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android / platform / packages / modules / NeuralNetworks / refs/heads/android-s-v2-beta-3 / . / runtime / ModelBuilder.cpp
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/*
* Copyright (C) 2017 The Android Open Source Project
*
* 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.
*/
#define LOG_TAG "ModelBuilder"
#include "ModelBuilder.h"
#include <GraphDump.h>
#include <LegacyUtils.h>
#include <algorithm>
#include <map>
#include <memory>
#include <set>
#include <utility>
#include <vector>
#include "CompilationBuilder.h"
#include "Manager.h"
#include "TypeManager.h"
namespace android {
namespace nn {
// The maximum number of operands and operations that a model may have.
const uint32_t MAX_NUMBER_OF_OPERANDS = 0xFFFFFFFE;
const uint32_t MAX_NUMBER_OF_OPERATIONS = 0xFFFFFFFE;
#define NN_VALIDATE_NULL_OR_SIZED(tag, data, length) \
if ((data == nullptr) != (length == 0)) { \
LOG(ERROR) << "ANeuralNetworksModel_" << tag << " " << #data << " is " \
<< (data == nullptr ? "null" : "not null") << " but " << #length << " is " \
<< length; \
return ANEURALNETWORKS_BAD_DATA; \
}
template <typename Type>
static std::vector<Type> makeVector(const Type* data, uint32_t length) {
return length > 0 ? std::vector<Type>(data, data + length) : std::vector<Type>();
}
bool ModelBuilder::badState(const char* name) {
if (mCompletedModel) {
LOG(ERROR) << "ANeuralNetworksModel_" << name << " can't modify after model finished";
return true;
}
if (mInvalidModel) {
LOG(ERROR) << "ANeuralNetworksModel_" << name << " can't modify an invalid model";
return true;
}
return false;
}
int ModelBuilder::getExtensionType(const char* extensionName, uint16_t typeWithinExtension,
int32_t* type) {
return TypeManager::get()->getExtensionType(extensionName, typeWithinExtension, type)
? ANEURALNETWORKS_NO_ERROR
: ANEURALNETWORKS_BAD_DATA;
}
int ModelBuilder::addOperand(const ANeuralNetworksOperandType& type) {
if (badState("addOperand")) {
return ANEURALNETWORKS_BAD_STATE;
}
OperandType operandType = static_cast<OperandType>(type.type);
if (isExtension(operandType) && !TypeManager::get()->areExtensionsAllowed()) {
LOG(ERROR) << "Extensions are not supported for this process.";
return ANEURALNETWORKS_BAD_DATA;
}
bool isOemOperand =
operandType == OperandType::OEM || operandType == OperandType::TENSOR_OEM_BYTE;
if (isOemOperand && !mHasOEMOperand) {
LOG(WARNING) << "OEM data type is deprecated. Use Extensions instead.";
}
const Extension::OperandTypeInformation* info = nullptr;
if (isExtension(operandType) &&
!TypeManager::get()->getExtensionOperandTypeInfo(operandType, &info)) {
LOG(ERROR) << "Extension operand type " << operandType << " is not registered";
return ANEURALNETWORKS_BAD_DATA;
}
NN_VALIDATE_NULL_OR_SIZED("addOperand", type.dimensions, type.dimensionCount);
Operand operand = {
.type = operandType,
.dimensions = makeVector(type.dimensions, type.dimensionCount),
.scale = type.scale,
.zeroPoint = type.zeroPoint,
.lifetime = Operand::LifeTime::TEMPORARY_VARIABLE,
.location = {.poolIndex = 0, .offset = 0, .length = 0},
.extraParams = {},
};
if (auto result = validateOperandType(operand, info, "ANeuralNetworksModel_addOperand", true);
!result.ok()) {
LOG(ERROR) << result.error();
return ANEURALNETWORKS_BAD_DATA;
}
size_t idx = mOperands.size();
if (idx >= MAX_NUMBER_OF_OPERANDS) {
LOG(ERROR) << "ANeuralNetworksModel_addOperand exceed max operands";
return ANEURALNETWORKS_BAD_DATA;
}
mOperands.push_back(std::move(operand));
mHasOEMOperand |= isOemOperand;
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::setOperandValue(uint32_t index, const void* buffer, size_t length) {
VLOG(MODEL) << __func__ << " for operand " << index << " size " << length;
if (badState("setOperandValue")) {
return ANEURALNETWORKS_BAD_STATE;
}
if (index >= operandCount()) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValue setting operand " << index << " of "
<< operandCount();
return ANEURALNETWORKS_BAD_DATA;
}
Operand& operand = mOperands[index];
NN_VALIDATE_NULL_OR_SIZED("setOperandValue", buffer, length);
if (buffer == nullptr) {
operand.lifetime = Operand::LifeTime::NO_VALUE;
// The location is unused and is set to zeros.
operand.location = {.poolIndex = 0, .offset = 0, .length = 0};
} else {
if (TypeManager::get()->isTensorType(operand.type) &&
tensorHasUnspecifiedDimensions(operand)) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValue setting operand " << index
<< " which has operand type that is not fully specified";
return ANEURALNETWORKS_BAD_DATA;
}
if (length > 0xFFFFFFFF) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValue value length of " << length
<< " exceeds max size";
return ANEURALNETWORKS_BAD_DATA;
}
uint32_t valueLength = static_cast<uint32_t>(length);
if (operand.type != OperandType::OEM) {
uint32_t neededLength = TypeManager::get()->getSizeOfData(operand);
if (neededLength != valueLength) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValue setting " << valueLength
<< " bytes when needing " << neededLength;
return ANEURALNETWORKS_BAD_DATA;
}
}
if (valueLength <= ANEURALNETWORKS_MAX_SIZE_OF_IMMEDIATELY_COPIED_VALUES) {
uint32_t existingSize = static_cast<uint32_t>(mSmallOperandValues.size());
uint32_t extraBytes = alignBytesNeeded(existingSize, valueLength);
mSmallOperandValues.resize(existingSize + extraBytes + valueLength);
operand.lifetime = Operand::LifeTime::CONSTANT_COPY;
operand.location = {
.poolIndex = 0, .offset = existingSize + extraBytes, .length = valueLength};
memcpy(&mSmallOperandValues[operand.location.offset], buffer, valueLength);
VLOG(MODEL) << "Copied small value to offset " << operand.location.offset;
} else {
VLOG(MODEL) << "Saving large value";
operand.lifetime = Operand::LifeTime::CONSTANT_REFERENCE;
// The values for poolIndex and offset will be set when the model is finished.
typedef decltype(operand.location.poolIndex) PoolIndexType;
typedef decltype(operand.location.offset) OffsetType;
operand.location = {.poolIndex = ~PoolIndexType(0),
.offset = ~OffsetType(0),
.length = valueLength};
// We keep track of the buffers. We'll allocate the shared memory only
// once we know the total size, to avoid needless copies.
mLargeOperandValues.push_back(LargeValue{.operandIndex = index, .buffer = buffer});
}
}
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::setOperandValueFromModel(uint32_t index, const ModelBuilder* value) {
VLOG(MODEL) << __func__ << " for operand " << index << " model " << value;
if (badState("setOperandValueFromModel")) {
return ANEURALNETWORKS_BAD_STATE;
}
if (!value->mCompletedModel) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValueFromModel value model must be finished";
return ANEURALNETWORKS_BAD_STATE;
}
if (value->mInvalidModel) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValueFromModel value model is invalid";
return ANEURALNETWORKS_BAD_STATE;
}
if (index >= operandCount()) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValueFromModel setting operand " << index
<< " of " << operandCount();
return ANEURALNETWORKS_BAD_DATA;
}
Operand& operand = mOperands[index];
operand.lifetime = Operand::LifeTime::SUBGRAPH;
operand.location = {
.poolIndex = 0,
.offset = static_cast<uint32_t>(mReferencedModels.size()),
.length = 0,
};
mReferencedModels.push_back(value);
mReferencedSubgraphsForValidation.push_back(value->makeModel().main);
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::setOperandSymmPerChannelQuantParams(
uint32_t index, const ANeuralNetworksSymmPerChannelQuantParams& channelQuant) {
if (badState("setOperandSymmPerChannelQuantParams")) {
return ANEURALNETWORKS_BAD_STATE;
}
if (index >= operandCount()) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandSymmPerChannelQuantParams "
<< "setting per-channel quantization parameters for operand " << index << " of "
<< operandCount();
return ANEURALNETWORKS_BAD_DATA;
}
Operand& operand = mOperands[index];
NN_VALIDATE_NULL_OR_SIZED("setOperandSymmPerChannelQuantParams", channelQuant.scales,
channelQuant.scaleCount);
Operand::SymmPerChannelQuantParams extraParams = {
.scales = makeVector(channelQuant.scales, channelQuant.scaleCount),
.channelDim = channelQuant.channelDim,
};
if (auto result = validateOperandSymmPerChannelQuantParams(
operand, extraParams, "ANeuralNetworksModel_setOperandSymmPerChannelQuantParams");
!result.ok()) {
LOG(ERROR) << result.error();
return ANEURALNETWORKS_BAD_DATA;
}
switch (operand.type) {
case OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL:
operand.extraParams = std::move(extraParams);
break;
default:
LOG(ERROR) << "ANeuralNetworksModel_setOperandSymmPerChannelQuantParams "
<< "invalid operand type " << static_cast<int32_t>(operand.type);
return ANEURALNETWORKS_BAD_DATA;
}
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::setOperandExtensionData(uint32_t index, const void* data, size_t length) {
if (badState("setOperandExtensionData")) {
return ANEURALNETWORKS_BAD_STATE;
}
if (index >= operandCount()) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandExtensionData "
<< "setting extension data for operand " << index << " of " << operandCount();
return ANEURALNETWORKS_BAD_DATA;
}
Operand& operand = mOperands[index];
if (!isExtension(operand.type)) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandExtensionData "
<< "setting extension data for a base operand type "
<< static_cast<int32_t>(operand.type);
return ANEURALNETWORKS_BAD_DATA;
}
NN_VALIDATE_NULL_OR_SIZED("setOperandExtensionData", data, length);
if (data == nullptr) {
operand.extraParams = {};
} else {
operand.extraParams = Operand::ExtensionParams(
std::vector<uint8_t>(reinterpret_cast<const uint8_t*>(data),
reinterpret_cast<const uint8_t*>(data) + length));
}
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::copyLargeValuesToSharedMemory() {
VLOG(MODEL) << __func__ << " has " << mLargeOperandValues.size() << " values.";
if (!mLargeOperandValues.empty()) {
// Calculate the size of the shared memory needed for all the large values.
// Also sets the offset for each value within the memory.
size_t poolSize = 0;
for (LargeValue& l : mLargeOperandValues) {
Operand& operand = mOperands[l.operandIndex];
CHECK_EQ(operand.lifetime, Operand::LifeTime::CONSTANT_REFERENCE);
poolSize += alignBytesNeeded(poolSize, operand.location.length);
operand.location.offset = poolSize;
poolSize += operand.location.length;
}
// Allocate the shared memory.
int n;
std::tie(n, mLargeValueMemory) = MemoryAshmem::create(poolSize);
NN_RETURN_IF_ERROR(n);
uint8_t* memoryPointer = mLargeValueMemory->getPointer();
uint32_t poolIndex = mMemories.add(mLargeValueMemory.get());
VLOG(MODEL) << "Allocated large value pool of size " << poolSize << " at index "
<< poolIndex;
// Copy the values to this memory.
for (LargeValue& l : mLargeOperandValues) {
Operand& operand = mOperands[l.operandIndex];
operand.location.poolIndex = poolIndex;
memcpy(memoryPointer + operand.location.offset, l.buffer, operand.location.length);
}
}
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::setOperandValueFromMemory(uint32_t index, const RuntimeMemory* memory,
uint32_t offset, size_t length) {
VLOG(MODEL) << __func__ << " for operand " << index << " offset " << offset << " size "
<< length;
if (badState("setOperandValueFromMemory")) {
return ANEURALNETWORKS_BAD_STATE;
}
if (index >= operandCount()) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValueFromMemory setting operand " << index
<< " of " << operandCount();
return ANEURALNETWORKS_BAD_DATA;
}
Operand& operand = mOperands[index];
if (TypeManager::get()->isTensorType(operand.type) && tensorHasUnspecifiedDimensions(operand)) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValueFromMemory setting operand " << index
<< " which has operand type that is not fully specified";
return ANEURALNETWORKS_BAD_DATA;
}
uint32_t neededLength = TypeManager::get()->getSizeOfData(operand);
if (neededLength != length) {
LOG(ERROR) << "ANeuralNetworksModel_setOperandValueFromMemory setting " << length
<< " bytes when needing " << neededLength;
return ANEURALNETWORKS_BAD_DATA;
}
// Set compilation = nullptr to indicate that the memory is used for a model constant.
// In this case, IOType::INPUT is a placeholder value that is ignored by the validator.
if (!memory->getValidator().validate(/*compilation=*/nullptr, /*placeholder*/ IOType::INPUT,
index, nullptr, offset, length)) {
return ANEURALNETWORKS_BAD_DATA;
}
operand.lifetime = Operand::LifeTime::CONSTANT_REFERENCE;
operand.location = {.poolIndex = mMemories.add(memory),
.offset = offset,
.length = static_cast<uint32_t>(length)};
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::addOperation(ANeuralNetworksOperationType type, uint32_t inputCount,
const uint32_t* inputs, uint32_t outputCount,
const uint32_t* outputs) {
if (badState("addOperation")) {
return ANEURALNETWORKS_BAD_STATE;
}
OperationType operationType = static_cast<OperationType>(type);
if (isExtension(operationType) && !TypeManager::get()->areExtensionsAllowed()) {
LOG(ERROR) << "Extensions are not supported for this process.";
return ANEURALNETWORKS_BAD_DATA;
}
if (operationType == OperationType::OEM_OPERATION && !mHasOEMOperation) {
LOG(WARNING) << "OEM_OPERATION is deprecated. Use Extensions instead.";
}
if (!isExtension(operationType)) {
if (!validCode(kNumberOfOperationTypes, kNumberOfOperationTypesOEM, type)) {
LOG(ERROR) << "ANeuralNetworksModel_addOperation invalid operation type " << type;
return ANEURALNETWORKS_BAD_DATA;
}
} else {
const Extension* extension;
uint16_t extensionPrefix = getExtensionPrefix(static_cast<uint32_t>(operationType));
if (!TypeManager::get()->getExtensionInfo(extensionPrefix, &extension)) {
LOG(ERROR) << "Extension operation type " << operationType << " is not recognized";
return ANEURALNETWORKS_BAD_DATA;
}
}
NN_VALIDATE_NULL_OR_SIZED("addOperation", inputs, inputCount);
NN_VALIDATE_NULL_OR_SIZED("addOperation", outputs, outputCount);
Operation operation = {
.type = operationType,
.inputs = makeVector(inputs, inputCount),
.outputs = makeVector(outputs, outputCount),
};
if (auto result = validateOperationButNotOperands(operation, mOperands,
mReferencedSubgraphsForValidation);
!result.ok()) {
LOG(ERROR) << "Invalid Operation: " << result.error();
return ANEURALNETWORKS_BAD_DATA;
}
uint32_t operationIndex = operationCount();
if (operationIndex >= MAX_NUMBER_OF_OPERATIONS) {
LOG(ERROR) << "ANeuralNetworksModel_addOperation exceed max operations";
return ANEURALNETWORKS_BAD_DATA;
}
mOperations.push_back(std::move(operation));
mHasOEMOperation |= (operationType == OperationType::OEM_OPERATION);
mHasExtensionOperation |= isExtension(operationType);
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::identifyInputsAndOutputs(uint32_t inputCount, const uint32_t* inputs,
uint32_t outputCount, const uint32_t* outputs) {
if (badState("identifyInputsAndOutputs")) {
return ANEURALNETWORKS_BAD_STATE;
}
NN_VALIDATE_NULL_OR_SIZED("identifyInputsAndOutputs", inputs, inputCount);
if (auto result = validateOperandList(makeVector(inputs, inputCount), operandCount(),
"ANeuralNetworksModel_identifyInputsAndOutputs inputs");
!result.ok()) {
LOG(ERROR) << result.error();
return ANEURALNETWORKS_BAD_DATA;
}
NN_VALIDATE_NULL_OR_SIZED("identifyInputsAndOutputs", outputs, outputCount);
if (auto result = validateOperandList(makeVector(outputs, outputCount), operandCount(),
"ANeuralNetworksModel_identifyInputsAndOutputs outputs");
!result.ok()) {
LOG(ERROR) << result.error();
return ANEURALNETWORKS_BAD_DATA;
}
// Makes a copy of the index list, validates the arguments, and changes
// the lifetime info of the corresponding operand.
auto setArguments = [&](std::vector<uint32_t>* indexVector, uint32_t indexCount,
const uint32_t* indexList, Operand::LifeTime lifetime) -> bool {
indexVector->resize(indexCount);
for (uint32_t i = 0; i < indexCount; i++) {
const uint32_t operandIndex = indexList[i];
if (operandIndex >= mOperands.size()) {
LOG(ERROR) << "ANeuralNetworksModel_identifyInputsAndOutputs Can't set input or "
"output "
"to be "
<< operandIndex << " as this exceeds the numbe of operands "
<< mOperands.size();
return false;
}
(*indexVector)[i] = operandIndex;
Operand& operand = mOperands[operandIndex];
if (operand.lifetime != Operand::LifeTime::TEMPORARY_VARIABLE) {
LOG(ERROR) << "ANeuralNetworksModel_identifyInputsAndOutputs Can't set operand "
<< operandIndex
<< " to be an input or output. Check that it's not a constant or "
"already an input or output";
return false;
}
operand.lifetime = lifetime;
}
return true;
};
if (!setArguments(&mInputIndexes, inputCount, inputs, Operand::LifeTime::SUBGRAPH_INPUT) ||
!setArguments(&mOutputIndexes, outputCount, outputs, Operand::LifeTime::SUBGRAPH_OUTPUT)) {
return ANEURALNETWORKS_BAD_DATA;
}
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::relaxComputationFloat32toFloat16(bool allow) {
if (badState("relaxComputationFloat32toFloat16")) {
return ANEURALNETWORKS_BAD_STATE;
}
mRelaxComputationFloat32toFloat16 = allow;
return ANEURALNETWORKS_NO_ERROR;
}
int ModelBuilder::createCompilation(CompilationBuilder** compilation,
const std::vector<std::shared_ptr<Device>>& devices,
bool explicitDeviceList) {
if (!mCompletedModel || mInvalidModel) {
LOG(ERROR) << "ANeuralNetworksCompilation_create passed an unfinished or invalid model";
*compilation = nullptr;
return ANEURALNETWORKS_BAD_STATE;
}
*compilation = new (std::nothrow) CompilationBuilder(this, devices, explicitDeviceList);
return (*compilation ? ANEURALNETWORKS_NO_ERROR : ANEURALNETWORKS_OUT_OF_MEMORY);
}
int ModelBuilder::finish() {
if (mCompletedModel) {
LOG(ERROR) << "ANeuralNetworksModel_finish called more than once";
return ANEURALNETWORKS_BAD_STATE;
}
if (mInvalidModel) {
LOG(ERROR) << "ANeuralNetworksModel_finish called on an invalid model";
return ANEURALNETWORKS_BAD_STATE;
}
int n = copyLargeValuesToSharedMemory();
if (n != ANEURALNETWORKS_NO_ERROR) {
return n;
}
// We sort the operations so that they will be in the appropriate
// order for a single-threaded, op at a time execution.
// TODO: we don't need this if we always run the partitioner.
if (!sortIntoRunOrder()) {
// We expect sortIntoRunOrder() to have logged an appropriate error message.
mInvalidModel = true;
return ANEURALNETWORKS_BAD_DATA;
}
// TODO: Modify validation so that it can be called without creating a Model.
// NOTE: Must sortIntoRunOrder() before validation; validator expects operations
// to have been sorted.
// NOTE: Must copyLargeValuesToSharedMemory() before validation; otherwise,
// a CONSTANT_REFERENCE operand will not have correct .poolIndex, and
// validation will not work properly.
const Model modelForValidation = makeModel();
if (auto result = validate(modelForValidation); !result.ok()) {
LOG(ERROR) << "ANeuralNetworksModel_finish called on invalid model: " << result.error();
mInvalidModel = true;
return ANEURALNETWORKS_BAD_DATA;
}
if (VLOG_IS_ON(MODEL)) {
graphDump("ModelBuilder::finish", modelForValidation, nullptr);
}
removeTrailingArgumentsWithDefaultValues();
mCompletedModel = true;
return ANEURALNETWORKS_NO_ERROR;
}
static void logRemoval(const Operation& operation, uint32_t count,
const std::vector<Operand>& operands) {
std::ostringstream message;
message << "Operation " << operation.type << " with inputs {";
for (uint32_t i = 0; i < operation.inputs.size(); ++i) {
if (i != 0) {
message << ", ";
}
message << operands[operation.inputs[i]].type;
}
message << "} has trailing optional inputs set to default values. Removing " << count
<< " trailing inputs.";
VLOG(MODEL) << message.str();
}
void ModelBuilder::removeTrailingArgumentsWithDefaultValues() {
for (Operation& operation : mOperations) {
const uint32_t count = getNumTrailingArgumentsToRemove(operation);
if (count == 0) {
continue;
}
if (VLOG_IS_ON(MODEL)) {
logRemoval(operation, count, mOperands);
}
const uint32_t inputCount = operation.inputs.size();
CHECK_LT(count, inputCount);
const uint32_t newInputCount = inputCount - count;
operation.inputs.resize(newInputCount);
}
}
// See countMatchingTrailingArguments().
enum class TailSpec {
BOOL_FALSE,
INT32_ONE,
INT32_NEGATIVE_ONE,
};
// See countMatchingTrailingArguments().
static bool matchesSpec(TailSpec spec, const Operand& operand,
const std::vector<uint8_t>& mSmallOperandValues) {
const void* valuePtr = nullptr;
if (operand.lifetime == Operand::LifeTime::CONSTANT_COPY) {
valuePtr = static_cast<const void*>(&mSmallOperandValues[operand.location.offset]);
} else if (operand.lifetime == Operand::LifeTime::POINTER) {
valuePtr = std::get<const void*>(operand.location.pointer);
} else {
// CONSTANT_REFERENCE operands are not supported to avoid mapping memory
// during compilation.
return false;
}
switch (spec) {
case TailSpec::BOOL_FALSE:
return operand.type == OperandType::BOOL &&
*static_cast<const bool8*>(valuePtr) == false;
case TailSpec::INT32_ONE:
return operand.type == OperandType::INT32 &&
*static_cast<const int32_t*>(valuePtr) == 1;
case TailSpec::INT32_NEGATIVE_ONE:
return operand.type == OperandType::INT32 &&
*static_cast<const int32_t*>(valuePtr) == -1;
default:
CHECK(false) << "Unhandled TailSpec: " << static_cast<int>(spec);
}
}
// Returns the number of trailing operation inputs that match the specification.
//
// Example:
// opeation.inputs = {BOOL_TRUE, BOOL_TRUE, INT32_ONE, INT32_NEGATIVE_ONE}
// tail = {BOOL_FALSE, INT32_ONE, INT32_NEGATIVE_ONE}
// tailStartIndex = 1 matching elements: ^^^^^^^^^ ^^^^^^^^^^^^^^^^^^
static uint32_t countMatchingTrailingArguments(uint32_t tailStartIndex,
const std::vector<TailSpec>& tail,
const Operation& operation,
const std::vector<Operand>& operands,
const std::vector<uint8_t>& smallOperandValues) {
const uint32_t inputCount = operation.inputs.size();
uint32_t count = 0;
for (uint32_t i = inputCount - 1; i >= tailStartIndex; --i) {
const Operand& operand = operands[operation.inputs[i]];
if (!matchesSpec(tail[i - tailStartIndex], operand, smallOperandValues)) {
break;
}
++count;
}
return count;
}
uint32_t ModelBuilder::getNumTrailingArgumentsToRemove(const Operation& operation) const {
const uint32_t inputCount = operation.inputs.size();
auto getCount = [this, &operation](uint32_t tailStartIndex, const std::vector<TailSpec>& tail) {
return countMatchingTrailingArguments(tailStartIndex, tail, operation, mOperands,
mSmallOperandValues);
};
using TS = TailSpec;
// Check if the operation has optional arguments that might be set to default
// values. Skip the counting if no optional arguments are present.
switch (operation.type) {
case OperationType::AVERAGE_POOL_2D: {
if (inputCount == 11 && mOperands[operation.inputs[7]].type == OperandType::INT32) {
// Explicit padding
// API level 29: 10 to 11 inputs
// API level 27: 10 inputs
return getCount(10, {TS::BOOL_FALSE});
} else if (inputCount == 8 &&
mOperands[operation.inputs[7]].type == OperandType::BOOL) {
// Implicit padding
// API level 29: 7 to 8 inputs
// API level 27: 7 inputs
return getCount(7, {TS::BOOL_FALSE});
}
} break;
case OperationType::CONV_2D: {
if (10 < inputCount && inputCount <= 13 &&
mOperands[operation.inputs[7]].type == OperandType::INT32) {
// Explicit padding
// API level 29: 10 to 13 inputs
// API level 27: 10 inputs
uint32_t count = getCount(10, {TS::BOOL_FALSE, TS::INT32_ONE, TS::INT32_ONE});
// Inputs 11 and 12 must come together.
return inputCount - count == 12 ? 0 : count;
} else if (7 < inputCount && inputCount <= 10 &&
mOperands[operation.inputs[7]].type == OperandType::BOOL) {
// Implicit padding
// API level 29: 7 to 10 inputs
// API level 27: 7 inputs
uint32_t count = getCount(7, {TS::BOOL_FALSE, TS::INT32_ONE, TS::INT32_ONE});
// Inputs 8 and 9 must come together.
return inputCount - count == 9 ? 0 : count;
}
} break;
case OperationType::DEPTHWISE_CONV_2D: {
if (11 < inputCount && inputCount <= 14 &&
mOperands[operation.inputs[8]].type == OperandType::INT32) {
// Explicit padding
// API level 29: 11 to 14 inputs
// API level 27: 11 inputs
uint32_t count = getCount(11, {TS::BOOL_FALSE, TS::INT32_ONE, TS::INT32_ONE});
// Inputs 12 and 13 must come together.
return inputCount - count == 13 ? 0 : count;
} else if (8 < inputCount && inputCount <= 11 &&
mOperands[operation.inputs[8]].type == OperandType::BOOL) {
// Implicit padding
// API level 29: 8 to 11 inputs
// API level 27: 8 inputs
uint32_t count = getCount(8, {TS::BOOL_FALSE, TS::INT32_ONE, TS::INT32_ONE});
// Inputs 9 and 10 must come together.
return inputCount - count == 10 ? 0 : count;
}
} break;
case OperationType::DEPTH_TO_SPACE: {
if (inputCount == 3) {
// API level 29: 2 to 3 inputs
// API level 27: 2 inputs
return getCount(2, {TS::BOOL_FALSE});
}
} break;
case OperationType::L2_NORMALIZATION: {
if (inputCount == 2) {
// API level 29: 1 to 2 inputs
// API level 27: 1 inputs
return getCount(1, {TS::INT32_NEGATIVE_ONE});
}
} break;
case OperationType::L2_POOL_2D: {
if (inputCount == 11 && mOperands[operation.inputs[7]].type == OperandType::INT32) {
// Explicit padding
// API level 29: 10 to 11 inputs
// API level 27: 10 inputs
return getCount(10, {TS::BOOL_FALSE});
} else if (inputCount == 8 &&
mOperands[operation.inputs[7]].type == OperandType::BOOL) {
// Implicit padding
// API level 29: 7 to 8 inputs
// API level 27: 7 inputs
return getCount(7, {TS::BOOL_FALSE});
}
} break;
case OperationType::LOCAL_RESPONSE_NORMALIZATION: {
if (inputCount == 6) {
// API level 29: 5 to 6 inputs
// API level 27: 5 inputs
return getCount(5, {TS::INT32_NEGATIVE_ONE});
}
} break;
case OperationType::MAX_POOL_2D: {
if (inputCount == 11 && mOperands[operation.inputs[7]].type == OperandType::INT32) {
// Explicit padding
// API level 29: 10 to 11 inputs
// API level 27: 10 inputs
return getCount(10, {TS::BOOL_FALSE});
} else if (inputCount == 8 &&
mOperands[operation.inputs[7]].type == OperandType::BOOL) {
// Implicit padding
// API level 29: 7 to 8 inputs
// API level 27: 7 inputs
return getCount(7, {TS::BOOL_FALSE});
}
} break;
case OperationType::RESIZE_BILINEAR: {
if (3 < inputCount && inputCount <= 6) {
// By shape:
// API level 30: 3 to 6 inputs
// API level 29: 3 to 4 inputs
// API level 27: 3 inputs
// By scale:
// API level 30: 3 to 6 inputs
// API level 29: 3 to 4 inputs
return getCount(3, {TS::BOOL_FALSE, TS::BOOL_FALSE, TS::BOOL_FALSE});
}
} break;
case OperationType::SOFTMAX: {
if (inputCount == 3) {
// API level 29: 2 to 3 inputs
// API level 27: 2 inputs
return getCount(2, {TS::INT32_NEGATIVE_ONE});
}
} break;
case OperationType::SPACE_TO_DEPTH: {
if (inputCount == 3) {
// API level 29: 2 to 3 inputs
// API level 27: 2 inputs
return getCount(2, {TS::BOOL_FALSE});
}
} break;
case OperationType::BATCH_TO_SPACE_ND: {
if (inputCount == 3) {
// API level 29: 2 to 3 inputs
// API level 28: 2 inputs
return getCount(2, {TS::BOOL_FALSE});
}
} break;
case OperationType::SPACE_TO_BATCH_ND: {
if (inputCount == 4) {
// API level 29: 3 to 4 inputs
// API level 28: 3 inputs
return getCount(3, {TS::BOOL_FALSE});
}
} break;
case OperationType::RESIZE_NEAREST_NEIGHBOR: {
if (4 < inputCount && inputCount <= 6) {
// By shape or scale
// API level 30: 4 to 6 inputs
// API level 29: 4 inputs
return getCount(4, {TS::BOOL_FALSE, TS::BOOL_FALSE});
}
} break;
default: {
// Do nothing.
} break;
}
// No trailing optional arguments to check.
return 0;
}
bool ModelBuilder::sortIntoRunOrder() {
// Note that this may be called before the model has been
// validated, so we must code defensively. However, we can assume
// an Operation's inputs and outputs have legal indices -- this
// should have been checked in addOperation().
if (!mSortedOperationIndexMap.empty()) {
LOG(ERROR) << "Operations were already sorted into run order.";
return true;
}
// Tracks the operations that can be executed.
std::vector<uint32_t> sortedOperationIndexMap;
std::vector<uint32_t> opsReadyToRun;
std::vector<Operation> runOrder;
// Tracks how many inputs are needed for each operation to be ready to run.
std::multimap<uint32_t, uint32_t> operandToOperations;
std::vector<uint32_t> unknownInputCount(operationCount());
for (uint32_t operationIndex = 0; operationIndex < operationCount(); operationIndex++) {
uint32_t& count = unknownInputCount[operationIndex];
count = 0;
for (uint32_t operandIndex : mOperations[operationIndex].inputs) {
auto lifetime = mOperands[operandIndex].lifetime;
if (lifetime == Operand::LifeTime::TEMPORARY_VARIABLE ||
lifetime == Operand::LifeTime::SUBGRAPH_OUTPUT) {
count++;
operandToOperations.insert(
std::pair<uint32_t, uint32_t>(operandIndex, operationIndex));
}
}
if (count == 0) {
opsReadyToRun.push_back(operationIndex);
}
}
while (opsReadyToRun.size() > 0) {
// Execute the next op
int opIndex = opsReadyToRun.back();
opsReadyToRun.pop_back();
const Operation& operation = mOperations[opIndex];
runOrder.push_back(mOperations[opIndex]);
sortedOperationIndexMap.push_back(opIndex);
// Mark all its outputs as known.
for (uint32_t operandIndex : operation.outputs) {
auto range = operandToOperations.equal_range(operandIndex);
for (auto i = range.first; i != range.second; i++) {
uint32_t& count = unknownInputCount[i->second];
if (--count == 0) {
opsReadyToRun.push_back(i->second);
}
}
}
}
if (runOrder.size() != mOperations.size()) {
nnAssert(runOrder.size() < mOperations.size());
// Graph must contain at least one cycle or one never-written
// operand, because there is at least one Operation that never
// became ready.
LOG(ERROR) << "Graph contains at least one cycle or one never-written operand";
return false;
}
mSortedOperationIndexMap = std::move(sortedOperationIndexMap);
mOperations = std::move(runOrder);
return true;
}
// A helper class to simplify state management when creating a Model.
class ModelBuilder::ModelMaker {
public:
static Model run(const ModelBuilder* model);
private:
static Model::Subgraph makeSubgraph(const ModelBuilder* model);
ModelMaker() {}
Model makeModel(const ModelBuilder* mainModel);
uint32_t addSubgraph(const ModelBuilder* refModel);
void updateOperandLocations(const ModelBuilder* refModel, Model::Subgraph* subgraph);
void addExtensions(const ModelBuilder* model);
void addExtensionWithPrefix(uint16_t prefix);
std::vector<Model::Subgraph> mRefSubgraphs;
Model::OperandValues mOperandValues;
MemoryTracker mMemories;
std::vector<Model::ExtensionNameAndPrefix> mExtensionNameToPrefix;
std::set<uint16_t> mPrefixSet;
};
Model ModelBuilder::makeModel() const {
// TODO: Cache the Model to speed up subsequent calls.
return ModelMaker::run(this);
}
Model ModelBuilder::ModelMaker::run(const ModelBuilder* model) {
// run() ensures the state of ModelMaker is destroyed after the call.
return ModelMaker().makeModel(model);
}
Model ModelBuilder::ModelMaker::makeModel(const ModelBuilder* mainModel) {
addExtensions(mainModel);
Model model;
model.main = makeSubgraph(mainModel);
updateOperandLocations(mainModel, &model.main);
model.referenced = std::move(mRefSubgraphs);
model.operandValues = std::move(mOperandValues);
model.pools.reserve(mMemories.size());
std::transform(mMemories.begin(), mMemories.end(), std::back_inserter(model.pools),
[](const RuntimeMemory* m) { return m->getMemory(); });
model.relaxComputationFloat32toFloat16 = mainModel->mRelaxComputationFloat32toFloat16;
model.extensionNameToPrefix = std::move(mExtensionNameToPrefix);
return model;
}
Model::Subgraph ModelBuilder::ModelMaker::makeSubgraph(const ModelBuilder* model) {
Model::Subgraph subgraph;
subgraph.operands = model->mOperands;
subgraph.operations = model->mOperations;
subgraph.inputIndexes = model->mInputIndexes;
subgraph.outputIndexes = model->mOutputIndexes;
return subgraph;
}
void ModelBuilder::ModelMaker::updateOperandLocations(const ModelBuilder* refModel,
Model::Subgraph* subgraph) {
for (Operand& operand : subgraph->operands) {
if (operand.lifetime == Operand::LifeTime::CONSTANT_COPY) {
uint32_t valueLength = operand.location.length;
uint32_t originalOffset = operand.location.offset;
operand.location = mOperandValues.append(&refModel->mSmallOperandValues[originalOffset],
valueLength);
} else if (operand.lifetime == Operand::LifeTime::CONSTANT_REFERENCE) {
uint32_t originalPoolIndex = operand.location.poolIndex;
operand.location.poolIndex = mMemories.add(refModel->mMemories[originalPoolIndex]);
}
}
// Do recursive calls at the end to improve locality of mOperandValues.
for (Operand& operand : subgraph->operands) {
if (operand.lifetime == Operand::LifeTime::SUBGRAPH) {
uint32_t refModelIndex = operand.location.offset;
// TODO(b/147875885): Avoid creating duplicate refSubgraphs when
// a single refModel is referenced multiple times.
operand.location.offset = addSubgraph(refModel->mReferencedModels[refModelIndex]);
}
}
}
uint32_t ModelBuilder::ModelMaker::addSubgraph(const ModelBuilder* refModel) {
uint32_t index = mRefSubgraphs.size();
mRefSubgraphs.push_back(makeSubgraph(refModel));
updateOperandLocations(refModel, &mRefSubgraphs.back());
return index;
}
void ModelBuilder::ModelMaker::addExtensions(const ModelBuilder* model) {
for (const auto& operand : model->mOperands) {
if (isExtension(operand.type)) {
addExtensionWithPrefix(static_cast<uint32_t>(operand.type) >> kExtensionTypeBits);
}
}
for (const auto& operation : model->mOperations) {
if (isExtension(operation.type)) {
addExtensionWithPrefix(static_cast<uint32_t>(operation.type) >> kExtensionTypeBits);
}
}
for (const auto& refModel : model->mReferencedModels) {
addExtensions(refModel);
}
}
void ModelBuilder::ModelMaker::addExtensionWithPrefix(uint16_t prefix) {
if (!mPrefixSet.insert(prefix).second) {
return;
}
const Extension* extension;
CHECK(TypeManager::get()->getExtensionInfo(prefix, &extension));
mExtensionNameToPrefix.push_back({
.name = extension->name,
.prefix = prefix,
});
}
#undef NN_VALIDATE_NULL_OR_SIZED
} // namespace nn
} // namespace android