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CoMP.cpp
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CoMP.cpp
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#include "CoMP.hpp"
CoMP::CoMP()
{
// initialize socket buffer
socket_buffer_.buffer.resize(PackageReceiver::package_length
* subframe_num_perframe * BS_ANT_NUM * SOCKET_BUFFER_FRAME_NUM); // buffer entire frame
socket_buffer_.buffer_status.resize(subframe_num_perframe * BS_ANT_NUM * SOCKET_BUFFER_FRAME_NUM);
// initialize FFT buffer
int FFT_buffer_block_num = BS_ANT_NUM * subframe_num_perframe * TASK_BUFFER_FRAME_NUM;
fft_buffer_.FFT_inputs = new complex_float*[FFT_buffer_block_num];
fft_buffer_.FFT_outputs = new complex_float*[FFT_buffer_block_num];
for(int i = 0; i < FFT_buffer_block_num; i++)
{
fft_buffer_.FFT_inputs[i] = (complex_float *)mufft_alloc(OFDM_CA_NUM * sizeof(complex_float));
fft_buffer_.FFT_outputs[i] = (complex_float *)mufft_alloc(OFDM_CA_NUM * sizeof(complex_float));
}
for(int i = 0; i < TASK_THREAD_NUM; i++)
{
muplans_[i] = mufft_create_plan_1d_c2c(OFDM_CA_NUM, MUFFT_FORWARD, MUFFT_FLAG_CPU_ANY);
}
// initialize pipes
pipe(pipe_socket_);
//fcntl(pipe_socket_[0], F_SETFL, fcntl(pipe_socket_[0], F_GETFL, 0) | O_NONBLOCK); // non-blocking pipe
//fcntl(pipe_socket_[1], F_SETFL, fcntl(pipe_socket_[1], F_GETFL, 0) | O_NONBLOCK);
receiver_.reset(new PackageReceiver(pipe_socket_));
for(int i = 0; i < TASK_THREAD_NUM; i++)
{
pipe(pipe_task_[i]);
pipe(pipe_task_finish_[i]);
//fcntl(pipe_task_[i][0], F_SETFL, fcntl(pipe_task_[i][0], F_GETFL, 0) | O_NONBLOCK); // non-blocking pipe
//fcntl(pipe_task_[i][1], F_SETFL, fcntl(pipe_task_[i][1], F_GETFL, 0) | O_NONBLOCK);
}
epoll_fd = epoll_create(MAX_EVENT_NUM);
// Setup the event 0 for package receiver
event[0].events = EPOLLIN;
event[0].data.fd = pipe_socket_[0];
epoll_ctl( epoll_fd, EPOLL_CTL_ADD, pipe_socket_[0], &event[0]);
for(int i = 1; i < MAX_EVENT_NUM; i++)
{
event[i].events = EPOLLIN;
event[i].data.fd = pipe_task_finish_[i-1][0];
epoll_ctl( epoll_fd, EPOLL_CTL_ADD, pipe_task_finish_[i-1][0], &event[i]);
}
// task side
for(int i = 0; i < TASK_THREAD_NUM; i++)
{
epoll_fd_task_side[i] = epoll_create(1);
event_task_side[i].events = EPOLLIN;
event_task_side[i].data.fd = pipe_task_[i][0]; // port 0 at task threads
epoll_ctl( epoll_fd_task_side[i], EPOLL_CTL_ADD, pipe_task_[i][0], &event_task_side[i]);
}
memset(cropper_checker_, 0, sizeof(int) * subframe_num_perframe);
memset(task_status_, 0, sizeof(bool) * TASK_THREAD_NUM);
// create
for(int i = 0; i < TASK_THREAD_NUM; i++)
{
context[i].obj_ptr = this;
context[i].id = i;
//printf("create thread %d\n", i);
if(pthread_create( &task_threads[i], NULL, CoMP::taskThread, &context[i]) != 0)
{
perror("task thread create failed");
exit(0);
}
}
}
CoMP::~CoMP()
{
for(int i = 0; i < TASK_THREAD_NUM; i++)
{
mufft_free_plan_1d(muplans_[i]);
}
// release FFT_buffer
int FFT_buffer_block_num = BS_ANT_NUM * subframe_num_perframe * TASK_BUFFER_FRAME_NUM;
for(int i = 0; i < FFT_buffer_block_num; i++)
{
mufft_free(fft_buffer_.FFT_inputs[i]);
mufft_free(fft_buffer_.FFT_outputs[i]);
}
}
void CoMP::start()
{
pthread_t recv_thread = receiver_->startRecv(socket_buffer_.buffer.data(),
socket_buffer_.buffer_status.data(), socket_buffer_.buffer_status.size(), socket_buffer_.buffer.size());
// event loop
struct epoll_event ev[MAX_EVENT_NUM];
int nfds;
while(true)
{
nfds = epoll_wait(epoll_fd, ev, MAX_EPOLL_EVENTS_PER_RUN, -1);
if(nfds < 0)
{
std::error_code ec(errno, std::system_category());
printf("Error in epoll_wait: %s\n", ec.message().c_str());
exit(0);
}
// loop each ready events
for(int i = 0; i < nfds; i++)
{
if(ev[i].data.fd == pipe_socket_[0]) // socket event
{
//printf("get socket event\n");
int offset;
read(pipe_socket_[0], (char *)&offset, sizeof(int)); // read position
// find an empty thread and run
int tid = -1;
for (int i = 0; i < TASK_THREAD_NUM; ++i)
{
if(!task_status_[i])
{
tid = i;
break;
}
}
if(tid >= 0) // find a thread
{
// write TASK_CROP and offset
//printf("assign offset %d to thread %d\n", offset, tid);
char tmp_data[sizeof(int) * 2];
int task_id = TASK_CROP;
memcpy(tmp_data, &task_id, sizeof(int));
memcpy(tmp_data + sizeof(int), &(offset), sizeof(int));
write(pipe_task_[tid][1], tmp_data, sizeof(int) * 2); // port 1 at main_thread end
task_status_[tid] = true; // set status to busy
}
else // all thread are running
{
cropWaitList.push(offset);
}
}
else // task event
{
//printf("get task event\n");
int tid = 0;
while(ev[i].data.fd != pipe_task_finish_[tid][0]) // find tid
{
tid++;
}
//printf("tid %d finished\n", tid);
task_status_[tid] = false; // now free
// the data length should be the same for all kinds of events ????
char tmp_data[sizeof(int) * 2];
read(pipe_task_finish_[tid][0], tmp_data, sizeof(int) * 2); // read
int event_id = *((int *)tmp_data);
if(event_id == EVENT_CROPPED)
{
int subframe_id = *((int *)tmp_data + 1);
// check subframe
cropper_checker_[subframe_id] ++;
if(cropper_checker_[subframe_id] == BS_ANT_NUM) // this sub-frame is finished
{
//printf("subframe_id %d finished\n", subframe_id);
cropper_checker_[subframe_id] = 0;
// TODO: assign further tasks
}
else
{
// find a task in the waiting list
if(cropWaitList.size() > 0) // not empty
{
if(cropWaitList.size() > max_queue_delay)
{
max_queue_delay = cropWaitList.size();
printf("maximum wait list length %d\n", cropWaitList.size());
}
int offset = cropWaitList.front();
cropWaitList.pop();
char tmp_data_for_crop[sizeof(int) * 2];
int task_id_for_crop = TASK_CROP;
memcpy(tmp_data_for_crop, &task_id_for_crop, sizeof(int));
memcpy(tmp_data_for_crop + sizeof(int), &(offset), sizeof(int));
write(pipe_task_[tid][1], tmp_data_for_crop, sizeof(int) * 2); // port 1 at main_thread end
}
}
}
}
}
}
}
void* CoMP::taskThread(void* context)
{
CoMP* obj_ptr = ((EventHandlerContext *)context)->obj_ptr;
int tid = ((EventHandlerContext *)context)->id;
printf("task thread %d starts\n", tid);
int task_epoll_fd = obj_ptr->epoll_fd_task_side[tid];
// wait for event
struct epoll_event ev;
char data_from_main[1024];
int task_id;
while(true)
{
//printf("thread %d wait for event\n", tid);
int nfds = epoll_wait(task_epoll_fd, &ev, 1, -1);
if(nfds < 0)
{
std::error_code ec(errno, std::system_category());
printf("Error in thread %d, epoll_wait: %s\n", tid, ec.message().c_str());
exit(0);
}
//printf("thread %d get event\n", tid);
// the data length should be the same for all kinds of tasks????
read(ev.data.fd, data_from_main, sizeof(int) * 2);
task_id = *((int *)data_from_main);
if(task_id == TASK_CROP)
{
int offset;
offset = *((int *)data_from_main + 1);
//printf("thread %d task_id %d, offset %d\n", tid, task_id, offset);
obj_ptr->doCrop(tid, offset);
}
else
{
}
}
}
inline int CoMP::getFFTBufferIndex(int frame_id, int subframe_id, int ant_id)
{
frame_id = frame_id % TASK_BUFFER_FRAME_NUM;
return frame_id * (BS_ANT_NUM * subframe_num_perframe) + subframe_id * BS_ANT_NUM + ant_id;
}
void CoMP::doCrop(int tid, int offset)
{
// read info
char* cur_ptr_buffer = socket_buffer_.buffer.data() + offset * PackageReceiver::package_length;
int ant_id, frame_id, subframe_id, cell_id;
frame_id = *((int *)cur_ptr_buffer);
subframe_id = *((int *)cur_ptr_buffer + 1);
cell_id = *((int *)cur_ptr_buffer + 2);
ant_id = *((int *)cur_ptr_buffer + 3);
//printf("thread %d process frame_id %d, subframe_id %d, cell_id %d, ant_id %d\n", tid, frame_id, subframe_id, cell_id, ant_id);
// remove CP, do FFT
int delay_offset = 0;
int FFT_buffer_target_id = getFFTBufferIndex(frame_id, subframe_id, ant_id);
memcpy((char *)fft_buffer_.FFT_inputs[FFT_buffer_target_id],
cur_ptr_buffer + sizeof(int) * 4 + (OFDM_PREFIX_LEN + delay_offset) * 2 * sizeof(float),
sizeof(float) * (OFDM_CA_NUM - delay_offset) * 2); // COPY
if(delay_offset > 0) // append zero
{
memset((char *)fft_buffer_.FFT_inputs[FFT_buffer_target_id]
+ (OFDM_CA_NUM - delay_offset) * 2 * sizeof(float), 0, sizeof(float) * 2 * delay_offset);
}
// perform fft
mufft_execute_plan_1d(muplans_[tid], fft_buffer_.FFT_outputs[FFT_buffer_target_id],
fft_buffer_.FFT_inputs[FFT_buffer_target_id]);
// debug
/*
if(tid ==0)
{
complex_float *cur_fft_buffer_ptr = fft_buffer_.FFT_inputs[FFT_buffer_target_id];
for(int i = 0; i < 10; i++)
printf("%f + %f i\n", cur_fft_buffer_ptr[i].real, cur_fft_buffer_ptr[i].imag);
printf("after fft\n");
cur_fft_buffer_ptr = fft_buffer_.FFT_outputs[FFT_buffer_target_id];
for(int i = 0; i < 10; i++)
printf("%f + %f i\n", cur_fft_buffer_ptr[i].real, cur_fft_buffer_ptr[i].imag);
exit(0);
}
*/
// after finish
socket_buffer_.buffer_status[offset] = 0; // now empty
// inform main thread
char tmp_data[sizeof(int) * 2];
int event_id = EVENT_CROPPED;
memcpy(tmp_data, &event_id, sizeof(int));
memcpy(tmp_data + sizeof(int), &(subframe_id), sizeof(int));
write(pipe_task_finish_[tid][1], tmp_data, sizeof(int) * 2); // tell main thread crop finished
}