rxSize);
}
unsigned int Timeout = 500;
libusb_transfer *tr = contexts[i].transfer;
libusb_fill_bulk_transfer(tr, dev_handle, mStreamRdEndPtAddr, (unsigned char*)buffer, length, callback_libusbtransfer, &contexts[i], Timeout);
contexts[i].done = false;
contexts[i].bytesXfered = 0;
contexts[i].bytesExpected = length;
int status = libusb_submit_transfer(tr);
if(status != 0)
{
printf("ERROR BEGIN DATA READING %s\n", libusb_error_name(status));
contexts[i].used = false;
return -1;
}
#endif
return i;
}
/**
@brief Waits for asynchronous data reception
@param contextHandle handle of which context data to wait
@param timeout_ms number of miliseconds to wait
@return 1-data received, 0-data not received
*/
int Connection_uLimeSDR::WaitForReading(int contextHandle, unsigned int timeout_ms)
{
if(contextHandle >= 0 && contexts[contextHandle].used == true)
{
#ifndef __unix__
DWORD dwRet = WaitForSingleObject(contexts[contextHandle].inOvLap.hEvent, timeout_ms);
if (dwRet == WAIT_OBJECT_0)
return 1;
#else
auto t1 = chrono::high_resolution_clock::now();
auto t2 = chrono::high_resolution_clock::now();
std::unique_lock<std::mutex> lck(contexts[contextHandle].transferLock);
while(contexts[contextHandle].done.load() == false && std::chrono::duration_cast<std::chrono::milliseconds>(t2 - t1).count() < timeout_ms)
{
//blocking not to waste CPU
contexts[contextHandle].cv.wait_for(lck, chrono::milliseconds(timeout_ms));
t2 = chrono::high_resolution_clock::now();
}
return contexts[contextHandle].done.load() == true;
#endif
}
return 0;
}
/**
@brief Finishes asynchronous data reading from board
@param buffer array where to store received data
@param length number of bytes to read
@param contextHandle handle of which context to finish
@return false failure, true number of bytes received
*/
int Connection_uLimeSDR::FinishDataReading(char *buffer, uint32_t length, int contextHandle)
{
if(contextHandle >= 0 && contexts[contextHandle].used == true)
{
#ifndef __unix__
ULONG ulActualBytesTransferred;
FT_STATUS ftStatus = FT_OK;
ftStatus = FT_GetOverlappedResult(mFTHandle, &contexts[contextHandle].inOvLap, &ulActualBytesTransferred, FALSE);
if (ftStatus != FT_OK)
length = 0;
else
length = ulActualBytesTransferred;
FT_ReleaseOverlapped(mFTHandle, &contexts[contextHandle].inOvLap);
contexts[contextHandle].used = false;
return length;
#else
length = contexts[contextHandle].bytesXfered;
contexts[contextHandle].used = false;
contexts[contextHandle].reset();
return length;
#endif
}
else
return 0;
}
/**
@brief Aborts reading operations
*/
void Connection_uLimeSDR::AbortReading()
{
#ifndef __unix__
FT_AbortPipe(mFTHandle, mStreamRdEndPtAddr);
for (int i = 0; i < USB_MAX_CONTEXTS; ++i)
{
if (contexts[i].used == true)
{
FT_ReleaseOverlapped(mFTHandle, &contexts[i].inOvLap);
contexts[i].used = false;
}
}
FT_FlushPipe(mFTHandle, mStreamRdEndPtAddr);
rxSize = 0;
#else
for(int i = 0; i<USB_MAX_CONTEXTS; ++i)
{
if(contexts[i].used)
libusb_cancel_transfer(contexts[i].transfer);
}
FT_FlushPipe(mStreamRdEndPtAddr);
rxSize = 0;
#endif
}
/**
@brief Starts asynchronous data Sending to board
@param *buffer buffer to send
@param length number of bytes to send
@return handle of transfer context
*/
int Connection_uLimeSDR::BeginDataSending(const char *buffer, uint32_t length)
{
int i = 0;
//find not used context
bool contextFound = false;
for(i = 0; i<USB_MAX_CONTEXTS; i++)
{
if(!contextsToSend[i].used)
{
contextFound = true;
break;
}
}
if(!contextFound)
return -1;
contextsToSend[i].used = true;
#ifndef __unix__
FT_STATUS ftStatus = FT_OK;
ULONG ulActualBytesSend;
if (length != txSize)
{
txSize = length;
FT_SetStreamPipe(mFTHandle, FALSE, FALSE, mStreamWrEndPtAddr, txSize);
}
FT_InitializeOverlapped(mFTHandle, &contextsToSend[i].inOvLap);
ftStatus = FT_WritePipe(mFTHandle, mStreamWrEndPtAddr, (unsigned char*)buffer, length, &ulActualBytesSend, &contextsToSend[i].inOvLap);
if (ftStatus != FT_IO_PENDING)
return -1;
#else
if (length != txSize)
{
txSize = length;
FT_SetStreamPipe(mStreamWrEndPtAddr,txSize);
}
unsigned int Timeout = 500;
libusb_transfer *tr = contextsToSend[i].transfer;
libusb_fill_bulk_transfer(tr, dev_handle, mStreamWrEndPtAddr, (unsigned char*)buffer, length, callback_libusbtransfer, &contextsToSend[i], Timeout);
contextsToSend[i].done = false;
contextsToSend[i].bytesXfered = 0;
contextsToSend[i].bytesExpected = length;
int status = libusb_submit_transfer(tr);
if(status != 0)
{
printf("ERROR BEGIN DATA SENDING %s\n", libusb_error_name(status));
contextsToSend[i].used = false;
return -1;
}
#endif
return i;
}
/**
@brief Waits for asynchronous data sending
@param contextHandle handle of which context data to wait
@param timeout_ms number of miliseconds to wait
@return 1-data received, 0-data not received
*/
int Connection_uLimeSDR::WaitForSending(int contextHandle, unsigned int timeout_ms)
{
if(contextsToSend[contextHandle].used == true)
{
#ifndef __unix__
DWORD dwRet = WaitForSingleObject(contextsToSend[contextHandle].inOvLap.hEvent, timeout_ms);
if (dwRet == WAIT_OBJECT_0)
return 1;
#else
auto t1 = chrono::high_resolution_clock::now();
auto t2 = chrono::high_resolution_clock::now();
std::unique_lock<std::mutex> lck(contextsToSend[contextHandle].transferLock);
while(contextsToSend[contextHandle].done.load() == false && std::chrono::duration_cast<std::chrono::milliseconds>(t2 - t1).count() < timeout_ms)
{
//blocking not to waste CPU
contextsToSend[contextHandle].cv.wait_for(lck, chrono::milliseconds(timeout_ms));
t2 = chrono::high_resolution_clock::now();
}
return contextsToSend[contextHandle].done == true;
#endif
}
return 0;
}
/**
@brief Finishes asynchronous data sending to board
@param buffer array where to store received data
@param length number of bytes to read
@param contextHandle handle of which context to finish
@return false failure, true number of bytes sent
*/
int Connection_uLimeSDR::FinishDataSending(const char *buffer, uint32_t length, int contextHandle)
{
if(contextsToSend[contextHandle].used == true)
{
#ifndef __unix__
ULONG ulActualBytesTransferred ;
FT_STATUS ftStatus = FT_OK;
ftStatus = FT_GetOverlappedResult(mFTHandle, &contextsToSend[contextHandle].inOvLap, &ulActualBytesTransferred, FALSE);
if (ftStatus != FT_OK)
length = 0;
else
length = ulActualBytesTransferred;
FT_ReleaseOverlapped(mFTHandle, &contextsToSend[contextHandle].inOvLap);
contextsToSend[contextHandle].used = false;
return length;
#else
length = contextsToSend[contextHandle].bytesXfered;
contextsToSend[contextHandle].used = false;
contextsToSend[contextHandle].reset();
return length;
#endif
}
else
return 0;
}
/**
@brief Aborts sending operations
*/
void Connection_uLimeSDR::AbortSending()
{
#ifndef __unix__
FT_AbortPipe(mFTHandle, mStreamWrEndPtAddr);
for (int i = 0; i < USB_MAX_CONTEXTS; ++i)
{
if (contextsToSend[i].used == true)
{
FT_ReleaseOverlapped(mFTHandle, &contextsToSend[i].inOvLap);
contextsToSend[i].used = false;
}
}
txSize = 0;
#else
for(int i = 0; i<USB_MAX_CONTEXTS; ++i)
{
if(contextsToSend[i].used)
libusb_cancel_transfer(contextsToSend[i].transfer);
}
FT_FlushPipe(mStreamWrEndPtAddr);
txSize = 0;
#endif
}