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onnx_trt_backend.cpp
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onnx_trt_backend.cpp
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/*
* SPDX-License-Identifier: Apache-2.0
*/
#include "NvOnnxParser.h"
#include "onnx/onnxifi.h"
#include <NvInfer.h>
#include <atomic>
#include <ctime>
#include <cuda_runtime.h>
#include <mutex>
#include <thrust/device_vector.h>
#include <unordered_map>
#define BACKEND_NAME "TensorRT"
#define BACKEND_VENDOR "Nvidia"
#define BACKEND_VERSION "1.0.0"
#define BACKEND_EXTENSIONS ""
#define BACKEND_IR_VERSION "3"
#define BACKEND_OPSET_VERSION "ai.onnx:7"
namespace
{
struct InferDeleter
{
template <typename T>
void operator()(T* obj) const
{
if (obj)
{
obj->destroy();
}
}
};
template <typename T>
inline std::shared_ptr<T> infer_object(T* obj)
{
if (!obj)
{
throw std::runtime_error("Failed to create object");
}
return std::shared_ptr<T>(obj, InferDeleter());
}
// Logger for TRT info/warning/errors
class TRT_Logger : public nvinfer1::ILogger
{
nvinfer1::ILogger::Severity _verbosity;
std::ostream* _ostream;
public:
TRT_Logger(Severity verbosity = Severity::kWARNING, std::ostream& ostream = std::cout)
: _verbosity(verbosity)
, _ostream(&ostream)
{
}
void log(Severity severity, const char* msg) override
{
if (severity <= _verbosity)
{
time_t rawtime = std::time(0);
char buf[256];
strftime(&buf[0], 256, "%Y-%m-%d %H:%M:%S", std::gmtime(&rawtime));
const char* sevstr = (severity == Severity::kINTERNAL_ERROR ? " BUG" : severity == Severity::kERROR
? " ERROR"
: severity == Severity::kWARNING ? "WARNING" : severity == Severity::kINFO ? " INFO"
: "UNKNOWN");
(*_ostream) << "[" << buf << " " << sevstr << "] " << msg << std::endl;
}
}
};
onnxStatus CheckShape(const nvinfer1::Dims& dims, const onnxTensorDescriptorV1& desc, bool allow_same_size)
{
bool matched = false;
if (desc.dimensions == static_cast<uint32_t>(dims.nbDims) + 1)
{
matched = true;
for (int i = 0; i < dims.nbDims; ++i)
{
if (desc.shape[i + 1] != static_cast<uint64_t>(dims.d[i]))
{
return ONNXIFI_STATUS_MISMATCHING_SHAPE;
}
}
}
else if (allow_same_size && desc.dimensions > 1)
{
size_t dim_size = 1;
for (int i = 0; i < dims.nbDims; ++i)
{
dim_size *= dims.d[i];
}
size_t desc_size = 1;
// Skip the first dim which is batch size
for (uint32_t i = 1; i < desc.dimensions; ++i)
{
desc_size *= desc.shape[i];
}
matched = (dim_size == desc_size) ? true : false;
if (!matched)
{
std::cerr << "mismatched output " << desc.name << ": " << desc_size << " vs " << dim_size << std::endl;
}
}
return matched ? ONNXIFI_STATUS_SUCCESS : ONNXIFI_STATUS_MISMATCHING_SHAPE;
}
size_t GetTensorFootprint(const onnxTensorDescriptorV1& input)
{
size_t acc = 1;
for (unsigned i = 0; i < input.dimensions; ++i)
{
acc *= input.shape[i];
}
size_t multiplier = 1;
switch (input.dataType)
{
case ONNXIFI_DATATYPE_FLOAT16: multiplier = sizeof(float) / 2; break;
case ONNXIFI_DATATYPE_FLOAT32: multiplier = sizeof(float); break;
case ONNXIFI_DATATYPE_INT8: multiplier = sizeof(int8_t); break;
case ONNXIFI_DATATYPE_INT16: multiplier = sizeof(int16_t); break;
case ONNXIFI_DATATYPE_INT32: multiplier = sizeof(int32_t); break;
case ONNXIFI_DATATYPE_UINT8: multiplier = sizeof(uint8_t); break;
case ONNXIFI_DATATYPE_UINT16: multiplier = sizeof(uint16_t); break;
case ONNXIFI_DATATYPE_UINT32: multiplier = sizeof(uint32_t); break;
default: multiplier = 0;
}
return acc * multiplier;
}
struct OnnxTensorRTBackendID
{
OnnxTensorRTBackendID(int i)
: device_id(i)
{
}
int device_id{0};
};
class OnnxTensorRTEvent
{
public:
OnnxTensorRTEvent(cudaStream_t s)
: stream_(s)
{
if (cudaEventCreateWithFlags(&event_, cudaEventDisableTiming) != cudaSuccess)
{
throw std::runtime_error("Cannot create cudaEvent");
}
}
~OnnxTensorRTEvent()
{
cudaEventDestroy(event_);
}
onnxStatus Signal()
{
std::lock_guard<std::mutex> guard(mutex_);
if (fired_)
{
return ONNXIFI_STATUS_INVALID_STATE;
}
if (cudaEventRecord(event_, stream_) == cudaSuccess)
{
fired_ = true;
return ONNXIFI_STATUS_SUCCESS;
}
else
{
return ONNXIFI_STATUS_INTERNAL_ERROR;
}
}
onnxStatus Wait()
{
std::lock_guard<std::mutex> guard(mutex_);
return (cudaEventSynchronize(event_) == cudaSuccess) ? ONNXIFI_STATUS_SUCCESS : ONNXIFI_STATUS_INTERNAL_ERROR;
}
onnxStatus CheckState(onnxEventState* state)
{
std::lock_guard<std::mutex> guard(mutex_);
if (!fired_)
{
*state = ONNXIFI_EVENT_STATE_NONSIGNALLED;
return ONNXIFI_STATUS_SUCCESS;
}
auto rt = cudaEventQuery(event_);
if (rt == cudaErrorNotReady)
{
*state = ONNXIFI_EVENT_STATE_NONSIGNALLED;
return ONNXIFI_STATUS_SUCCESS;
}
else if (rt == cudaSuccess)
{
*state = ONNXIFI_EVENT_STATE_SIGNALLED;
return ONNXIFI_STATUS_SUCCESS;
}
else
{
*state = ONNXIFI_EVENT_STATE_INVALID;
return ONNXIFI_STATUS_INVALID_STATE;
}
}
private:
std::mutex mutex_;
std::atomic<bool> fired_{false};
cudaStream_t stream_{0};
cudaEvent_t event_;
};
class CudaDeviceGuard
{
public:
CudaDeviceGuard(int backend_id)
{
if (cudaGetDevice(&saved_device_) != cudaSuccess)
{
throw std::runtime_error("Cannot run cudaGetDevice");
}
if (saved_device_ != backend_id)
{
if (cudaSetDevice(backend_id) != cudaSuccess)
{
throw std::runtime_error("Cannot run cudaSetDevice");
}
need_restore_ = true;
}
}
~CudaDeviceGuard()
{
if (need_restore_)
{
cudaSetDevice(saved_device_);
}
}
private:
int saved_device_{-1};
bool need_restore_{false};
};
class OnnxTensorRTBackendRep
{
public:
OnnxTensorRTBackendRep(const OnnxTensorRTBackendID& backend_id)
: device_id_(backend_id.device_id)
{
trt_builder_ = infer_object(nvinfer1::createInferBuilder(trt_logger_));
trt_builder_->setMaxBatchSize(max_batch_size_);
trt_builder_->setMaxWorkspaceSize(max_workspace_size_);
trt_network_ = infer_object(trt_builder_->createNetwork());
parser_ = infer_object(nvonnxparser::createParser(*trt_network_, trt_logger_));
CudaDeviceGuard guard(device_id_);
if (cudaStreamCreate(&stream_) != cudaSuccess)
{
throw std::runtime_error("Cannot create cudaStream");
}
}
~OnnxTensorRTBackendRep()
{
cudaStreamDestroy(stream_);
}
int device_id() const
{
return device_id_;
}
cudaStream_t stream() const
{
return stream_;
}
onnxStatus ImportModel(void const* serialized_onnx_model, size_t serialized_onnx_model_size, uint32_t weight_count,
onnxTensorDescriptorV1 const* weight_descriptors)
{
auto succeeded = parser_->parseWithWeightDescriptors(
serialized_onnx_model, serialized_onnx_model_size, weight_count, weight_descriptors);
if (!succeeded)
{
const auto num_errors = parser_->getNbErrors();
if (num_errors > 0)
{
const auto* error = parser_->getError(num_errors - 1);
std::cerr << "Parsing error: " << error->desc() << " at " << error->file() << ":" << error->line()
<< " (" << error->func() << ")." << std::endl;
switch (error->code())
{
case nvonnxparser::ErrorCode::kMEM_ALLOC_FAILED: return ONNXIFI_STATUS_NO_SYSTEM_MEMORY;
case nvonnxparser::ErrorCode::kMODEL_DESERIALIZE_FAILED: return ONNXIFI_STATUS_INVALID_PROTOBUF;
case nvonnxparser::ErrorCode::kINVALID_VALUE: return ONNXIFI_STATUS_UNSUPPORTED_ATTRIBUTE;
case nvonnxparser::ErrorCode::kINVALID_GRAPH:
case nvonnxparser::ErrorCode::kINVALID_NODE: return ONNXIFI_STATUS_INVALID_MODEL;
case nvonnxparser::ErrorCode::kUNSUPPORTED_NODE:
case nvonnxparser::ErrorCode::kUNSUPPORTED_GRAPH: return ONNXIFI_STATUS_UNSUPPORTED_OPERATOR;
default: return ONNXIFI_STATUS_INTERNAL_ERROR;
}
}
}
return ONNXIFI_STATUS_SUCCESS;
}
nvinfer1::ICudaEngine* buildCudaEngine()
{
return trt_builder_->buildCudaEngine(*trt_network_);
}
size_t max_batch_size() const
{
return max_batch_size_;
}
private:
TRT_Logger trt_logger_;
cudaStream_t stream_;
std::shared_ptr<nvinfer1::IBuilder> trt_builder_{nullptr};
std::shared_ptr<nvinfer1::INetworkDefinition> trt_network_{nullptr};
std::shared_ptr<nvonnxparser::IParser> parser_{nullptr};
// TODO: configerable max batch size
int device_id_{0};
size_t max_batch_size_{128};
size_t max_workspace_size_{1024UL * 1024UL * 1024UL * 2UL};
};
class GraphRep
{
public:
GraphRep(OnnxTensorRTBackendRep* backendrep)
: device_id_(backendrep->device_id())
, max_batch_size_(backendrep->max_batch_size())
, stream_(backendrep->stream())
{
if (cudaSetDevice(device_id_) != cudaSuccess)
{
throw std::runtime_error("Cannot set CUDA device");
}
trt_engine_ = infer_object(backendrep->buildCudaEngine());
max_batch_size_ = backendrep->max_batch_size();
}
~GraphRep()
{
ClearDeviceBuffers();
}
onnxStatus InitIO(uint32_t inputsCount, const onnxTensorDescriptorV1* inputDescriptors, uint32_t outputsCount,
const onnxTensorDescriptorV1* outputDescriptors);
onnxStatus Run();
cudaStream_t stream() const
{
return stream_;
}
private:
void ClearDeviceBuffers();
onnxStatus CheckAndBindTensor(const nvinfer1::Dims& dims, const onnxTensorDescriptorV1& tensor, bool is_output);
std::shared_ptr<nvinfer1::ICudaEngine> trt_engine_{nullptr};
std::shared_ptr<nvinfer1::IExecutionContext> trt_executor_{nullptr};
std::vector<void*> bindings_;
std::unordered_map<std::string, const onnxTensorDescriptorV1*> input_map_;
std::unordered_map<std::string, const onnxTensorDescriptorV1*> output_map_;
std::unordered_map<std::string, void*> device_buffers_;
int device_id_{0};
size_t max_batch_size_{0};
size_t batch_size_{0};
cudaStream_t stream_;
};
void GraphRep::ClearDeviceBuffers()
{
for (auto kv : device_buffers_)
{
cudaFree(kv.second);
}
device_buffers_.clear();
}
onnxStatus GraphRep::CheckAndBindTensor(
const nvinfer1::Dims& dims, const onnxTensorDescriptorV1& tensor, bool is_output)
{
// Check memory type
if (tensor.memoryType != ONNXIFI_MEMORY_TYPE_CPU && tensor.memoryType != ONNXIFI_MEMORY_TYPE_CUDA_BUFFER)
{
return ONNXIFI_STATUS_INVALID_DATATYPE;
}
// Check tensor shape
auto ret = CheckShape(dims, tensor, is_output);
if (ret != ONNXIFI_STATUS_SUCCESS)
{
return ret;
}
// For CPU tensor, we need to create a device memory and the bind. For CUDA
// tensor, we can bind directly
if (tensor.memoryType == ONNXIFI_MEMORY_TYPE_CPU)
{
void* cuda_buffer;
size_t footprint = GetTensorFootprint(tensor);
if (!footprint)
{
return ONNXIFI_STATUS_INVALID_SHAPE;
}
if (cudaMalloc(&cuda_buffer, footprint) != cudaSuccess)
{
return ONNXIFI_STATUS_NO_DEVICE_MEMORY;
}
device_buffers_.emplace(tensor.name, cuda_buffer);
bindings_.push_back(cuda_buffer);
}
else
{
bindings_.push_back((void*) (tensor.buffer));
}
return ONNXIFI_STATUS_SUCCESS;
}
onnxStatus GraphRep::InitIO(uint32_t inputsCount, const onnxTensorDescriptorV1* inputDescriptors, uint32_t outputsCount,
const onnxTensorDescriptorV1* outputDescriptors)
{
CudaDeviceGuard guard(device_id_);
ClearDeviceBuffers();
// Setup the input/output bindings and decide batch size
for (unsigned i = 0; i < inputsCount; ++i)
{
if (inputDescriptors[i].tag != ONNXIFI_TAG_TENSOR_DESCRIPTOR_V1)
{
return ONNXIFI_STATUS_UNSUPPORTED_TAG;
}
if (!inputDescriptors[i].name)
{
return ONNXIFI_STATUS_INVALID_NAME;
}
// We only support NCHW
if (inputDescriptors[i].dimensions != 4)
{
return ONNXIFI_STATUS_INVALID_SHAPE;
}
if (i == 0)
{
batch_size_ = inputDescriptors[i].shape[0];
}
else
{
if (batch_size_ != inputDescriptors[i].shape[0])
{
return ONNXIFI_STATUS_INVALID_SHAPE;
}
}
std::cerr << "Adding input " << i << ": " << inputDescriptors[i].name
<< ", type: " << inputDescriptors[i].memoryType << std::endl;
input_map_.emplace(std::string(inputDescriptors[i].name), inputDescriptors + i);
}
// We don't support the case when batch size is larger than max batch size
// yet, but this is not a hard constraint.
if (batch_size_ > max_batch_size_)
{
return ONNXIFI_STATUS_NO_DEVICE_RESOURCES;
}
for (unsigned i = 0; i < outputsCount; ++i)
{
if (outputDescriptors[i].tag != ONNXIFI_TAG_TENSOR_DESCRIPTOR_V1)
{
return ONNXIFI_STATUS_UNSUPPORTED_TAG;
}
if (!outputDescriptors[i].name)
{
return ONNXIFI_STATUS_INVALID_NAME;
}
output_map_.emplace(std::string(outputDescriptors[i].name), outputDescriptors + i);
}
int nbindings = trt_engine_->getNbBindings();
for (int b = 0; b < nbindings; ++b)
{
nvinfer1::Dims dims = trt_engine_->getBindingDimensions(b);
// Check data type consistency
auto binding_datatype = trt_engine_->getBindingDataType(b);
if (binding_datatype != nvinfer1::DataType::kFLOAT)
{
return ONNXIFI_STATUS_MISMATCHING_DATATYPE;
}
if (trt_engine_->bindingIsInput(b))
{
std::cerr << "Input: " << trt_engine_->getBindingName(b) << ", Dim: " << dims.d[0] << ", " << dims.d[1]
<< ", " << dims.d[2] << std::endl;
const auto it = input_map_.find(trt_engine_->getBindingName(b));
if (it == input_map_.end())
{
return ONNXIFI_STATUS_UNIDENTIFIED_NAME;
}
if (auto ret = CheckAndBindTensor(dims, *it->second, false) != ONNXIFI_STATUS_SUCCESS)
{
return ret;
}
}
else
{
// output: for output, we enforce 4D dim although it can be in 2D, we do
// an implicit reshape in `CheckAndBindTensor`
const auto it = output_map_.find(trt_engine_->getBindingName(b));
if (it == output_map_.end())
{
return ONNXIFI_STATUS_UNIDENTIFIED_NAME;
}
if (auto ret = CheckAndBindTensor(dims, *it->second, true) != ONNXIFI_STATUS_SUCCESS)
{
return ret;
}
}
}
trt_executor_ = infer_object(trt_engine_->createExecutionContext());
return ONNXIFI_STATUS_SUCCESS;
}
onnxStatus GraphRep::Run()
{
CudaDeviceGuard guard(device_id_);
// Copy input if necessary
// TODO: cache tensor footprint
for (auto kv : device_buffers_)
{
auto it = input_map_.find(kv.first);
if (it != input_map_.end())
{
cudaMemcpyAsync(kv.second, (void*) (it->second->buffer), GetTensorFootprint(*it->second),
cudaMemcpyHostToDevice, stream_);
}
else if (output_map_.find(kv.first) == output_map_.end())
{
return ONNXIFI_STATUS_UNIDENTIFIED_NAME;
}
}
// Run TensorRT
trt_executor_->enqueue(batch_size_, bindings_.data(), stream_, nullptr);
// Copy output if necessary
for (auto kv : device_buffers_)
{
auto it = output_map_.find(kv.first);
if (it != output_map_.end())
{
cudaMemcpyAsync((void*) (it->second->buffer), kv.second, GetTensorFootprint(*it->second),
cudaMemcpyDeviceToHost, stream_);
}
else if (input_map_.find(kv.first) == input_map_.end())
{
return ONNXIFI_STATUS_UNIDENTIFIED_NAME;
}
}
return ONNXIFI_STATUS_SUCCESS;
}
template <class F>
onnxStatus OnnxifiTryCatch(F&& tryBlock)
{
try
{
return tryBlock();
}
catch (const std::bad_alloc& e)
{
std::cerr << "Allocation failed: " << e.what() << std::endl;
return ONNXIFI_STATUS_NO_SYSTEM_MEMORY;
}
catch (const std::exception& e)
{
std::cerr << "Internal Error: " << e.what() << std::endl;
return ONNXIFI_STATUS_INTERNAL_ERROR;
}
catch (...)
{
return ONNXIFI_STATUS_INTERNAL_ERROR;
}
}
} // namespace
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxGetBackendIDs(
onnxBackendID* backendIDs, size_t* numBackends)
{
return OnnxifiTryCatch([&] {
if (!numBackends)
{
return ONNXIFI_STATUS_INVALID_POINTER;
}
int nDevices_int{0};
cudaGetDeviceCount(&nDevices_int);
size_t nDevices{static_cast<size_t>(nDevices_int)};
if (!backendIDs)
{
*numBackends = nDevices;
return ONNXIFI_STATUS_FALLBACK;
}
else
{
size_t len = (*numBackends < nDevices) ? (*numBackends) : nDevices;
std::vector<std::unique_ptr<OnnxTensorRTBackendID>> vtmp;
for (size_t i = 0; i < len; ++i)
{
vtmp.emplace_back(new OnnxTensorRTBackendID(i));
}
for (size_t i = 0; i < len; ++i)
{
backendIDs[i] = (onnxBackendID)(vtmp[i].release());
}
return (*numBackends < nDevices) ? ONNXIFI_STATUS_FALLBACK : ONNXIFI_STATUS_SUCCESS;
}
});
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxReleaseBackendID(onnxBackendID backendID)
{
return OnnxifiTryCatch([&] {
auto* backend_id = reinterpret_cast<OnnxTensorRTBackendID*>(backendID);
if (!backend_id)
{
return ONNXIFI_STATUS_INVALID_ID;
}
delete backend_id;
return ONNXIFI_STATUS_SUCCESS;
});
}
static onnxStatus setUIntInfo(void* valuePtr, size_t* valueSizePtr, uint64_t value)
{
onnxStatus status = ONNXIFI_STATUS_FALLBACK;
if (valuePtr != nullptr && *valueSizePtr >= sizeof(uint64_t))
{
*static_cast<uint64_t*>(valuePtr) = value;
status = ONNXIFI_STATUS_SUCCESS;
}
*valueSizePtr = sizeof(uint64_t);
return status;
}
static onnxStatus setStringInfo(void* valuePtr, size_t* valueSizePtr, const char* value, size_t valueSize)
{
onnxStatus status = ONNXIFI_STATUS_FALLBACK;
if (valuePtr != nullptr && *valueSizePtr >= valueSize)
{
memcpy(valuePtr, value, valueSize);
status = ONNXIFI_STATUS_SUCCESS;
}
*valueSizePtr = valueSize;
return status;
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxGetBackendInfo(
onnxBackendID backendID, onnxBackendInfo infoType, void* infoValue, size_t* infoValueSize)
{
return OnnxifiTryCatch([&] {
if (infoValueSize == nullptr)
{
return ONNXIFI_STATUS_INVALID_POINTER;
}
if (backendID == nullptr)
{
return ONNXIFI_STATUS_INVALID_ID;
}
const int cudaDeviceId = static_cast<OnnxTensorRTBackendID*>(backendID)->device_id;
switch (infoType)
{
case ONNXIFI_BACKEND_ONNXIFI_VERSION:
return setUIntInfo(infoValue, infoValueSize, UINT64_C(0x0000000100000000));
case ONNXIFI_BACKEND_NAME: return setStringInfo(infoValue, infoValueSize, BACKEND_NAME, strlen(BACKEND_NAME));
case ONNXIFI_BACKEND_VENDOR:
return setStringInfo(infoValue, infoValueSize, BACKEND_VENDOR, strlen(BACKEND_VENDOR));
case ONNXIFI_BACKEND_VERSION:
return setStringInfo(infoValue, infoValueSize, BACKEND_VERSION, strlen(BACKEND_VERSION));
case ONNXIFI_BACKEND_EXTENSIONS:
return setStringInfo(infoValue, infoValueSize, BACKEND_EXTENSIONS, strlen(BACKEND_EXTENSIONS));
case ONNXIFI_BACKEND_DEVICE:
{
cudaDeviceProp deviceProperties = {0};
cudaError_t cudaError = cudaGetDeviceProperties(&deviceProperties, cudaDeviceId);
switch (cudaError)
{
case cudaSuccess: break;
case cudaErrorInvalidDevice: return ONNXIFI_STATUS_INVALID_ID;
default: return ONNXIFI_STATUS_INTERNAL_ERROR;
}
return setStringInfo(infoValue, infoValueSize, deviceProperties.name,
strnlen(deviceProperties.name, sizeof(deviceProperties.name)));
}
case ONNXIFI_BACKEND_DEVICE_TYPE: return setUIntInfo(infoValue, infoValueSize, ONNXIFI_DEVICE_TYPE_GPU);
case ONNXIFI_BACKEND_ONNX_IR_VERSION:
return setStringInfo(infoValue, infoValueSize, BACKEND_IR_VERSION, strlen(BACKEND_IR_VERSION));
case ONNXIFI_BACKEND_OPSET_VERSION:
return setStringInfo(infoValue, infoValueSize, BACKEND_OPSET_VERSION, strlen(BACKEND_OPSET_VERSION));
case ONNXIFI_BACKEND_CAPABILITIES: return setUIntInfo(infoValue, infoValueSize, 0);
case ONNXIFI_BACKEND_INIT_PROPERTIES: return setUIntInfo(infoValue, infoValueSize, 0);
case ONNXIFI_BACKEND_MEMORY_TYPES:
return setUIntInfo(infoValue, infoValueSize, ONNXIFI_MEMORY_TYPE_CPU | ONNXIFI_MEMORY_TYPE_CUDA_BUFFER);
case ONNXIFI_BACKEND_GRAPH_INIT_PROPERTIES: return setUIntInfo(infoValue, infoValueSize, 0);
case ONNXIFI_BACKEND_SYNCHRONIZATION_TYPES:
return setUIntInfo(infoValue, infoValueSize, ONNXIFI_SYNCHRONIZATION_EVENT);
case ONNXIFI_BACKEND_CPU_MEMORY_READ_BANDWIDTH:
case ONNXIFI_BACKEND_CPU_MEMORY_WRITE_BANDWIDTH:
/* Assume PCI Express 3.0 x16 */
return setUIntInfo(infoValue, infoValueSize, UINT64_C(16519104985));
case ONNXIFI_BACKEND_MAX_GRAPH_COUNT: return setUIntInfo(infoValue, infoValueSize, UINT64_MAX);
case ONNXIFI_BACKEND_MEMORY_SIZE:
case ONNXIFI_BACKEND_MAX_GRAPH_SIZE:
case ONNXIFI_BACKEND_PCI_BUS_ID:
case ONNXIFI_BACKEND_PCI_DEVICE_ID:
case ONNXIFI_BACKEND_PCI_DOMAIN_ID:
case ONNXIFI_BACKEND_MACS_FP32:
case ONNXIFI_BACKEND_MACS_FP16:
case ONNXIFI_BACKEND_MEMORY_BANDWIDTH:
{
cudaDeviceProp deviceProperties = {0};
cudaError_t cudaError = cudaGetDeviceProperties(&deviceProperties, cudaDeviceId);
switch (cudaError)
{
case cudaSuccess: break;
case cudaErrorInvalidDevice: return ONNXIFI_STATUS_INVALID_ID;
default: return ONNXIFI_STATUS_INTERNAL_ERROR;
}
switch (infoType)
{
case ONNXIFI_BACKEND_MEMORY_SIZE:
case ONNXIFI_BACKEND_MAX_GRAPH_SIZE:
return setUIntInfo(infoValue, infoValueSize, static_cast<uint64_t>(deviceProperties.totalGlobalMem));
case ONNXIFI_BACKEND_MEMORY_BANDWIDTH:
return setUIntInfo(infoValue, infoValueSize, static_cast<uint64_t>(deviceProperties.memoryClockRate)
* static_cast<uint64_t>(deviceProperties.memoryBusWidth) *
/*
* clock rate: kHZ -> HZ (multiply by 1000)
* bus width: bits -> bytes (divide by 8)
* 2x DDR factor (multiply by 2)
*/
UINT64_C(250));
case ONNXIFI_BACKEND_PCI_BUS_ID:
return setUIntInfo(infoValue, infoValueSize, static_cast<uint64_t>(deviceProperties.pciBusID));
case ONNXIFI_BACKEND_PCI_DEVICE_ID:
return setUIntInfo(infoValue, infoValueSize, static_cast<uint64_t>(deviceProperties.pciDeviceID));
case ONNXIFI_BACKEND_PCI_DOMAIN_ID:
return setUIntInfo(infoValue, infoValueSize, static_cast<uint64_t>(deviceProperties.pciDomainID));
case ONNXIFI_BACKEND_MACS_FP32:
{
/*
* See "32-bit floating-point add, multiply, multiply-add" in
* "Throughput of Native Arithmetic Instructions" table in
* CUDA Programming Guide. Multiply by 2 because we could FMA
* as two FLOPs.
*/
uint64_t flopsPerCycle = 0;
switch (deviceProperties.major)
{
case 3:
/* Kepler */
flopsPerCycle = 192 * 2;
break;
case 5:
/* Maxwell */
flopsPerCycle = 128 * 2;
break;
case 6:
/* Pascal */
switch (deviceProperties.minor)
{
case 0: flopsPerCycle = 64 * 2; break;
case 1: flopsPerCycle = 128 * 2; break;
case 2: flopsPerCycle = 128 * 2; break;
}
break;
case 7:
/* Volta */
if (deviceProperties.minor == 0)
{
flopsPerCycle = 64 * 2;
}
break;
}
if (flopsPerCycle == 0)
{
return ONNXIFI_STATUS_UNSUPPORTED_ATTRIBUTE;
}
return setUIntInfo(infoValue, infoValueSize, UINT64_C(1000) /* KHz -> Hz */
* static_cast<uint64_t>(deviceProperties.clockRate)
* static_cast<uint64_t>(deviceProperties.multiProcessorCount) * flopsPerCycle);
}
case ONNXIFI_BACKEND_MACS_FP16:
{
/*
* See "16-bit floating-point add, multiply, multiply-add" and
* "32-bit floating-point add, multiply, multiply-add" in
* "Throughput of Native Arithmetic Instructions" table in
* CUDA Programming Guide. Use the maximum among 16-bit and 32-bit
* throughput. Multiply by 2 because we could FMA as two FLOPs.
*/
uint64_t flopsPerCycle = 0;
switch (deviceProperties.major)
{
case 3:
/* Kepler */
flopsPerCycle = 192 * 2;
break;
case 5:
/* Maxwell */
if (deviceProperties.minor == 3)
{
/* Maxwell-based Tegra supports FP16 at 2x rate */
flopsPerCycle = 256 * 2;
}
else
{
flopsPerCycle = 128 * 2;
}
break;
case 6:
/* Pascal */
switch (deviceProperties.minor)
{
case 0:
/* Use FP16 */
flopsPerCycle = 128 * 2;
break;
case 1:
/* Use FP32 */
flopsPerCycle = 128 * 2;
break;
case 2:
/* Use FP16 */
flopsPerCycle = 256 * 2;
break;
}
break;
case 7:
/* Volta */
if (deviceProperties.minor == 0)
{
/*
* Tensor Core:
* - 8 Tensor Cores per multiprocessor
* - 64 FMA/cycle on each Tensor Core
* - 2 FLOPs / FMA
*/
flopsPerCycle = 8 * 64 * 2;
}
break;
}
if (flopsPerCycle == 0)
{
return ONNXIFI_STATUS_UNSUPPORTED_ATTRIBUTE;
}
return setUIntInfo(infoValue, infoValueSize, UINT64_C(1000) /* KHz -> Hz */
* static_cast<uint64_t>(deviceProperties.clockRate)
* static_cast<uint64_t>(deviceProperties.multiProcessorCount) * flopsPerCycle);
}
default: return ONNXIFI_STATUS_UNSUPPORTED_ATTRIBUTE;
}
}
case ONNXIFI_BACKEND_CUDA_INDEX:
return setUIntInfo(infoValue, infoValueSize, static_cast<uint64_t>(cudaDeviceId));
default: return ONNXIFI_STATUS_UNSUPPORTED_ATTRIBUTE;
}
});
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxGetBackendCompatibility(
onnxBackendID backendID, size_t onnxModelSize, const void* onnxModel)
{
return OnnxifiTryCatch([&] {
if (!onnxModel)
{
return ONNXIFI_STATUS_INVALID_POINTER;
}
if (onnxModelSize == 0)
{
return ONNXIFI_STATUS_INVALID_SIZE;
}
TRT_Logger trt_logger;
std::shared_ptr<nvinfer1::IBuilder> trt_builder = infer_object(nvinfer1::createInferBuilder(trt_logger));
std::shared_ptr<nvinfer1::INetworkDefinition> trt_network = infer_object(trt_builder->createNetwork());
auto parser = infer_object(nvonnxparser::createParser(*trt_network, trt_logger));
if (parser->supportsModel(onnxModel, onnxModelSize))
{
return ONNXIFI_STATUS_SUCCESS;
}
else
{
return ONNXIFI_STATUS_UNSUPPORTED_OPERATOR;
}
});
}
// NB: Passing arguments to backend is tricky. And we need more documentation
// for it I didn't put any arguments here for now.
// TODO: submit arguments for
// - setMaxBatchSize (size_t)
// - setMaxWorkspaceSize (size_t)
// - setHalf2Mode (bool)
// - setInt8Mode (bool)
// - setDebugSync (bool)
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxInitBackend(
onnxBackendID backendID, const uint64_t* auxPropertiesList, onnxBackend* backend)
{
auto ret = OnnxifiTryCatch([&] {
auto* backend_id = reinterpret_cast<OnnxTensorRTBackendID*>(backendID);
if (!backend_id)
{
return ONNXIFI_STATUS_INVALID_ID;
}
*backend = (onnxBackend)(new OnnxTensorRTBackendRep(*backend_id));
return ONNXIFI_STATUS_SUCCESS;
});
if (ret != ONNXIFI_STATUS_SUCCESS)
{
*backend = NULL;
}
return ret;
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxReleaseBackend(onnxBackend backend)
{
return OnnxifiTryCatch([&] {
auto* backendrep = reinterpret_cast<OnnxTensorRTBackendRep*>(backend);
if (!backendrep)
{
return ONNXIFI_STATUS_INVALID_BACKEND;
}
delete backendrep;
return ONNXIFI_STATUS_SUCCESS;
});
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxInitEvent(onnxBackend backend, onnxEvent* event)
{
auto ret = OnnxifiTryCatch([&] {
if (!event)
{
return ONNXIFI_STATUS_INVALID_POINTER;
}
auto* backendrep = reinterpret_cast<OnnxTensorRTBackendRep*>(backend);
if (!backendrep)
{
return ONNXIFI_STATUS_INVALID_BACKEND;
}
*event = reinterpret_cast<onnxEvent>(new OnnxTensorRTEvent(backendrep->stream()));
return ONNXIFI_STATUS_SUCCESS;
});
if (ret != ONNXIFI_STATUS_SUCCESS)
{
*event = NULL;
}
return ret;
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxSignalEvent(onnxEvent event)
{
return OnnxifiTryCatch([&] {
auto trt_event = reinterpret_cast<OnnxTensorRTEvent*>(event);
if (!trt_event)
{
return ONNXIFI_STATUS_INVALID_EVENT;
}
return trt_event->Signal();
});
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxWaitEvent(onnxEvent event)
{
return OnnxifiTryCatch([&] {
auto trt_event = reinterpret_cast<OnnxTensorRTEvent*>(event);
if (!trt_event)
{
return ONNXIFI_STATUS_INVALID_EVENT;
}
return trt_event->Wait();
});
}
ONNXIFI_PUBLIC ONNXIFI_CHECK_RESULT onnxStatus ONNXIFI_ABI onnxGetEventState(onnxEvent event, onnxEventState* state)
{
return OnnxifiTryCatch([&] {
if (!state)