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rocm-systems/test/ctrl/tool.cpp
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///////////////////////////////////////////////////////////////////////////////
// //
// Test tool used as ROC profiler library demo //
// //
///////////////////////////////////////////////////////////////////////////////
#include <hsa.h>
#include <pthread.h>
#include <stdio.h>
#include <stdlib.h>
#include <iostream>
#include <map>
#include <sstream>
#include <string>
#include <vector>
#include "inc/rocprofiler.h"
#include "util/xml.h"
#define PUBLIC_API __attribute__((visibility("default")))
#define CONSTRUCTOR_API __attribute__((constructor))
#define DESTRUCTOR_API __attribute__((destructor))
// Disoatch callback data type
struct dispatch_data_t {
rocprofiler_feature_t* features;
unsigned feature_count;
unsigned group_index;
FILE* file_handle;
};
// Context stored entry type
struct context_entry_t {
uint32_t index;
rocprofiler_group_t group;
rocprofiler_feature_t* features;
unsigned feature_count;
rocprofiler_callback_data_t data;
FILE* file_handle;
};
// Dispatch callbacks and context handlers synchronization
pthread_mutex_t mutex = PTHREAD_MUTEX_INITIALIZER;
// Stored contexts array size
unsigned context_array_size = 1;
// Stored contexts array
context_entry_t* context_array = NULL;
// Number of stored contexts
unsigned context_array_count = 0;
// Profiling results output file name
const char* result_prefix = NULL;
// Check returned HSA API status
void check_status(hsa_status_t status) {
if (status != HSA_STATUS_SUCCESS) {
const char* error_string = NULL;
rocprofiler_error_string(&error_string);
fprintf(stderr, "ERROR: %s\n", error_string);
exit(1);
}
}
// Allocate entry to store profiling context
context_entry_t* alloc_context_entry() {
context_entry_t* ptr = 0;
if (pthread_mutex_lock(&mutex) != 0) {
perror("pthread_mutex_lock");
exit(1);
}
if ((context_array == NULL) || (context_array_count >= context_array_size)) {
context_array_size *= 2;
context_array = reinterpret_cast<context_entry_t*>(
realloc(context_array, context_array_size * sizeof(context_entry_t)));
}
ptr = &context_array[context_array_count];
*ptr = {};
ptr->index = context_array_count;
context_array_count += 1;
if (pthread_mutex_unlock(&mutex) != 0) {
perror("pthread_mutex_unlock");
exit(1);
}
return ptr;
}
// Dump trace data to file
void dump_sqtt_trace(const uint32_t chunk, const void* data, const uint32_t& size) {
if (result_prefix != NULL) {
// Opening SQTT file
std::ostringstream oss;
oss << result_prefix << "/thread_trace.se" << chunk << ".out";
FILE* file = fopen(oss.str().c_str(), "w");
if (file == NULL) {
perror("result file fopen");
exit(1);
}
// Write the buffer in terms of shorts (16 bits)
const unsigned short* ptr = reinterpret_cast<const unsigned short*>(data);
for (uint32_t i = 0; i < (size / sizeof(short)); ++i) {
fprintf(file, "%04x\n", ptr[i]);
}
}
}
// Trace data callback for getting trace data from GPU local mamory
hsa_status_t trace_data_cb(hsa_ven_amd_aqlprofile_info_type_t info_type,
hsa_ven_amd_aqlprofile_info_data_t* info_data, void* data) {
FILE* file = reinterpret_cast<FILE*>(data);
hsa_status_t status = HSA_STATUS_SUCCESS;
if (info_type == HSA_VEN_AMD_AQLPROFILE_INFO_SQTT_DATA) {
fprintf(file, " SE(%u) size(%u)\n", info_data->sample_id, info_data->sqtt_data.size);
dump_sqtt_trace(info_data->sample_id, info_data->sqtt_data.ptr, info_data->sqtt_data.size);
} else
status = HSA_STATUS_ERROR;
return status;
}
// Align to specified alignment
unsigned align_size(unsigned size, unsigned alignment) {
return ((size + alignment - 1) & ~(alignment - 1));
}
// Output profiling results for input features
void output_results(FILE* file, const rocprofiler_feature_t* features, const unsigned feature_count,
rocprofiler_t* context, const char* str) {
if (str) fprintf(file, "%s:\n", str);
for (unsigned i = 0; i < feature_count; ++i) {
const rocprofiler_feature_t* p = &features[i];
fprintf(file, " %s ", p->name);
switch (p->data.kind) {
// Output metrics results
case ROCPROFILER_DATA_KIND_INT64:
fprintf(file, "(%lu)\n", p->data.result_int64);
break;
// Output trace results
case ROCPROFILER_DATA_KIND_BYTES: {
if (p->data.result_bytes.copy) {
uint64_t size = 0;
const char* ptr = reinterpret_cast<const char*>(p->data.result_bytes.ptr);
for (unsigned i = 0; i < p->data.result_bytes.instance_count; ++i) {
const uint32_t chunk_size = *reinterpret_cast<const uint64_t*>(ptr);
const char* chunk_data = ptr + sizeof(uint64_t);
dump_sqtt_trace(i, chunk_data, chunk_size);
const uint32_t off = align_size(chunk_size, sizeof(uint64_t));
ptr = chunk_data + off;
size += chunk_size;
}
fprintf(file, "size(%lu)\n", size);
if (size > p->data.result_bytes.size) {
fprintf(stderr, "SQTT data size is out of the result buffer size\n");
exit(1);
}
} else {
//fprintf(file, "iterate GPU local memory ");
fprintf(file, "(\n");
rocprofiler_iterate_trace_data(context, trace_data_cb, reinterpret_cast<void*>(file));
fprintf(file, " )\n");
}
break;
}
default:
std::cout << "Bad result kind (" << p->data.kind << ")" << std::endl;
}
}
}
// Output group intermeadate profiling results, created internally for complex metrics
void output_group(FILE* file, const rocprofiler_group_t* group, const char* str) {
if (str) fprintf(file, "%s:\n", str);
for (unsigned i = 0; i < group->feature_count; ++i) {
output_results(file, group->features[i], 1, group->context, NULL);
}
}
// Dump stored context profiling output data
void dump_context(context_entry_t* entry) {
hsa_status_t status = HSA_STATUS_ERROR;
const rocprofiler_feature_t* features = entry->features;
if (features) {
rocprofiler_group_t group = entry->group;
uint32_t index = entry->index;
const unsigned feature_count = entry->feature_count;
FILE* file_handle = entry->file_handle;
fprintf(file_handle,
"Dispatch[%u], queue_index(%lu), kernel_object(0x%lx), kernel_name(\"%s\"):\n", index,
entry->data.queue_index, entry->data.kernel_object, entry->data.kernel_name);
status = rocprofiler_group_get_data(&group);
check_status(status);
// output_group(file, group, "Group[0] data");
status = rocprofiler_get_metrics(group.context);
check_status(status);
output_results(file_handle, features, feature_count, group.context, NULL);
// Finishing cleanup
// Deleting profiling context will delete all allocated resources
rocprofiler_close(group.context);
entry->features = NULL;
}
}
// Dump all stored contexts profiling output data
void dump_context_array() {
if (pthread_mutex_lock(&mutex) != 0) {
perror("pthread_mutex_lock");
exit(1);
}
for (unsigned index = 0; index < context_array_count; ++index) {
dump_context(&context_array[index]);
}
if (pthread_mutex_unlock(&mutex) != 0) {
perror("pthread_mutex_unlock");
exit(1);
}
}
// Profiling completion handler
void handler(rocprofiler_group_t group, void* arg) {
if (pthread_mutex_lock(&mutex) != 0) {
perror("pthread_mutex_lock");
exit(1);
}
context_entry_t* entry = reinterpret_cast<context_entry_t*>(arg);
dump_context(entry);
if (pthread_mutex_unlock(&mutex) != 0) {
perror("pthread_mutex_unlock");
exit(1);
}
}
// Kernel disoatch callback
hsa_status_t dispatch_callback(const rocprofiler_callback_data_t* callback_data, void* user_data,
rocprofiler_group_t* group) {
// HSA status
hsa_status_t status = HSA_STATUS_ERROR;
// Passed tool data
dispatch_data_t* tool_data = reinterpret_cast<dispatch_data_t*>(user_data);
// Profiling context
rocprofiler_t* context = NULL;
// Context entry
context_entry_t* entry = alloc_context_entry();
// context properties
rocprofiler_properties_t properties{};
properties.handler = (result_prefix != NULL) ? handler : NULL;
properties.handler_arg = (void*)entry;
// Open profiling context
status = rocprofiler_open(callback_data->agent, tool_data->features, tool_data->feature_count,
&context, 0 /*ROCPROFILER_MODE_SINGLEGROUP*/, &properties);
check_status(status);
// Check that we have only one profiling group
uint32_t group_count = 0;
status = rocprofiler_group_count(context, &group_count);
check_status(status);
assert(group_count == 1);
// Get group[0]
const uint32_t group_index = 0;
status = rocprofiler_get_group(context, group_index, group);
check_status(status);
// Fill profiling context entry
entry->group = *group;
entry->features = tool_data->features;
entry->feature_count = tool_data->feature_count;
entry->data = *callback_data;
entry->file_handle = tool_data->file_handle;
return status;
}
// Tool constructor
CONSTRUCTOR_API void constructor() {
std::map<std::string, hsa_ven_amd_aqlprofile_parameter_name_t> parameters_dict;
parameters_dict["HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_COMPUTE_UNIT_TARGET"] =
HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_COMPUTE_UNIT_TARGET;
parameters_dict["HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_VM_ID_MASK"] =
HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_VM_ID_MASK;
parameters_dict["HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_MASK"] =
HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_MASK;
parameters_dict["HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_TOKEN_MASK"] =
HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_TOKEN_MASK;
parameters_dict["HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_TOKEN_MASK2"] =
HSA_VEN_AMD_AQLPROFILE_PARAMETER_NAME_TOKEN_MASK2;
// Set output file
result_prefix = getenv("ROCP_OUTPUT_DIR");
FILE* file_handle = NULL;
if (result_prefix != NULL) {
std::ostringstream oss;
oss << result_prefix << "/results.txt";
file_handle = fopen(oss.str().c_str(), "w");
if (file_handle == NULL) {
perror("result file fopen");
exit(1);
}
} else
file_handle = stdout;
// Getting input
const char* xml_name = getenv("ROCP_INPUT");
if (xml_name == NULL) {
fprintf(stderr, "ROCProfiler: input is not specified, ROCP_INPUT env");
exit(1);
}
printf("ROCProfiler: input from \"%s\"\n", xml_name);
xml::Xml* xml = xml::Xml::Create(xml_name);
if (xml == NULL) {
fprintf(stderr, "Input file not found '%s'\n", xml_name);
exit(1);
}
// Getting metrics
auto metrics_list = xml->GetNodes("top.metric");
std::vector<std::string> metrics_vec;
for (auto* entry : metrics_list) {
const std::string entry_str = entry->opts["name"];
size_t pos1 = 0;
while (pos1 < entry_str.length()) {
const size_t pos2 = entry_str.find(",", pos1);
const std::string metric_name = entry_str.substr(pos1, pos2 - pos1);
metrics_vec.push_back(metric_name);
if (pos2 == std::string::npos) break;
pos1 = pos2 + 1;
}
}
// Getting traces
auto traces_list = xml->GetNodes("top.trace");
const unsigned feature_count = metrics_vec.size() + traces_list.size();
rocprofiler_feature_t* features = new rocprofiler_feature_t[feature_count];
memset(features, 0, feature_count * sizeof(rocprofiler_feature_t));
printf(" %d metrics\n", (int)metrics_vec.size());
for (unsigned i = 0; i < metrics_vec.size(); ++i) {
const std::string& name = metrics_vec[i];
printf("%s%s", (i == 0) ? " " : ", ", name.c_str());
features[i] = {};
features[i].kind = ROCPROFILER_FEATURE_KIND_METRIC;
features[i].name = strdup(name.c_str());
}
if (metrics_vec.size()) printf("\n");
printf(" %d traces\n", (int)traces_list.size());
unsigned index = metrics_vec.size();
for (auto* entry : traces_list) {
auto params_list = xml->GetNodes("top.trace.parameters");
if (params_list.size() != 1) {
fprintf(stderr, "ROCProfiler: Single input 'parameters' section is supported\n");
exit(1);
}
const std::string& name = entry->opts["name"];
const bool to_copy_data = (entry->opts["copy"] == "true");
printf(" %s (\n", name.c_str());
features[index] = {};
features[index].kind = ROCPROFILER_FEATURE_KIND_TRACE;
features[index].name = strdup(name.c_str());
features[index].data.result_bytes.copy = to_copy_data;
for (auto* params : params_list) {
const unsigned parameter_count = params->opts.size();
rocprofiler_parameter_t* parameters = new rocprofiler_parameter_t[parameter_count];
unsigned p_index = 0;
for (auto& v : params->opts) {
const std::string parameter_name = v.first;
if (parameters_dict.find(parameter_name) == parameters_dict.end()) {
fprintf(stderr, "ROCProfiler: unknown trace parameter %s\n", parameter_name.c_str());
exit(1);
}
const uint32_t value = strtol(v.second.c_str(), NULL, 0);
printf(" %s = 0x%x\n", parameter_name.c_str(), value);
parameters[p_index] = {};
parameters[p_index].parameter_name = parameters_dict[parameter_name];
parameters[p_index].value = value;
++p_index;
}
features[index].parameters = parameters;
features[index].parameter_count = parameter_count;
}
printf(" )\n");
++index;
}
// Adding dispatch observer
if (feature_count) {
dispatch_data_t* dispatch_data = new dispatch_data_t{};
dispatch_data->features = features;
dispatch_data->feature_count = feature_count;
dispatch_data->group_index = 0;
dispatch_data->file_handle = file_handle;
rocprofiler_set_dispatch_callback(dispatch_callback, dispatch_data);
}
}
// Tool destructor
DESTRUCTOR_API void destructor() {
printf("\nROCPRofiler: %u contexts collected", context_array_count);
if (result_prefix == NULL) {
printf("\n");
} else {
printf(", dumping to %s\n", result_prefix);
}
// Dump profiling output data which hasn't yet dumped by completi onhandler
dump_context_array();
}