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rdtsc.c
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rdtsc.c
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#include "rdtsc.h"
cl_event ocdTempEvent;
#ifdef ENABLE_TIMER
cl_ulong startTime, endTime;
struct ocdTimer * ocdTempTimer;
struct ocdDualTimer * ocdTempDualTimer;
struct ocdHostTimer * ocdTempHostTimer;
struct ocdHostTimer fullExecTimer = {OCD_TIMER_HOST, NULL, 0, 0, 0, {0, 0}};
struct timer_group_mem head = {NULL, NULL, NULL};
struct timer_group_mem * tail;
char rootStr[1] = { (char)0};
cl_ulong rootTimes[7] = {0, 0, 0, 0, 0, 0, 0};
cl_ulong totalTimes[7] = {0, 0, 0, 0, 0, 0, 0};
struct timer_name_tree_node root = {
rootStr, 0, NULL, NULL, &head, 0, rootTimes
}; //sentinel
//linear search of the Name List.
//returns a pointer to the correct time array, or -1 if none exists yet
//rather inefficient if many names are used, but the tree will take care of
// speeding lookups, and we'll switch to alpha sort by default as a sideffect
void * checkSimpleNameList(const char * s, int len) {
struct timer_name_tree_node * curr = root.next;
while (curr != NULL) { //still unique names to be checked
if (strcmp(s, curr->string) == 0) {
return curr->times;
}
curr = curr->next;
}
return (void *)-1;
}
struct timer_name_tree_node * atail = &root;
//simple named timer aggregation
//linear scan of the timer list, adds nodes to a names list as necessary
//DO NOT USE AT THE SAME TIME AS THE TREE
//this replaces the tree with a simple unordered list
void simpleNameTally() {
struct timer_group_mem * curr = head.next;
while (curr != NULL) {
void * time;
if (curr->timer->s.name != NULL) {
time = checkSimpleNameList(curr->timer->s.name, curr->timer->s.nlen);
if (time == (void *)-1) {
//initialize a new name list node
atail->next = (struct timer_name_tree_node *) calloc(sizeof (struct timer_name_tree_node), 1);
atail = atail->next;
atail->next = NULL;
atail->len = curr->timer->s.nlen;
atail->string = curr->timer->s.name;
atail->times = (cl_ulong *) calloc(sizeof(cl_ulong), 7);
time = (void *)atail->times;
}} else {
time = (void *)root.times;
}
if (curr->timer->s.endtime > curr->timer->s.starttime) {
switch (curr->timer->s.type) {
case OCD_TIMER_D2H:
((cl_ulong *) time)[1] += curr->timer->s.endtime - curr->timer->s.starttime;
totalTimes[1] +=curr->timer->s.endtime - curr->timer->s.starttime;
break;
case OCD_TIMER_H2D:
((cl_ulong *) time)[2] += curr->timer->s.endtime - curr->timer->s.starttime;
totalTimes[2] +=curr->timer->s.endtime - curr->timer->s.starttime;
break;
case OCD_TIMER_D2D:
((cl_ulong *) time)[3] += curr->timer->s.endtime - curr->timer->s.starttime;
totalTimes[3] +=curr->timer->s.endtime - curr->timer->s.starttime;
break;
case OCD_TIMER_KERNEL:
((cl_ulong *) time)[4] += curr->timer->s.endtime - curr->timer->s.starttime;
totalTimes[4] +=curr->timer->s.endtime - curr->timer->s.starttime;
break;
case OCD_TIMER_HOST:
((cl_ulong *) time)[5] += curr->timer->s.endtime - curr->timer->s.starttime;
totalTimes[5] +=curr->timer->s.endtime - curr->timer->s.starttime;
break;
case OCD_TIMER_DUAL:
((cl_ulong *) time)[6] += curr->timer->s.endtime - curr->timer->s.starttime;
totalTimes[6] +=curr->timer->s.endtime - curr->timer->s.starttime;
break;
}
((cl_ulong *) time)[0] += curr->timer->s.endtime - curr->timer->s.starttime;
}
curr = curr->next;
}
totalTimes[0] = fullExecTimer.endtime - fullExecTimer.starttime;
}
//assumes simpleNameTally was already called (once) to add up timers
//now culls off zero-value timers
void simpleNamePrint() {
struct timer_name_tree_node * curr = &root;
while (curr != NULL) { //still unique names to be checked
if (curr->times[0] > 0) {if (strcmp(curr->string, rootStr) != 0) {// if the string isn't empty
printf("Timer [%s]: \t %llu\n", curr->string, curr->times[0]);
} else {
printf("Unnamed Timers: \t %llu\n", curr->times[0]);
}
if (curr->times[1] > 0) printf("\tD2H: \t %llu\n", curr->times[1]);
if (curr->times[2] > 0) printf("\tH2D: \t %llu\n", curr->times[2]);
if (curr->times[3] > 0) printf("\tD2D: \t %llu\n", curr->times[3]);
if (curr->times[4] > 0) printf("\tKernel: \t %llu\n", curr->times[4]);
if (curr->times[5] > 0) printf("\tHost: \t %llu\n", curr->times[5]);
if (curr->times[6] > 0) printf("\tDual: \t %llu\n", curr->times[6]);
}
curr = curr->next;
}
}
//chews up the timer list from head to tail, deallocating all nodes
void destTimerList() {
struct timer_group_mem * temp, * curr = head.next;
temp = curr;
//make sure we can't try to do another cleanup
head.next = NULL;
while (curr != NULL) {
//slide the window
curr = curr->next;
//cleanup behind
if (temp != NULL) {
if (temp->timer !=NULL) free(temp->timer);
free(temp);
}
//catch up
temp = curr;
}
}
//chews up the simpleNameList from root to atail, deallocating all nodes
void destNameList() {
struct timer_name_tree_node * temp, * curr = root.next;
temp = curr;
//make sure we can't try to do another cleanup
root.next = NULL;
while (curr != NULL) {
curr=curr->next;
if (temp !=NULL) {
if (temp->times != NULL) free(temp->times);
free(temp);
}
temp = curr;
}
}
void * getTimePtr(cl_event e) {
struct timer_group_mem * curr = head.next;
while (curr != 0) {
//if composed, will be a negative value
if (curr->timer->s.type > 0) {
if (curr->timer->s.event == e) return (void *) curr->timer;
}
curr = curr->next;
}
return (void *) - 1;
}
//only returns a composed timer with events matching both e1 and e2, in either order
void * getDualTimePtr(cl_event e1, cl_event e2) {
struct timer_group_mem * curr = head.next;
while (curr != 0) {
//if composed, will be a negative value
if (curr->timer->s.type < 0) {
if ((curr->timer->c.event[0] == e1 \
&& curr->timer->c.event[1] == e2) \
|| (curr->timer->c.event[0] == e2 \
&& curr->timer->c.event[1] == e1)) \
return (void *) curr->timer;
}
curr = curr->next;
}
return (void *) - 1;
}
//simply adds timer t to the end of the list
void addTimer(union ocdInternalTimer * t) {
if (head.next == NULL) { //no members
tail = &head; //reset tail, just incase
} else {
while (tail->next != NULL) { //slide tail to the end
tail = tail->next;
}
}
struct timer_group_mem * temp_wrap = (struct timer_group_mem *) calloc(sizeof (struct timer_group_mem), 1);
temp_wrap->next = NULL;
temp_wrap->timer = t;
tail->next = temp_wrap;
tail = temp_wrap;
}
//irreversible! Only call immediately before freeing the timer!
int removeTimer(union ocdInternalTimer * t) {
struct timer_group_mem * curr = head.next, * old = &head;
while (curr != 0 && curr->timer != t) {
old = curr;
curr = curr->next;
}
if (curr != 0) {
if (curr->next == 0) { //we are the tail!
tail = old; //so back the tail up one
}
old->next = curr->next;
free(curr);
return 0;
}
return -1; // probably should free(groups) somehow
}
#ifdef TIMER_TEST
//Debug call for checking list construction
void walkList() {
struct timer_group_mem * curr = head.next;
fprintf(stderr, "Walking list starting at [%lx]--[%lx]\n", (unsigned long) &head, (unsigned long) head.timer);
while (curr != 0) {
fprintf(stderr, "\t[%lx]--[%lx]\n", (unsigned long) curr, (unsigned long) curr->timer->s.event);
curr = curr->next;
}
}
#endif //TIMER_TEST
#endif //ENABLE_TIMER
cl_device_id
GetDevice(int platform, int device) {
cl_int err;
cl_uint nPlatforms = 1;
err = clGetPlatformIDs(0, NULL, &nPlatforms);
CHECK_ERROR(err);
if (nPlatforms <= 0) {
printf("No OpenCL platforms found. Exiting.\n");
exit(0);
}
if (platform < 0 || platform >= nPlatforms) // platform ID out of range
{
printf("Platform index %d is out of range. \n", platform);
exit(-4);
}
cl_platform_id *platforms = (cl_platform_id *) malloc(sizeof (cl_platform_id) * nPlatforms);
err = clGetPlatformIDs(nPlatforms, platforms, NULL);
CHECK_ERROR(err);
cl_uint nDevices = 1;
char platformName[100];
err = clGetPlatformInfo(platforms[0], CL_PLATFORM_VENDOR, sizeof (platformName), platformName, NULL);
CHECK_ERROR(err);
printf("Platform Chosen : %s\n", platformName);
// query devices
err = clGetDeviceIDs(platforms[platform], USEGPU ? CL_DEVICE_TYPE_GPU : CL_DEVICE_TYPE_CPU, 0, NULL, &nDevices);
CHECK_ERROR(err);
if (nDevices <= 0) {
printf("No OpenCL Device found. Exiting.\n");
exit(0);
}
if (device < 0 || device >= nDevices) // platform ID out of range
{
printf("Device index %d is out of range. \n", device);
exit(-4);
}
cl_device_id* devices = (cl_device_id *) malloc(sizeof (cl_device_id) * nDevices);
err = clGetDeviceIDs(platforms[platform], USEGPU ? CL_DEVICE_TYPE_GPU : CL_DEVICE_TYPE_CPU, nDevices, devices, NULL);
CHECK_ERROR(err);
char DeviceName[100];
err = clGetDeviceInfo(devices[device], CL_DEVICE_NAME, sizeof (DeviceName), DeviceName, NULL);
CHECK_ERROR(err);
printf("Device Chosen : %s\n", DeviceName);
return devices[device];
}
const char *get_error_string(cl_int err){
switch(err){
case 0: return "CL_SUCCESS";
case -1: return "CL_DEVICE_NOT_FOUND";
case -2: return "CL_DEVICE_NOT_AVAILABLE";
case -3: return "CL_COMPILER_NOT_AVAILABLE";
case -4: return "CL_MEM_OBJECT_ALLOCATION_FAILURE";
case -5: return "CL_OUT_OF_RESOURCES";
case -6: return "CL_OUT_OF_HOST_MEMORY";
case -7: return "CL_PROFILING_INFO_NOT_AVAILABLE";
case -8: return "CL_MEM_COPY_OVERLAP";
case -9: return "CL_IMAGE_FORMAT_MISMATCH";
case -10: return "CL_IMAGE_FORMAT_NOT_SUPPORTED";
case -11: return "CL_BUILD_PROGRAM_FAILURE";
case -12: return "CL_MAP_FAILURE";
case -30: return "CL_INVALID_VALUE";
case -31: return "CL_INVALID_DEVICE_TYPE";
case -32: return "CL_INVALID_PLATFORM";
case -33: return "CL_INVALID_DEVICE";
case -34: return "CL_INVALID_CONTEXT";
case -35: return "CL_INVALID_QUEUE_PROPERTIES";
case -36: return "CL_INVALID_COMMAND_QUEUE";
case -37: return "CL_INVALID_HOST_PTR";
case -38: return "CL_INVALID_MEM_OBJECT";
case -39: return "CL_INVALID_IMAGE_FORMAT_DESCRIPTOR";
case -40: return "CL_INVALID_IMAGE_SIZE";
case -41: return "CL_INVALID_SAMPLER";
case -42: return "CL_INVALID_BINARY";
case -43: return "CL_INVALID_BUILD_OPTIONS";
case -44: return "CL_INVALID_PROGRAM";
case -45: return "CL_INVALID_PROGRAM_EXECUTABLE";
case -46: return "CL_INVALID_KERNEL_NAME";
case -47: return "CL_INVALID_KERNEL_DEFINITION";
case -48: return "CL_INVALID_KERNEL";
case -49: return "CL_INVALID_ARG_INDEX";
case -50: return "CL_INVALID_ARG_VALUE";
case -51: return "CL_INVALID_ARG_SIZE";
case -52: return "CL_INVALID_KERNEL_ARGS";
case -53: return "CL_INVALID_WORK_DIMENSION";
case -54: return "CL_INVALID_WORK_GROUP_SIZE";
case -55: return "CL_INVALID_WORK_ITEM_SIZE";
case -56: return "CL_INVALID_GLOBAL_OFFSET";
case -57: return "CL_INVALID_EVENT_WAIT_LIST";
case -58: return "CL_INVALID_EVENT";
case -59: return "CL_INVALID_OPERATION";
case -60: return "CL_INVALID_GL_OBJECT";
case -61: return "CL_INVALID_BUFFER_SIZE";
case -62: return "CL_INVALID_MIP_LEVEL";
case -63: return "CL_INVALID_GLOBAL_WORK_SIZE";
default: return "Unknown OpenCL error";
}
}