DeCLIP-TPAMI / deployment /declip_quant /TensorRT /plugin /bertQKVToContextPlugin /qkvToContextPlugin.cpp
| /* | |
| * SPDX-FileCopyrightText: Copyright (c) 1993-2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved. | |
| * SPDX-License-Identifier: Apache-2.0 | |
| * | |
| * Licensed under the Apache License, Version 2.0 (the "License"); | |
| * you may not use this file except in compliance with the License. | |
| * You may obtain a copy of the License at | |
| * | |
| * http://www.apache.org/licenses/LICENSE-2.0 | |
| * | |
| * Unless required by applicable law or agreed to in writing, software | |
| * distributed under the License is distributed on an "AS IS" BASIS, | |
| * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. | |
| * See the License for the specific language governing permissions and | |
| * limitations under the License. | |
| */ | |
| // Need 10.1 for cublasGemmStridedBatchedEx | |
| using namespace nvinfer1; | |
| using namespace nvinfer1::plugin; | |
| using namespace nvinfer1::plugin::bert; | |
| using namespace nvinfer1::pluginInternal; | |
| namespace | |
| { | |
| char const* const kQKV_TO_CONTEXT_PLUGIN_VERSION{"4"}; | |
| char const* const kQKV_TO_CONTEXT_VAR_SEQLEN_PLUGIN_VERSION{"5"}; | |
| char const* const kQKV_TO_CONTEXT_PLUGIN_NAME{"CustomQKVToContextPluginDynamic"}; | |
| } // namespace | |
| REGISTER_TENSORRT_PLUGIN(QKVToContextPluginDynamicCreator); | |
| constexpr uint32_t kIIDX = 0; // index of the input tensor | |
| constexpr uint32_t kMIDX = 1; // index of the mask | |
| REGISTER_TENSORRT_PLUGIN(QKVToContextVarSeqlenPluginCreator); | |
| QKVToContextPluginDynamic::~QKVToContextPluginDynamic() {} | |
| QKVToContextPluginDynamic::QKVToContextPluginDynamic(const std::string name, const DataType type, | |
| const int32_t hiddenSize, const int32_t numHeads, float const dqProbs, bool hasImask) | |
| : mLayerName(name) | |
| , mS(0) | |
| , mB(0) | |
| , mHeadSize(hiddenSize / numHeads) | |
| , mHiddenSize(hiddenSize) | |
| , mNumHeads(numHeads) | |
| , mType(type) | |
| , mDqProbs(dqProbs) | |
| { | |
| mHasImask = static_cast<int32_t>(hasImask); | |
| mSM = getSmVersion(); | |
| } | |
| QKVToContextPluginDynamic::QKVToContextPluginDynamic(const std::string name, const DataType type, const int32_t S, | |
| const int32_t B, const int32_t SM, const int32_t hiddenSize, const int32_t numHeads, float const dqProbs, | |
| bool hasImask, bool hasUnfusedDispatcher, void const* runnerStateBuffer) | |
| : mLayerName(name) | |
| , mS(S) | |
| , mB(B) | |
| , mSM(SM) | |
| , mHeadSize(hiddenSize / numHeads) | |
| , mHiddenSize(hiddenSize) | |
| , mNumHeads(numHeads) | |
| , mType(type) | |
| , mDqProbs(dqProbs) | |
| { | |
| BERT_DEBUG_MSG("MHA Runner Deser"); | |
| mHasImask = static_cast<int32_t>(hasImask); | |
| mHasUnfusedDispatcher = static_cast<int32_t>(hasUnfusedDispatcher); | |
| createMHARunner(); | |
| if (hasUnfusedDispatcher) | |
| { | |
| PLUGIN_ASSERT(unfusedDispatcher.get()); | |
| PLUGIN_ASSERT(runnerStateBuffer != nullptr); | |
| auto length = unfusedDispatcher->getSerializationSize(); | |
| unfusedDispatcher->deserialize(runnerStateBuffer, length); | |
| } | |
| BERT_DEBUG_MSG("MHA Runner Deser Done"); | |
| } | |
| IPluginCapability* QKVToContextPluginDynamic::getCapabilityInterface(PluginCapabilityType type) noexcept | |
| { | |
| try | |
| { | |
| if (type == PluginCapabilityType::kBUILD) | |
| { | |
| return static_cast<IPluginV3OneBuild*>(this); | |
| } | |
| if (type == PluginCapabilityType::kRUNTIME) | |
| { | |
| return static_cast<IPluginV3OneRuntime*>(this); | |
| } | |
| PLUGIN_ASSERT(type == PluginCapabilityType::kCORE); | |
| return static_cast<IPluginV3OneCore*>(this); | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return nullptr; | |
| } | |
| void QKVToContextPluginDynamic::createMHARunner() | |
| { | |
| if (!fusedDispatcher.get()) | |
| { | |
| if (mType == DataType::kHALF) | |
| { | |
| fusedDispatcher.reset(new FusedMHARunnerFP16(mNumHeads, mSM)); | |
| } | |
| else if (mType == DataType::kINT8) | |
| { | |
| fusedDispatcher.reset(new FusedMHARunnerInt8(mNumHeads, mSM, mDqProbs)); | |
| } | |
| } | |
| if (!unfusedDispatcher.get()) | |
| { | |
| unfusedDispatcher.reset(new UnfusedMHARunner(mType, mNumHeads, mSM)); | |
| } | |
| } | |
| IPluginV3* QKVToContextPluginDynamic::clone() noexcept | |
| { | |
| BERT_DEBUG_MSG("QKV Clone"); | |
| QKVToContextPluginDynamic* ret = nullptr; | |
| mHasUnfusedDispatcher = 0; | |
| char* bufferData = nullptr; | |
| // the workspacesize is 0 if we have not call setup the dispatcher yet. | |
| if (unfusedDispatcher.get() && unfusedDispatcher->getWorkspaceSize()) | |
| { | |
| mHasUnfusedDispatcher = 1; | |
| mRunnerStateBuffer.resize(unfusedDispatcher->getSerializationSize()); | |
| unfusedDispatcher->serialize(mRunnerStateBuffer.data()); | |
| bufferData = mRunnerStateBuffer.data(); | |
| } | |
| ret = new QKVToContextPluginDynamic(mLayerName, mType, mS, mB, mSM, mHiddenSize, mNumHeads, mDqProbs, | |
| static_cast<bool>(mHasImask), mHasUnfusedDispatcher, static_cast<void const*>(bufferData)); | |
| ret->setPluginNamespace(mNamespace.c_str()); | |
| BERT_DEBUG_MSG("QKV Clone done"); | |
| return ret; | |
| } | |
| int32_t QKVToContextPluginDynamic::getOutputShapes(DimsExprs const* inputs, int32_t nbInputs, | |
| DimsExprs const* shapeInputs, int32_t nbShapeInputs, DimsExprs* outputs, int32_t nbOutputs, | |
| IExprBuilder& exprBuilder) noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT(inputs != nullptr); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask); | |
| PLUGIN_ASSERT(nbShapeInputs == 0); | |
| PLUGIN_ASSERT(outputs != nullptr); | |
| PLUGIN_ASSERT(nbOutputs == 1); | |
| // Input is BxSx3*N*H, output should be BxSxN*H | |
| // Copy over everything | |
| outputs[kIIDX] = inputs[kIIDX]; | |
| // Divide last dim by three | |
| auto const* three = exprBuilder.constant(3); | |
| outputs[kIIDX].d[HDIM] = exprBuilder.operation(DimensionOperation::kFLOOR_DIV, *inputs[kIIDX].d[HDIM], *three); | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| bool QKVToContextPluginDynamic::supportsFormatCombination( | |
| int32_t pos, DynamicPluginTensorDesc const* inOut, int32_t nbInputs, int32_t /*nbOutputs*/) noexcept | |
| { | |
| PLUGIN_ASSERT(pos >= 0); | |
| PLUGIN_ASSERT(pos < 2 + mHasImask); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask); | |
| auto const* in = inOut; | |
| auto const* out = inOut + nbInputs; | |
| int32_t packedSize = getMHAMaskPackedSize(mSM, mType, in->desc.dims.d[SDIM]); | |
| // we only support int8 IO in fused mha runner, and we only support fused mha runner on Xavier, Turing and Ampere | |
| if (mType == DataType::kINT8) | |
| { | |
| if (!elem(mSM, {kSM_75, kSM_80, kSM_86, kSM_87, kSM_89, kSM_90, kSM_100, kSM_120})) | |
| { | |
| gLogError << "INT8 IO is only supported on Turing, Ampere, Hopper and Blackwell for plugin " | |
| << kQKV_TO_CONTEXT_PLUGIN_NAME << std::endl; | |
| return false; | |
| } | |
| if (in->desc.dims.d[SDIM] == -1) | |
| { | |
| gLogError << "INT8 IO not support dynamic shape in sequence dimension for plugin " | |
| << kQKV_TO_CONTEXT_PLUGIN_NAME << std::endl; | |
| return false; | |
| } | |
| if (packedSize == unfusedMaskSize) | |
| { | |
| gLogError << "INT8 IO only support sequence length 128,384 for plugin " << kQKV_TO_CONTEXT_PLUGIN_NAME | |
| << std::endl; | |
| return false; | |
| } | |
| } | |
| if (pos == 0) | |
| { | |
| bool isFormatSupported = in->desc.format == TensorFormat::kLINEAR; | |
| if (mType == DataType::kINT8) | |
| { | |
| if (in->desc.dims.d[HDIM] % 32U == 0) | |
| { | |
| isFormatSupported = in->desc.format == TensorFormat::kCHW32; | |
| } | |
| else | |
| { | |
| isFormatSupported = in->desc.format == TensorFormat::kCHW4; | |
| } | |
| } | |
| // must not check descriptions > pos | |
| return (in->desc.type == mType) && // precision | |
| isFormatSupported && // format | |
| (in->desc.dims.nbDims == 5) && // num dims | |
| ((in->desc.dims.d[HDIM] % 3U) == 0) && // see getOutputDimensions | |
| ((in->desc.dims.d[3]) == 1) && // for fc | |
| ((in->desc.dims.d[4]) == 1) // for fc | |
| ; | |
| } | |
| // pos==1 | |
| if ((mHasImask && pos == 1)) // pos 1 is the mask | |
| { | |
| auto const* inMask = &inOut[1].desc; | |
| if (inMask->dims.d[1] != -1 && inMask->dims.d[1] != packedSize) | |
| { | |
| gLogError << "CustomEmbLayerNormPluginDynamic returned mask with pack size " << inMask->dims.d[1] | |
| << ", but " << kQKV_TO_CONTEXT_PLUGIN_NAME << " expects mask pack size " << packedSize | |
| << std::endl; | |
| return false; | |
| } | |
| // detect full mask and check that it was produced | |
| return (inMask->type == DataType::kINT32) && // precision | |
| (inMask->format == TensorFormat::kLINEAR) && // format | |
| (inMask->dims.nbDims == 2) && // Bx2*maskSize | |
| (inMask->dims.d[0] == in->desc.dims.d[BDIM]); | |
| } | |
| if (!mHasImask || pos == 2) // output pos | |
| { | |
| bool isFormatSupported = out->desc.format == TensorFormat::kLINEAR; | |
| if (mType == DataType::kINT8) | |
| { | |
| if (out->desc.dims.d[HDIM] % 32U == 0) | |
| { | |
| isFormatSupported = out->desc.format == TensorFormat::kCHW32; | |
| } | |
| else | |
| { | |
| isFormatSupported = out->desc.format == TensorFormat::kCHW4; | |
| } | |
| } | |
| return (in->desc.type == out->desc.type) && // precision | |
| isFormatSupported && // format | |
| (out->desc.dims.nbDims == 5) && // num dims | |
| ((in->desc.dims.d[HDIM] / 3) == (out->desc.dims.d[HDIM])) && // div 3 | |
| ((out->desc.dims.d[3]) == 1) && // for fc | |
| ((out->desc.dims.d[4]) == 1) && // for fc | |
| ((out->desc.dims.d[BDIM]) == in->desc.dims.d[BDIM]) && // check B | |
| ((out->desc.dims.d[SDIM]) == in->desc.dims.d[SDIM]) // check S | |
| ; | |
| } | |
| return false; | |
| } | |
| int32_t QKVToContextPluginDynamic::onShapeChange( | |
| PluginTensorDesc const* in, int32_t nbInputs, PluginTensorDesc const* out, int32_t nbOutputs) noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT(in != nullptr); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask); | |
| PLUGIN_ASSERT(nbOutputs == 1); | |
| PluginTensorDesc const& inDesc = in[kIIDX]; | |
| TRT_UNUSED inDesc; | |
| PLUGIN_ASSERT(out != nullptr); | |
| PluginTensorDesc const& outDesc = out[0]; | |
| TRT_UNUSED outDesc; | |
| PLUGIN_ASSERT(mType == inDesc.type); | |
| PLUGIN_ASSERT(mType == outDesc.type); | |
| PLUGIN_ASSERT(inDesc.dims.d[BDIM] == outDesc.dims.d[BDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[SDIM] == outDesc.dims.d[SDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[HDIM] == 3 * outDesc.dims.d[HDIM]); | |
| if (mHasImask) | |
| { | |
| PluginTensorDesc const& maskDesc = in[kMIDX]; | |
| TRT_UNUSED maskDesc; | |
| PLUGIN_ASSERT(maskDesc.dims.d[0] == inDesc.dims.d[BDIM]); | |
| } | |
| createMHARunner(); | |
| // mS and mB that are set by configurePlugin() may be stale | |
| mS = inDesc.dims.d[SDIM]; | |
| mB = inDesc.dims.d[BDIM]; | |
| PLUGIN_ASSERT(mS); | |
| PLUGIN_ASSERT(mB); | |
| if (fusedDispatcher.get() && fusedDispatcher->isValid(mHeadSize, mS)) | |
| { | |
| fusedDispatcher->setup(mS, mB, mHeadSize); | |
| } | |
| else | |
| { | |
| unfusedDispatcher->setup(mS, mB, mHeadSize); | |
| } | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| int32_t QKVToContextPluginDynamic::configurePlugin( | |
| DynamicPluginTensorDesc const* in, int32_t nbInputs, DynamicPluginTensorDesc const* out, int32_t nbOutputs) noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT(in != nullptr); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask); | |
| PLUGIN_ASSERT(nbOutputs == 1); | |
| PluginTensorDesc const& inDesc = in[kIIDX].desc; | |
| TRT_UNUSED inDesc; | |
| PLUGIN_ASSERT(out != nullptr); | |
| PluginTensorDesc const& outDesc = out->desc; | |
| TRT_UNUSED outDesc; | |
| PLUGIN_ASSERT(mType == inDesc.type); | |
| PLUGIN_ASSERT(mType == outDesc.type); | |
| PLUGIN_ASSERT(inDesc.dims.d[BDIM] == outDesc.dims.d[BDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[SDIM] == outDesc.dims.d[SDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[HDIM] == 3 * outDesc.dims.d[HDIM]); | |
| if (mHasImask) | |
| { | |
| PluginTensorDesc const& maskDesc = in[kMIDX].desc; | |
| TRT_UNUSED maskDesc; | |
| PLUGIN_ASSERT(maskDesc.dims.d[0] == inDesc.dims.d[BDIM]); | |
| } | |
| createMHARunner(); | |
| const int32_t S = inDesc.dims.d[SDIM]; | |
| const int32_t B = inDesc.dims.d[BDIM] <= 0 ? in->max.d[BDIM] : inDesc.dims.d[BDIM]; | |
| if (S <= 0) | |
| { | |
| // in dynamic shape build stage, we setup with max sequence that cannot fused | |
| const int32_t Smin = in->min.d[SDIM]; | |
| const int32_t Smax = in->max.d[SDIM]; | |
| if (fusedDispatcher.get()) | |
| { | |
| for (int32_t i = Smax; i >= Smin; --i) | |
| { | |
| if (!fusedDispatcher->isValid(mHeadSize, i)) | |
| { | |
| unfusedDispatcher->setup(i, B, mHeadSize); | |
| mS = i; | |
| mB = B; | |
| break; | |
| } | |
| } | |
| } | |
| else | |
| { | |
| unfusedDispatcher->setup(Smax, B, mHeadSize); | |
| mS = Smax; | |
| mB = B; | |
| } | |
| } | |
| else | |
| { | |
| // in inference stage or in static shape build stage | |
| if (fusedDispatcher.get() && fusedDispatcher->isValid(mHeadSize, S)) | |
| { | |
| fusedDispatcher->setup(S, B, mHeadSize); | |
| } | |
| else | |
| { | |
| unfusedDispatcher->setup(S, B, mHeadSize); | |
| } | |
| mS = S; | |
| mB = B; | |
| } | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| size_t QKVToContextPluginDynamic::getWorkspaceSize(DynamicPluginTensorDesc const* /*inputs*/, int32_t /*nbInputs*/, | |
| DynamicPluginTensorDesc const* /*outputs*/, int32_t /*nbOutputs*/) const noexcept | |
| { | |
| // only unfused kernel need workspace, and we need larger workspace for larger sequence length | |
| // we have already setup unfusedDispatcher with max sequence in configurePlugin | |
| // if unfusedDispatcher is not initialized in configurePlugin | |
| PLUGIN_ASSERT(unfusedDispatcher.get()); | |
| return unfusedDispatcher->getWorkspaceSize(); | |
| } | |
| // IPluginV2Ext Methods | |
| int32_t QKVToContextPluginDynamic::getOutputDataTypes( | |
| DataType* outputTypes, int32_t nbOutputs, DataType const* inputTypes, int32_t nbInputs) const noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT( | |
| inputTypes[0] == DataType::kFLOAT || inputTypes[0] == DataType::kHALF || inputTypes[0] == DataType::kINT8); | |
| outputTypes[0] = inputTypes[0]; | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| void QKVToContextPluginDynamic::setCublasResources(std::shared_ptr<CublasWrapper> cublasWrapper) | |
| { | |
| mCublasWrapper = cublasWrapper; | |
| // The shared cublasWrapper resource owns the handle. | |
| // but `this` instance has a non-owning pointer to the handle. | |
| // Note that the cublasWrapper inits the handle and checks for nullptr | |
| // so we don't have to do that here. | |
| mCublasHandle = mCublasWrapper->getCublasHandle(); | |
| } | |
| IPluginV3* QKVToContextPluginDynamic::attachToContext(IPluginResourceContext* context) noexcept | |
| { | |
| try | |
| { | |
| auto p = static_cast<QKVToContextPluginDynamic*>(clone()); | |
| // the clone has shared ownership of underling cublasWrapper instance | |
| // that is mapped to current context | |
| p->setCublasResources(createPluginCublasWrapper(context)); | |
| return p; | |
| } | |
| catch (const std::exception& e) | |
| { | |
| caughtError(e); | |
| } | |
| return nullptr; | |
| } | |
| char const* QKVToContextPluginDynamic::getPluginVersion() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_PLUGIN_VERSION; | |
| } | |
| int32_t QKVToContextPluginDynamic::getNbOutputs() const noexcept | |
| { | |
| return 1; | |
| } | |
| char const* QKVToContextPluginDynamic::getPluginName() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_PLUGIN_NAME; | |
| } | |
| void QKVToContextPluginDynamic::setPluginNamespace(char const* libNamespace) noexcept | |
| { | |
| mNamespace = libNamespace; | |
| } | |
| char const* QKVToContextPluginDynamic::getPluginNamespace() const noexcept | |
| { | |
| return mNamespace.c_str(); | |
| } | |
| int32_t QKVToContextPluginDynamic::enqueue(PluginTensorDesc const* inputDesc, PluginTensorDesc const* outputDesc, | |
| void const* const* inputs, void* const* outputs, void* workspace, cudaStream_t stream) noexcept | |
| { | |
| PLUGIN_VALIDATE(inputDesc != nullptr && outputDesc != nullptr && inputs != nullptr && outputs != nullptr); | |
| PLUGIN_ASSERT(mS == inputDesc->dims.d[SDIM]); | |
| PLUGIN_ASSERT(mB == inputDesc->dims.d[BDIM]); | |
| try | |
| { | |
| void const* const maskPtr = mHasImask ? inputs[1] : nullptr; | |
| if (mHasImask && fusedDispatcher.get() && fusedDispatcher->isValid(mHeadSize, inputDesc->dims.d[SDIM])) | |
| { | |
| fusedDispatcher->run( | |
| inputDesc[0], outputDesc[0], inputs[0], maskPtr, outputs[0], workspace, stream, mCublasHandle); | |
| } | |
| else | |
| { | |
| PLUGIN_VALIDATE(unfusedDispatcher.get(), "The Unfused MHARunner is uninitialized, no MHARunner available!"); | |
| PLUGIN_VALIDATE(mType != DataType::kINT8, "The Unfused MHARunner does not support INT8!"); | |
| unfusedDispatcher->run( | |
| inputDesc[0], outputDesc[0], inputs[0], maskPtr, outputs[0], workspace, stream, mCublasHandle); | |
| } | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| return -1; | |
| } | |
| return 0; | |
| } | |
| PluginFieldCollection const* QKVToContextPluginDynamic::getFieldsToSerialize() noexcept | |
| { | |
| mDataToSerialize.clear(); | |
| mDataToSerialize.emplace_back("type_id", &mType, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("hidden_size", &mHiddenSize, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("num_heads", &mNumHeads, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("has_mask", &mHasImask, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("S", &mS, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("B", &mB, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("SM", &mSM, PluginFieldType::kINT32, 1); | |
| if (unfusedDispatcher.get() && unfusedDispatcher->getWorkspaceSize()) | |
| { | |
| mHasUnfusedDispatcher = 1; | |
| mRunnerStateBuffer.resize(unfusedDispatcher->getSerializationSize()); | |
| unfusedDispatcher->serialize(mRunnerStateBuffer.data()); | |
| mDataToSerialize.emplace_back("runnerStateBuffer", (void const*) mRunnerStateBuffer.data(), | |
| PluginFieldType::kUNKNOWN, mRunnerStateBuffer.size()); | |
| } | |
| else | |
| { | |
| mHasUnfusedDispatcher = 0; | |
| } | |
| mDataToSerialize.emplace_back("hasUnfusedDispatcher", &mHasUnfusedDispatcher, PluginFieldType::kINT32, 1); | |
| if (mDqProbs >= 0) | |
| { | |
| mDataToSerialize.emplace_back("dq_probs", &mDqProbs, PluginFieldType::kFLOAT32, 1); | |
| } | |
| mFCToSerialize.nbFields = mDataToSerialize.size(); | |
| mFCToSerialize.fields = mDataToSerialize.data(); | |
| return &mFCToSerialize; | |
| } | |
| QKVToContextPluginDynamicCreator::QKVToContextPluginDynamicCreator() | |
| { | |
| mPluginAttributes.emplace_back(PluginField("type_id", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("hidden_size", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("num_heads", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("has_mask", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("dq_probs", nullptr, PluginFieldType::kFLOAT32, 1)); | |
| mFC.nbFields = mPluginAttributes.size(); | |
| mFC.fields = mPluginAttributes.data(); | |
| } | |
| char const* QKVToContextPluginDynamicCreator::getPluginName() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_PLUGIN_NAME; | |
| } | |
| char const* QKVToContextPluginDynamicCreator::getPluginVersion() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_PLUGIN_VERSION; | |
| } | |
| PluginFieldCollection const* QKVToContextPluginDynamicCreator::getFieldNames() noexcept | |
| { | |
| return &mFC; | |
| } | |
| IPluginV3* QKVToContextPluginDynamicCreator::createPlugin( | |
| char const* name, PluginFieldCollection const* fc, TensorRTPhase phase) noexcept | |
| { | |
| try | |
| { | |
| BERT_DEBUG_MSG("Creating QKV2ContextPlugin..."); | |
| PLUGIN_VALIDATE(fc != nullptr); | |
| int32_t hiddenSize = 0; | |
| // Since numHeads must always exist or validateRequiredAttributes will fail, | |
| // we can set numHeads to -1 so that static analysis tools don't warn about | |
| // a division by zero in QKVToContextPluginDynamic constructor. | |
| int32_t numHeads{-1}; | |
| bool hasMask = false; | |
| int32_t typeId = -1; | |
| int32_t s = -1; | |
| int32_t b = -1; | |
| int32_t sm = -1; | |
| bool hasUnfusedDispatcher = false; | |
| void const* runnerStateBuffer = nullptr; | |
| float dqProbs = -1; | |
| PLUGIN_VALIDATE(fc->fields != nullptr); | |
| if (phase == TensorRTPhase::kBUILD) | |
| { | |
| plugin::validateRequiredAttributesExist({"type_id", "hidden_size", "num_heads", "has_mask"}, fc); | |
| } | |
| else | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| plugin::validateRequiredAttributesExist( | |
| {"type_id", "S", "B", "hidden_size", "num_heads", "has_mask", "SM", "hasUnfusedDispatcher"}, fc); | |
| } | |
| for (int32_t i = 0; i < fc->nbFields; i++) | |
| { | |
| PLUGIN_VALIDATE(fc->fields[i].name != nullptr); | |
| PLUGIN_VALIDATE(fc->fields[i].data != nullptr); | |
| std::string field_name(fc->fields[i].name); | |
| if (field_name.compare("type_id") == 0) | |
| { | |
| typeId = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(typeId >= 0 && typeId <= 2, ("QKV: Invalid TypeId " + std::to_string(typeId)).c_str()); | |
| BERT_DEBUG_VALUE("Building typeId: ", typeId); | |
| } | |
| else if (field_name.compare("hidden_size") == 0) | |
| { | |
| hiddenSize = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(hiddenSize > 0, ("QKV: Invalid hiddenSize " + std::to_string(hiddenSize)).c_str()); | |
| BERT_DEBUG_VALUE("Building hiddenSize: ", hiddenSize); | |
| } | |
| else if (field_name.compare("num_heads") == 0) | |
| { | |
| numHeads = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(numHeads > 0, ("QKV: Invalid numHeads " + std::to_string(numHeads)).c_str()); | |
| BERT_DEBUG_VALUE("Building numHeads: ", numHeads); | |
| } | |
| else if (field_name.compare("has_mask") == 0) | |
| { | |
| auto hasMaskValue = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(hasMaskValue == 0 || hasMaskValue == 1, | |
| ("QKV: Invalid hasMask " + std::to_string(hasMaskValue)).c_str()); | |
| hasMask = static_cast<bool>(hasMaskValue); | |
| BERT_DEBUG_VALUE("Building hasMask: ", hasMask); | |
| } | |
| else if (field_name.compare("dq_probs") == 0) | |
| { | |
| dqProbs = *static_cast<float const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(dqProbs > 0.0F, ("QKV: Invalid dqProbs " + std::to_string(dqProbs)).c_str()); | |
| BERT_DEBUG_VALUE("Building dqProbs: ", dqProbs); | |
| } | |
| else if (field_name.compare("S") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| s = *static_cast<int32_t const*>(fc->fields[i].data); | |
| BERT_DEBUG_VALUE("Building S: ", s); | |
| } | |
| else if (field_name.compare("B") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| b = *static_cast<int32_t const*>(fc->fields[i].data); | |
| BERT_DEBUG_VALUE("Building B: ", b); | |
| } | |
| else if (field_name.compare("SM") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| sm = *static_cast<int32_t const*>(fc->fields[i].data); | |
| BERT_DEBUG_VALUE("Building SM: ", sm); | |
| } | |
| else if (field_name.compare("hasUnfusedDispatcher") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| auto hasUnfusedDispatcherValue = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(hasUnfusedDispatcherValue == 0 || hasUnfusedDispatcherValue == 1, | |
| ("QKV: Invalid hasUnfusedDispatcher " + std::to_string(hasUnfusedDispatcherValue)).c_str()); | |
| hasUnfusedDispatcher = static_cast<bool>(hasUnfusedDispatcherValue); | |
| BERT_DEBUG_VALUE("Building hasUnfusedDispatcher: ", hasUnfusedDispatcher); | |
| } | |
| else if (field_name.compare("runnerStateBuffer") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| runnerStateBuffer = static_cast<void const*>(fc->fields[i].data); | |
| } | |
| } | |
| BERT_DEBUG_MSG("Building the Plugin..."); | |
| auto type = static_cast<DataType>(typeId); | |
| if (type == DataType::kINT8 && dqProbs < 0) | |
| { | |
| BERT_DEBUG_MSG("Using default scale factor"); | |
| dqProbs = 1.F / 127.F; | |
| } | |
| if (phase == TensorRTPhase::kBUILD) | |
| { | |
| return new QKVToContextPluginDynamic(name, type, hiddenSize, numHeads, dqProbs, hasMask); | |
| } | |
| PLUGIN_VALIDATE(s != -1, "invalid S during runtime plugin creation"); | |
| PLUGIN_VALIDATE(b != -1, "invalid B during runtime plugin creation"); | |
| PLUGIN_VALIDATE(sm != -1, "invalid SM during runtime plugin creation"); | |
| if (hasUnfusedDispatcher == 1) | |
| { | |
| PLUGIN_VALIDATE(runnerStateBuffer != nullptr, "invalid runnerStateBuffer during runtime plugin creation"); | |
| } | |
| else | |
| { | |
| PLUGIN_VALIDATE(runnerStateBuffer == nullptr, "invalid runnerStateBuffer during runtime plugin creation"); | |
| } | |
| return new QKVToContextPluginDynamic( | |
| name, type, s, b, sm, hiddenSize, numHeads, dqProbs, hasMask, hasUnfusedDispatcher, runnerStateBuffer); | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return nullptr; | |
| } | |
| void QKVToContextPluginDynamicCreator::setPluginNamespace(char const* libNamespace) noexcept | |
| { | |
| mNamespace = libNamespace; | |
| } | |
| char const* QKVToContextPluginDynamicCreator::getPluginNamespace() const noexcept | |
| { | |
| return mNamespace.c_str(); | |
| } | |
| ///// QKVToContextVarSeqlenPlugin (CustomQKVToContextPluginDynamic v5) //// | |
| QKVToContextVarSeqlenPlugin::~QKVToContextVarSeqlenPlugin() {} | |
| QKVToContextVarSeqlenPlugin::QKVToContextVarSeqlenPlugin(std::string const name, DataType const type, | |
| int32_t const hiddenSize, int32_t const numHeads, float const dqProbs, bool hasImask, bool varSeqlen, | |
| bool useInt8ScaleMax) | |
| : mLayerName(name) | |
| , mS(0) | |
| , mB(0) | |
| , mHeadSize(hiddenSize / numHeads) | |
| , mHiddenSize(hiddenSize) | |
| , mNumHeads(numHeads) | |
| , mType(type) | |
| , mDqProbs(dqProbs) | |
| , mHdim(HDIM) | |
| { | |
| mSM = getSmVersion(); | |
| mUseVarSeqlen = static_cast<int32_t>(varSeqlen); | |
| mUseInt8ScaleMax = static_cast<int32_t>(useInt8ScaleMax); | |
| mHasImask = static_cast<int32_t>(hasImask); | |
| if (varSeqlen) | |
| { | |
| // variable sequence length is only supported with the fused MHA kernels | |
| // we should not override mS! | |
| bool isSMSupported = elem(mSM, {kSM_75, kSM_80, kSM_86, kSM_87, kSM_89, kSM_90, kSM_100, kSM_120}); | |
| PLUGIN_ASSERT(isSMSupported && (type == DataType::kINT8 || type == DataType::kHALF) | |
| && "requesting maxSeqlen not compatible with GPU arch"); | |
| // the layout changes: SxB will be a combined \sum_i s_i and hdim will be the 2nd dimension instead of the third | |
| mHdim = 1; | |
| } | |
| } | |
| QKVToContextVarSeqlenPlugin::QKVToContextVarSeqlenPlugin(std::string const name, int32_t const S, int32_t const B, | |
| DataType const type, int32_t const hiddenSize, int32_t const numHeads, float const dqProbs, bool hasImask, | |
| bool varSeqlen, bool useInt8ScaleMax, void const* runnerStateBuffer) | |
| : mLayerName(name) | |
| , mS(S) | |
| , mB(B) | |
| , mHeadSize(hiddenSize / numHeads) | |
| , mHiddenSize(hiddenSize) | |
| , mNumHeads(numHeads) | |
| , mType(type) | |
| , mDqProbs(dqProbs) | |
| , mHdim(HDIM) | |
| { | |
| mSM = getSmVersion(); | |
| mUseVarSeqlen = static_cast<int32_t>(varSeqlen); | |
| mUseInt8ScaleMax = static_cast<int32_t>(useInt8ScaleMax); | |
| mHasImask = static_cast<int32_t>(hasImask); | |
| if (varSeqlen) | |
| { | |
| // variable sequence length is only supported with the fused MHA kernels | |
| // we should not override mS! | |
| bool isSMSupported = elem(mSM, {kSM_75, kSM_80, kSM_86, kSM_87, kSM_89, kSM_90, kSM_100, kSM_120}); | |
| PLUGIN_ASSERT(isSMSupported && (type == DataType::kINT8 || type == DataType::kHALF) | |
| && "requesting maxSeqlen not compatible with GPU arch"); | |
| // the layout changes: SxB will be a combined \sum_i s_i and hdim will be the 2nd dimension instead of the third | |
| mHdim = 1; | |
| } | |
| createMHARunner(); | |
| PLUGIN_ASSERT(runnerStateBuffer != nullptr); | |
| auto length = mDispatcher->getSerializationSize(); | |
| mDispatcher->deserialize(runnerStateBuffer, length); | |
| } | |
| IPluginCapability* QKVToContextVarSeqlenPlugin::getCapabilityInterface(PluginCapabilityType type) noexcept | |
| { | |
| try | |
| { | |
| if (type == PluginCapabilityType::kBUILD) | |
| { | |
| return static_cast<IPluginV3OneBuild*>(this); | |
| } | |
| if (type == PluginCapabilityType::kRUNTIME) | |
| { | |
| return static_cast<IPluginV3OneRuntime*>(this); | |
| } | |
| PLUGIN_ASSERT(type == PluginCapabilityType::kCORE); | |
| return static_cast<IPluginV3OneCore*>(this); | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return nullptr; | |
| } | |
| void QKVToContextVarSeqlenPlugin::createMHARunner() | |
| { | |
| if (mDispatcher.get()) | |
| { | |
| return; | |
| } | |
| if (mUseVarSeqlen) | |
| { | |
| PLUGIN_ASSERT(mHeadSize <= 64); | |
| { | |
| if (mHeadSize != 64) | |
| { | |
| mPatcher.reset(new QkvPaddingRunner(mType)); | |
| } | |
| if (mType == DataType::kHALF) | |
| { | |
| mDispatcher.reset(new FusedMHARunnerFP16v2(mNumHeads, mSM)); | |
| } | |
| else if (mType == DataType::kINT8) | |
| { | |
| mDispatcher.reset(new FusedMHARunnerInt8v2(mNumHeads, mSM, mDqProbs, mUseInt8ScaleMax)); | |
| } | |
| } | |
| } | |
| else | |
| { | |
| PLUGIN_ASSERT(mType != DataType::kINT8); | |
| mDispatcher.reset(new UnfusedMHARunner(mType, mNumHeads, mSM)); | |
| } | |
| } | |
| IPluginV3* QKVToContextVarSeqlenPlugin::clone() noexcept | |
| { | |
| BERT_DEBUG_MSG("QKV Clone"); | |
| QKVToContextVarSeqlenPlugin* ret = nullptr; | |
| char* bufferData = nullptr; | |
| // the workspacesize is 0 if we have not call setup the dispatcher yet. | |
| if (mDispatcher.get()) | |
| { | |
| mRunnerStateBuffer.resize(mDispatcher->getSerializationSize()); | |
| mDispatcher->serialize(mRunnerStateBuffer.data()); | |
| bufferData = mRunnerStateBuffer.data(); | |
| ret = new QKVToContextVarSeqlenPlugin(mLayerName, mS, mB, mType, mHiddenSize, mNumHeads, mDqProbs, mHasImask, | |
| mUseVarSeqlen, mUseInt8ScaleMax, static_cast<void const*>(bufferData)); | |
| } | |
| else | |
| { | |
| // dispatcher not setup yet, use type 1 constructor | |
| ret = new QKVToContextVarSeqlenPlugin( | |
| mLayerName, mType, mHiddenSize, mNumHeads, mDqProbs, mHasImask, mUseVarSeqlen, mUseInt8ScaleMax); | |
| } | |
| ret->setPluginNamespace(mNamespace.c_str()); | |
| BERT_DEBUG_MSG("QKV Clone done"); | |
| return ret; | |
| } | |
| int32_t QKVToContextVarSeqlenPlugin::getOutputShapes(DimsExprs const* inputs, int32_t nbInputs, | |
| DimsExprs const* shapeInputs, int32_t nbShapeInputs, DimsExprs* outputs, int32_t nbOutputs, | |
| IExprBuilder& exprBuilder) noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT(inputs != nullptr); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask + 2 * mUseVarSeqlen); | |
| PLUGIN_ASSERT(nbShapeInputs == 0); | |
| PLUGIN_ASSERT(outputs != nullptr); | |
| PLUGIN_ASSERT(nbOutputs == 1); | |
| // Input is BxSx3*N*H, output should be BxSxN*H | |
| // Copy over everything | |
| outputs[kIIDX] = inputs[kIIDX]; | |
| // Divide last dim by three | |
| auto const* three = exprBuilder.constant(3); | |
| // mHdim is 2 for fixed seqlen and is 1 for varseqlen | |
| outputs[kIIDX].d[mHdim] | |
| = exprBuilder.operation(DimensionOperation::kFLOOR_DIV, *inputs[kIIDX].d[mHdim], *three); | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| bool QKVToContextVarSeqlenPlugin::supportsFormatCombination( | |
| int32_t pos, DynamicPluginTensorDesc const* inOut, int32_t nbInputs, int32_t nbOutputs) noexcept | |
| { | |
| // we only support variable sequence and int8 IO in fused mha runner, and we only support fused mha runner on | |
| // Turing, Ampere, Hopper and Blackwell | |
| bool const hasV2Kernels = elem(mSM, {kSM_75, kSM_80, kSM_86, kSM_87, kSM_89, kSM_90, kSM_100, kSM_120}); | |
| PLUGIN_ASSERT((mType != DataType::kINT8 || hasV2Kernels) | |
| && "INT8 IO is only supported on Xavier, Turing, Ampere, Hopper and Blackwell!"); | |
| PLUGIN_ASSERT((!mUseVarSeqlen || hasV2Kernels) | |
| && "Variable sequence is only supported on Xavier, Turing, Ampere, Hopper and Blackwell!"); | |
| PLUGIN_ASSERT(pos >= 0); | |
| PLUGIN_ASSERT(pos < 2 + mHasImask + 2 * mUseVarSeqlen); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask + 2 * mUseVarSeqlen); | |
| PLUGIN_ASSERT(nbOutputs == 1); | |
| auto const* in = inOut; | |
| auto const* out = inOut + nbInputs; | |
| if (mUseVarSeqlen) | |
| { | |
| PLUGIN_ASSERT((mType == DataType::kHALF || mType == DataType::kINT8) | |
| && "Conditions for variable seqlen support not fulfilled"); | |
| // qkv, mask, cu_seqlens, dummy | |
| PLUGIN_ASSERT(nbInputs == 4 && "for varseqlen, expected 4 inputs"); | |
| } | |
| auto const inDims = in->desc.dims; | |
| auto const outDims = out->desc.dims; | |
| auto supportedFormat = TensorFormat::kLINEAR; | |
| if (mType == DataType::kINT8) | |
| { | |
| supportedFormat = (inDims.d[mHdim] % 32U == 0) ? TensorFormat::kCHW32 : TensorFormat::kCHW4; | |
| } | |
| int32_t supportedNbDims = 5; | |
| if (mUseVarSeqlen) | |
| { | |
| supportedNbDims = 4; | |
| } | |
| bool supportedHdim = (pos == 0) ? (inDims.d[mHdim] % 3U == 0) : (inDims.d[mHdim] / 3 == outDims.d[mHdim]); | |
| if (pos == 0 || pos == nbInputs) | |
| { // check input and output | |
| auto const& desc = inOut[pos].desc; | |
| return (desc.type == mType) && // check type | |
| (desc.format == supportedFormat) && // check format | |
| (desc.dims.nbDims == supportedNbDims) && // check dims: | |
| (supportedHdim) && // - hidden dims multiple of 3 for qkv | |
| (desc.dims.d[mHdim + 1] == 1) && // - dummy 1 or h | |
| (desc.dims.d[mHdim + 2] == 1) // - dummy 1 or w | |
| ; | |
| } | |
| PLUGIN_ASSERT(mHasImask); | |
| if (pos == 1) | |
| { // must be input mask | |
| auto const* mask = &inOut[pos].desc; | |
| if (mUseVarSeqlen) | |
| { | |
| // dummy input | |
| return true; | |
| } | |
| return mask->format == TensorFormat::kLINEAR && (mask->type == DataType::kINT32) && // precision | |
| (mask->dims.nbDims == 1); // num dims | |
| } | |
| PLUGIN_ASSERT(mUseVarSeqlen); | |
| if (pos == 2) | |
| { // must be cuSeqlens | |
| // cuSeqlens is a int32_t array of size B+1 | |
| auto const* seqlens = &inOut[pos].desc; | |
| return (seqlens->type == DataType::kINT32) && (seqlens->format == TensorFormat::kLINEAR); | |
| } | |
| if (pos == 3) | |
| { | |
| // this is the dummy input | |
| return inOut[pos].desc.dims.nbDims == 1; | |
| } | |
| return false; | |
| } | |
| int32_t QKVToContextVarSeqlenPlugin::onShapeChange( | |
| PluginTensorDesc const* in, int32_t nbInputs, PluginTensorDesc const* out, int32_t nbOutputs) noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT(in != nullptr); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask + 2 * mUseVarSeqlen); | |
| PLUGIN_ASSERT(nbOutputs == 1); | |
| PluginTensorDesc const& inDesc = in[kIIDX]; | |
| TRT_UNUSED inDesc; | |
| PluginTensorDesc const& outDesc = out[0]; | |
| TRT_UNUSED outDesc; | |
| PLUGIN_ASSERT(mType == inDesc.type); | |
| PLUGIN_ASSERT(mType == outDesc.type); | |
| if (!mUseVarSeqlen) | |
| { | |
| PLUGIN_ASSERT(inDesc.dims.d[BDIM] == outDesc.dims.d[BDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[SDIM] == outDesc.dims.d[SDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[mHdim] == 3 * outDesc.dims.d[mHdim]); | |
| if (mHasImask) | |
| { | |
| PluginTensorDesc const& maskDesc = in[kMIDX]; | |
| TRT_UNUSED maskDesc; | |
| PLUGIN_ASSERT(maskDesc.dims.d[0] == inDesc.dims.d[BDIM]); | |
| } | |
| // during build, configurePlugin() should have set mS, mB appropriately | |
| // during inference, the engine should have mS, mB information | |
| PLUGIN_ASSERT(mS); | |
| PLUGIN_ASSERT(mB); | |
| BERT_DEBUG_MSG("setting up MHA runner for single sequence length"); | |
| createMHARunner(); | |
| this->mDispatcher->setup(mS, mB, mHeadSize); | |
| } | |
| else | |
| { | |
| BERT_DEBUG_MSG("setting up MHA runner for variable sequence length"); | |
| createMHARunner(); | |
| // need to initialize S and B with somewhat useful values, they will be reset at enqueue for the actual | |
| // batchsize | |
| this->mDispatcher->setup(256, 1, mHeadSize); | |
| } | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| int32_t QKVToContextVarSeqlenPlugin::configurePlugin( | |
| DynamicPluginTensorDesc const* in, int32_t nbInputs, DynamicPluginTensorDesc const* out, int32_t nbOutputs) noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT(in != nullptr); | |
| PLUGIN_ASSERT(nbInputs == 1 + mHasImask + 2 * mUseVarSeqlen); | |
| PLUGIN_ASSERT(nbOutputs == 1); | |
| PluginTensorDesc const& inDesc = in[kIIDX].desc; | |
| TRT_UNUSED inDesc; | |
| PluginTensorDesc const& outDesc = out->desc; | |
| TRT_UNUSED outDesc; | |
| PLUGIN_ASSERT(mType == inDesc.type); | |
| PLUGIN_ASSERT(mType == outDesc.type); | |
| if (!mUseVarSeqlen) | |
| { | |
| PLUGIN_ASSERT(inDesc.dims.d[BDIM] == outDesc.dims.d[BDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[SDIM] == outDesc.dims.d[SDIM]); | |
| PLUGIN_ASSERT(inDesc.dims.d[mHdim] == 3 * outDesc.dims.d[mHdim]); | |
| if (mHasImask) | |
| { | |
| PluginTensorDesc const& maskDesc = in[kMIDX].desc; | |
| TRT_UNUSED maskDesc; | |
| PLUGIN_ASSERT(maskDesc.dims.d[0] == inDesc.dims.d[BDIM]); | |
| } | |
| const int32_t S = inDesc.dims.d[SDIM] <= 0 ? in->max.d[SDIM] : inDesc.dims.d[SDIM]; | |
| const int32_t B = inDesc.dims.d[BDIM] <= 0 ? in->max.d[BDIM] : inDesc.dims.d[BDIM]; | |
| if (S != mS || B != mB) | |
| { | |
| BERT_DEBUG_MSG("setting up MHA runner for single sequence length"); | |
| createMHARunner(); | |
| this->mDispatcher->setup(S, B, mHeadSize); | |
| mS = S; | |
| mB = B; | |
| } | |
| } | |
| else | |
| { | |
| BERT_DEBUG_MSG("setting up MHA runner for variable sequence length"); | |
| createMHARunner(); | |
| // need to initialize S and B with somewhat useful values, they will be reset at enqueue for the actual | |
| // batchsize | |
| this->mDispatcher->setup(256, 1, mHeadSize); | |
| } | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| size_t QKVToContextVarSeqlenPlugin::getWorkspaceSize(DynamicPluginTensorDesc const* inputs, int32_t /* nbInputs */, | |
| DynamicPluginTensorDesc const* /* outputs */, int32_t /* nbOutputs */) const noexcept | |
| { | |
| size_t paddingWorkpaceSize = mPatcher ? mPatcher->getWorkspaceSize(inputs[0].desc.dims.d[0], mNumHeads) : 0; | |
| return mDispatcher->getWorkspaceSize() + paddingWorkpaceSize; | |
| } | |
| int32_t QKVToContextVarSeqlenPlugin::getOutputDataTypes( | |
| DataType* outputTypes, int32_t nbOutputs, DataType const* inputTypes, int32_t nbInputs) const noexcept | |
| { | |
| try | |
| { | |
| PLUGIN_ASSERT( | |
| inputTypes[0] == DataType::kFLOAT || inputTypes[0] == DataType::kHALF || inputTypes[0] == DataType::kINT8); | |
| outputTypes[0] = inputTypes[0]; | |
| return pluginStatus_t::STATUS_SUCCESS; | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return pluginStatus_t::STATUS_FAILURE; | |
| } | |
| void QKVToContextVarSeqlenPlugin::setCublasResources(std::shared_ptr<CublasWrapper> cublasWrapper) | |
| { | |
| mCublasWrapper = cublasWrapper; | |
| // The shared cublasWrapper resource owns the handle. | |
| // but `this` instance has a non-owning pointer to the handle. | |
| // Note that the cublasWrapper inits the handle and checks for nullptr | |
| // so we don't have to do that here. | |
| mCublasHandle = mCublasWrapper->getCublasHandle(); | |
| } | |
| IPluginV3* QKVToContextVarSeqlenPlugin::attachToContext(IPluginResourceContext* context) noexcept | |
| { | |
| try | |
| { | |
| auto p = static_cast<QKVToContextVarSeqlenPlugin*>(clone()); | |
| // the clone has shared ownership of underling cublasWrapper instance | |
| // that is mapped to current context | |
| p->setCublasResources(createPluginCublasWrapper(context)); | |
| return p; | |
| } | |
| catch (const std::exception& e) | |
| { | |
| caughtError(e); | |
| } | |
| return nullptr; | |
| } | |
| char const* QKVToContextVarSeqlenPlugin::getPluginVersion() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_VAR_SEQLEN_PLUGIN_VERSION; | |
| } | |
| int32_t QKVToContextVarSeqlenPlugin::getNbOutputs() const noexcept | |
| { | |
| return 1; | |
| } | |
| char const* QKVToContextVarSeqlenPlugin::getPluginName() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_PLUGIN_NAME; | |
| } | |
| void QKVToContextVarSeqlenPlugin::setPluginNamespace(char const* libNamespace) noexcept | |
| { | |
| mNamespace = libNamespace; | |
| } | |
| char const* QKVToContextVarSeqlenPlugin::getPluginNamespace() const noexcept | |
| { | |
| return mNamespace.c_str(); | |
| } | |
| int32_t QKVToContextVarSeqlenPlugin::enqueue(nvinfer1::PluginTensorDesc const* inputDesc, | |
| nvinfer1::PluginTensorDesc const* outputDesc, void const* const* inputs, void* const* outputs, void* workspace, | |
| cudaStream_t stream) noexcept | |
| { | |
| PLUGIN_VALIDATE(inputDesc != nullptr && outputDesc != nullptr && inputs != nullptr && outputs != nullptr); | |
| if (mUseVarSeqlen) | |
| { | |
| const int32_t B = inputDesc[2].dims.d[0] - 1; | |
| const int32_t maxS = inputDesc[3].dims.d[0]; | |
| PLUGIN_ASSERT((maxS <= 512) | |
| && "No implementation for variable sequence length multi-head attention plugin with sequence > 512."); | |
| int32_t S = 512; | |
| if (DataType::kHALF == mType && maxS <= 64) | |
| { | |
| S = 64; | |
| } | |
| else if (DataType::kHALF == mType && maxS <= 96) | |
| { | |
| S = 96; | |
| } | |
| else if (maxS <= 128) | |
| { | |
| S = 128; | |
| } | |
| else if (maxS <= 192) | |
| { | |
| S = 192; | |
| if (mType == DataType::kHALF) | |
| { | |
| S = 256; | |
| } | |
| } | |
| else if (maxS <= 256) | |
| { | |
| S = 256; | |
| } | |
| else if (maxS <= 384) | |
| { | |
| S = 384; | |
| } | |
| auto runV2Kernel = [this, &S, &B, &workspace, &inputDesc, &outputDesc, &stream, &inputs, &outputs]( | |
| MHARunner* dispatcher, QkvPaddingRunner* patcher, int32_t padSize) { | |
| PLUGIN_ASSERT(dispatcher); | |
| // Validate that we can padding to the dispatch required head size also there is kernel exist for this | |
| // sequence length. | |
| if (mHeadSize > padSize || !dispatcher->isValid(padSize, S)) | |
| { | |
| return false; | |
| } | |
| dispatcher->setup(S, B, padSize); | |
| // Need pad and unpad to run the V2 kernel. | |
| if (mHeadSize < padSize) | |
| { | |
| PLUGIN_ASSERT(patcher); | |
| PLUGIN_ASSERT(padSize <= patcher->getMaxPaddingHeadSize()); | |
| auto sumSeqLen = inputDesc[0].dims.d[0]; | |
| auto paddingWorkspace = patcher->get16BytesAlignedPointer(workspace, dispatcher->getWorkspaceSize()); | |
| auto ret = mPatcher->pad(inputs[0], paddingWorkspace, sumSeqLen, mNumHeads, mHeadSize, padSize, stream); | |
| if (ret != cudaSuccess) | |
| { | |
| return false; | |
| } | |
| MhaRunParameter paddingArgs = patcher->patchMhaArgs( | |
| inputDesc, outputDesc, inputs, outputs, paddingWorkspace, sumSeqLen, mNumHeads, padSize); | |
| try | |
| { | |
| dispatcher->run(paddingArgs.inputDesc, paddingArgs.outputDesc, paddingArgs.inputs, | |
| paddingArgs.outputs, workspace, stream, mCublasHandle); | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| return false; | |
| } | |
| ret = patcher->unpad( | |
| paddingArgs.outputs[0], outputs[0], sumSeqLen, mNumHeads, mHeadSize, padSize, stream); | |
| return ret == cudaSuccess; | |
| } | |
| else | |
| { | |
| // No pad/unpad is needed. | |
| try | |
| { | |
| dispatcher->run(inputDesc, outputDesc, inputs, outputs, workspace, stream, mCublasHandle); | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| return false; | |
| } | |
| return true; | |
| } | |
| }; | |
| // Try pad head size to 32 first, if it failed, then try to pad head size to 64. | |
| if (!runV2Kernel(mDispatcher.get(), mPatcher.get(), 32) && !runV2Kernel(mDispatcher.get(), mPatcher.get(), 64)) | |
| { | |
| return false; | |
| } | |
| return cudaGetLastError(); | |
| } | |
| PLUGIN_ASSERT(mS == inputDesc->dims.d[SDIM]); | |
| PLUGIN_ASSERT(mB == inputDesc->dims.d[BDIM]); | |
| void const* maskPtr = mHasImask ? inputs[1] : nullptr; | |
| mDispatcher->run(inputDesc[0], outputDesc[0], inputs[0], maskPtr, outputs[0], workspace, stream, mCublasHandle); | |
| return cudaGetLastError(); | |
| } | |
| PluginFieldCollection const* QKVToContextVarSeqlenPlugin::getFieldsToSerialize() noexcept | |
| { | |
| mDataToSerialize.clear(); | |
| mDataToSerialize.emplace_back("type_id", &mType, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("hidden_size", &mHiddenSize, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("num_heads", &mNumHeads, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("has_mask", &mHasImask, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("var_seqlen", &mUseVarSeqlen, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("use_int8_scale_max", &mUseInt8ScaleMax, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("S", &mS, PluginFieldType::kINT32, 1); | |
| mDataToSerialize.emplace_back("B", &mB, PluginFieldType::kINT32, 1); | |
| mRunnerStateBuffer.resize(mDispatcher->getSerializationSize()); | |
| mDispatcher->serialize(mRunnerStateBuffer.data()); | |
| mDataToSerialize.emplace_back("runnerStateBuffer", (void const*) mRunnerStateBuffer.data(), | |
| PluginFieldType::kUNKNOWN, mRunnerStateBuffer.size()); | |
| if (mDqProbs >= 0) | |
| { | |
| mDataToSerialize.emplace_back("dq_probs", &mDqProbs, PluginFieldType::kFLOAT32, 1); | |
| } | |
| mFCToSerialize.nbFields = mDataToSerialize.size(); | |
| mFCToSerialize.fields = mDataToSerialize.data(); | |
| return &mFCToSerialize; | |
| } | |
| QKVToContextVarSeqlenPluginCreator::QKVToContextVarSeqlenPluginCreator() | |
| { | |
| mPluginAttributes.clear(); | |
| mPluginAttributes.emplace_back(PluginField("type_id", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("hidden_size", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("num_heads", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("has_mask", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("dq_probs", nullptr, PluginFieldType::kFLOAT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("var_seqlen", nullptr, PluginFieldType::kINT32, 1)); | |
| mPluginAttributes.emplace_back(PluginField("use_int8_scale_max", nullptr, PluginFieldType::kINT32, 1)); | |
| mFC.nbFields = mPluginAttributes.size(); | |
| mFC.fields = mPluginAttributes.data(); | |
| } | |
| char const* QKVToContextVarSeqlenPluginCreator::getPluginName() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_PLUGIN_NAME; | |
| } | |
| char const* QKVToContextVarSeqlenPluginCreator::getPluginVersion() const noexcept | |
| { | |
| return kQKV_TO_CONTEXT_VAR_SEQLEN_PLUGIN_VERSION; | |
| } | |
| PluginFieldCollection const* QKVToContextVarSeqlenPluginCreator::getFieldNames() noexcept | |
| { | |
| return &mFC; | |
| } | |
| IPluginV3* QKVToContextVarSeqlenPluginCreator::createPlugin( | |
| char const* name, PluginFieldCollection const* fc, TensorRTPhase phase) noexcept | |
| { | |
| try | |
| { | |
| BERT_DEBUG_MSG("Creating QKV2ContextPlugin..."); | |
| PLUGIN_VALIDATE(fc != nullptr); | |
| int32_t hiddenSize = 0; | |
| // Since numHeads must always exist or validateRequiredAttributes will fail, | |
| // we can set numHeads to -1 so that static analysis tools don't warn about | |
| // a division by zero in QKVToContextVarSeqelnPlugin constructor. | |
| int32_t numHeads = -1; | |
| bool hasMask = false; | |
| int32_t typeId = -1; | |
| int32_t s = -1; | |
| int32_t b = -1; | |
| void const* runnerStateBuffer = nullptr; | |
| int32_t varSeqlen = 0; | |
| float dqProbs = -1; | |
| int32_t useInt8ScaleMax = -1; | |
| PLUGIN_VALIDATE(fc->fields != nullptr); | |
| if (phase == TensorRTPhase::kBUILD) | |
| { | |
| plugin::validateRequiredAttributesExist({"type_id", "hidden_size", "num_heads", "has_mask"}, fc); | |
| } | |
| else | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| // since fc is from a deserialized engine, | |
| // we expect all attributes (except dq_probs) to be present during runtime | |
| plugin::validateRequiredAttributesExist({"type_id", "S", "B", "hidden_size", "num_heads", "has_mask", | |
| "var_seqlen", "use_int8_scale_max", "runnerStateBuffer"}, | |
| fc); | |
| } | |
| for (int32_t i = 0; i < fc->nbFields; i++) | |
| { | |
| std::string field_name(fc->fields[i].name); | |
| if (field_name.compare("type_id") == 0) | |
| { | |
| typeId = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(typeId >= 0 && typeId <= 2, ("QKV: Invalid TypeId " + std::to_string(typeId)).c_str()); | |
| BERT_DEBUG_VALUE("Building typeId: ", typeId); | |
| } | |
| else if (field_name.compare("hidden_size") == 0) | |
| { | |
| hiddenSize = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(hiddenSize > 0, ("QKV: Invalid hiddenSize " + std::to_string(hiddenSize)).c_str()); | |
| BERT_DEBUG_VALUE("Building hiddenSize: ", hiddenSize); | |
| } | |
| else if (field_name.compare("num_heads") == 0) | |
| { | |
| numHeads = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(numHeads > 0, ("QKV: Invalid numHeads " + std::to_string(numHeads)).c_str()); | |
| BERT_DEBUG_VALUE("Building numHeads: ", numHeads); | |
| } | |
| else if (field_name.compare("has_mask") == 0) | |
| { | |
| hasMask = *static_cast<bool const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE( | |
| hasMask == 0 || hasMask == 1, ("QKV: Invalid hasMask " + std::to_string(hasMask)).c_str()); | |
| BERT_DEBUG_VALUE("Building hasMask: ", hasMask); | |
| } | |
| else if (field_name.compare("dq_probs") == 0) | |
| { | |
| dqProbs = *static_cast<float const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(dqProbs > 0.0F, ("QKV: Invalid dqProbs " + std::to_string(dqProbs)).c_str()); | |
| BERT_DEBUG_VALUE("Building dqProbs: ", dqProbs); | |
| } | |
| else if (field_name.compare("var_seqlen") == 0) | |
| { | |
| varSeqlen = *static_cast<int32_t const*>(fc->fields[i].data); | |
| BERT_DEBUG_VALUE("Building var_seqlen: ", varSeqlen); | |
| } | |
| else if (field_name.compare("use_int8_scale_max") == 0) | |
| { | |
| useInt8ScaleMax = *static_cast<int32_t const*>(fc->fields[i].data); | |
| PLUGIN_VALIDATE(useInt8ScaleMax == 0 || useInt8ScaleMax == 1, | |
| ("QKV: Invalid useInt8ScaleMax " + std::to_string(useInt8ScaleMax)).c_str()); | |
| BERT_DEBUG_VALUE("Building useInt8ScaleMax: ", useInt8ScaleMax); | |
| } | |
| else if (field_name.compare("S") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| s = *static_cast<int32_t const*>(fc->fields[i].data); | |
| BERT_DEBUG_VALUE("Building S: ", s); | |
| } | |
| else if (field_name.compare("B") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| b = *static_cast<int32_t const*>(fc->fields[i].data); | |
| BERT_DEBUG_VALUE("Building B: ", b); | |
| } | |
| else if (field_name.compare("runnerStateBuffer") == 0) | |
| { | |
| PLUGIN_ASSERT(phase == TensorRTPhase::kRUNTIME); | |
| runnerStateBuffer = static_cast<void const*>(fc->fields[i].data); | |
| } | |
| } | |
| if (useInt8ScaleMax < 0) | |
| { | |
| gLogInfo << "Using default for use_int8_scale_max: true" << std::endl; | |
| useInt8ScaleMax = 1; | |
| } | |
| BERT_DEBUG_MSG("Building the Plugin..."); | |
| DataType type = static_cast<DataType>(typeId); | |
| if (type == DataType::kINT8 && dqProbs < 0) | |
| { | |
| gLogInfo << "Using default scale factor\n"; | |
| dqProbs = 1.F / 127.F; | |
| } | |
| auto const useInt8ScaleMaxFlag = static_cast<bool>(useInt8ScaleMax); | |
| if (phase == TensorRTPhase::kBUILD) | |
| { | |
| return new QKVToContextVarSeqlenPlugin( | |
| name, type, hiddenSize, numHeads, dqProbs, hasMask, varSeqlen, useInt8ScaleMaxFlag); | |
| } | |
| PLUGIN_VALIDATE(s != -1, "invalid S during runtime plugin creation"); | |
| PLUGIN_VALIDATE(b != -1, "invalid B during runtime plugin creation"); | |
| PLUGIN_VALIDATE(runnerStateBuffer != nullptr, "invalid runnerStateBuffer during runtime plugin creation"); | |
| return new QKVToContextVarSeqlenPlugin(name, s, b, type, hiddenSize, numHeads, dqProbs, hasMask, varSeqlen, | |
| useInt8ScaleMaxFlag, runnerStateBuffer); | |
| } | |
| catch (std::exception const& e) | |
| { | |
| caughtError(e); | |
| } | |
| return nullptr; | |
| } | |
| void QKVToContextVarSeqlenPluginCreator::setPluginNamespace(char const* libNamespace) noexcept | |
| { | |
| mNamespace = libNamespace; | |
| } | |
| char const* QKVToContextVarSeqlenPluginCreator::getPluginNamespace() const noexcept | |
| { | |
| return mNamespace.c_str(); | |
| } | |