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//
// Copyright © 2017 Arm Ltd. All rights reserved.
// SPDX-License-Identifier: MIT
//
#include "JsonPrinterTestImpl.hpp"
#include "armnn/utility/StringUtils.hpp"
#include <Profiling.hpp>
#include <armnn/Descriptors.hpp>
#include <armnn/IRuntime.hpp>
#include <armnn/INetwork.hpp>
#include <boost/test/unit_test.hpp>
#include <sstream>
#include <stack>
#include <string>
inline bool AreMatchingPair(const char opening, const char closing)
{
return (opening == '{' && closing == '}') || (opening == '[' && closing == ']');
}
bool AreParenthesesMatching(const std::string& exp)
{
std::stack<char> expStack;
for (size_t i = 0; i < exp.length(); ++i)
{
if (exp[i] == '{' || exp[i] == '[')
{
expStack.push(exp[i]);
}
else if (exp[i] == '}' || exp[i] == ']')
{
if (expStack.empty() || !AreMatchingPair(expStack.top(), exp[i]))
{
return false;
}
else
{
expStack.pop();
}
}
}
return expStack.empty();
}
std::vector<double> ExtractMeasurements(const std::string& exp)
{
std::vector<double> numbers;
bool inArray = false;
std::string numberString;
for (size_t i = 0; i < exp.size(); ++i)
{
if (exp[i] == '[')
{
inArray = true;
}
else if (exp[i] == ']' && inArray)
{
try
{
armnn::stringUtils::StringTrim(numberString, "\t,\n");
numbers.push_back(std::stod(numberString));
}
catch (std::invalid_argument const&)
{
BOOST_FAIL("Could not convert measurements to double: " + numberString);
}
numberString.clear();
inArray = false;
}
else if (exp[i] == ',' && inArray)
{
try
{
armnn::stringUtils::StringTrim(numberString, "\t,\n");
numbers.push_back(std::stod(numberString));
}
catch (std::invalid_argument const&)
{
BOOST_FAIL("Could not convert measurements to double: " + numberString);
}
numberString.clear();
}
else if (exp[i] != '[' && inArray && exp[i] != ',' && exp[i] != ' ')
{
numberString += exp[i];
}
}
return numbers;
}
std::vector<std::string> ExtractSections(const std::string& exp)
{
std::vector<std::string> sections;
std::stack<size_t> s;
for (size_t i = 0; i < exp.size(); i++)
{
if (exp.at(i) == '{')
{
s.push(i);
}
else if (exp.at(i) == '}')
{
size_t from = s.top();
s.pop();
sections.push_back(exp.substr(from, i - from + 1));
}
}
return sections;
}
std::string GetSoftmaxProfilerJson(const std::vector<armnn::BackendId>& backends)
{
using namespace armnn;
BOOST_CHECK(!backends.empty());
ProfilerManager& profilerManager = armnn::ProfilerManager::GetInstance();
// Create runtime in which test will run
IRuntime::CreationOptions options;
options.m_EnableGpuProfiling = backends.front() == armnn::Compute::GpuAcc;
IRuntimePtr runtime(IRuntime::Create(options));
// build up the structure of the network
INetworkPtr net(INetwork::Create());
IConnectableLayer* input = net->AddInputLayer(0, "input");
SoftmaxDescriptor softmaxDescriptor;
// Set Axis to 0 if CL or Neon until further Axes are supported.
if ( backends.front() == armnn::Compute::CpuAcc || backends.front() == armnn::Compute::GpuAcc)
{
softmaxDescriptor.m_Axis = 0;
}
IConnectableLayer* softmax = net->AddSoftmaxLayer(softmaxDescriptor, "softmax");
IConnectableLayer* output = net->AddOutputLayer(0, "output");
input->GetOutputSlot(0).Connect(softmax->GetInputSlot(0));
softmax->GetOutputSlot(0).Connect(output->GetInputSlot(0));
// set the tensors in the network
TensorInfo inputTensorInfo(TensorShape({1, 5}), DataType::QAsymmU8);
inputTensorInfo.SetQuantizationOffset(100);
inputTensorInfo.SetQuantizationScale(10000.0f);
input->GetOutputSlot(0).SetTensorInfo(inputTensorInfo);
TensorInfo outputTensorInfo(TensorShape({1, 5}), DataType::QAsymmU8);
outputTensorInfo.SetQuantizationOffset(0);
outputTensorInfo.SetQuantizationScale(1.0f / 256.0f);
softmax->GetOutputSlot(0).SetTensorInfo(outputTensorInfo);
// optimize the network
IOptimizedNetworkPtr optNet = Optimize(*net, backends, runtime->GetDeviceSpec());
if(!optNet)
{
BOOST_FAIL("Error occurred during Optimization, Optimize() returned nullptr.");
}
// load it into the runtime
NetworkId netId;
auto error = runtime->LoadNetwork(netId, std::move(optNet));
BOOST_TEST(error == Status::Success);
// create structures for input & output
std::vector<uint8_t> inputData
{
1, 10, 3, 200, 5
// one of inputs is sufficiently larger than the others to saturate softmax
};
std::vector<uint8_t> outputData(5);
armnn::InputTensors inputTensors
{
{0, armnn::ConstTensor(runtime->GetInputTensorInfo(netId, 0), inputData.data())}
};
armnn::OutputTensors outputTensors
{
{0, armnn::Tensor(runtime->GetOutputTensorInfo(netId, 0), outputData.data())}
};
runtime->GetProfiler(netId)->EnableProfiling(true);
// do the inferences
runtime->EnqueueWorkload(netId, inputTensors, outputTensors);
runtime->EnqueueWorkload(netId, inputTensors, outputTensors);
runtime->EnqueueWorkload(netId, inputTensors, outputTensors);
// retrieve the Profiler.Print() output
std::stringstream ss;
profilerManager.GetProfiler()->Print(ss);
return ss.str();
}
inline void ValidateProfilerJson(std::string& result)
{
// ensure all measurements are greater than zero
std::vector<double> measurementsVector = ExtractMeasurements(result);
BOOST_CHECK(!measurementsVector.empty());
// check sections contain raw and unit tags
// first ensure Parenthesis are balanced
if (AreParenthesesMatching(result))
{
// remove parent sections that will not have raw or unit tag
std::vector<std::string> sectionVector = ExtractSections(result);
for (size_t i = 0; i < sectionVector.size(); ++i)
{
if (sectionVector[i].find("\"ArmNN\":") != std::string::npos
|| sectionVector[i].find("\"inference_measurements\":") != std::string::npos)
{
sectionVector.erase(sectionVector.begin() + static_cast<int>(i));
}
}
BOOST_CHECK(!sectionVector.empty());
BOOST_CHECK(std::all_of(sectionVector.begin(), sectionVector.end(),
[](std::string i) { return (i.find("\"raw\":") != std::string::npos); }));
BOOST_CHECK(std::all_of(sectionVector.begin(), sectionVector.end(),
[](std::string i) { return (i.find("\"unit\":") != std::string::npos); }));
}
// remove the time measurements as they vary from test to test
result.erase(std::remove_if (result.begin(),result.end(),
[](char c) { return c == '.'; }), result.end());
result.erase(std::remove_if (result.begin(), result.end(), &isdigit), result.end());
result.erase(std::remove_if (result.begin(),result.end(),
[](char c) { return c == '\t'; }), result.end());
BOOST_CHECK(result.find("ArmNN") != std::string::npos);
BOOST_CHECK(result.find("inference_measurements") != std::string::npos);
// ensure no spare parenthesis present in print output
BOOST_CHECK(AreParenthesesMatching(result));
}
void RunSoftmaxProfilerJsonPrinterTest(const std::vector<armnn::BackendId>& backends)
{
// setup the test fixture and obtain JSON Printer result
std::string result = GetSoftmaxProfilerJson(backends);
// validate the JSON Printer result
ValidateProfilerJson(result);
const armnn::BackendId& firstBackend = backends.at(0);
if (firstBackend == armnn::Compute::GpuAcc)
{
BOOST_CHECK(result.find("OpenClKernelTimer/: softmax_layer_max_shift_exp_sum_quantized_serial GWS[,,]")
!= std::string::npos);
}
else if (firstBackend == armnn::Compute::CpuAcc)
{
BOOST_CHECK(result.find("NeonKernelTimer/: NEFillBorderKernel") != std::string::npos);
}
}
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