SMUCNGPerfOperator.cpp 10.5 KB
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//================================================================================
// Name        : SMUCNGPerfOperator.cpp
// Author      : Carla Guillen
// Contact     : info@dcdb.it
// Copyright   : Leibniz Supercomputing Centre
// Description : Template implementing features to use Units in Operators.
//================================================================================

//================================================================================
// This file is part of DCDB (DataCenter DataBase)
// Copyright (C) 2018-2019 Leibniz Supercomputing Centre
//
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License
// as published by the Free Software Foundation; either version 2
// of the License, or (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301, USA.
//================================================================================
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#include "SMUCNGPerfOperator.h"
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#include <boost/log/sources/record_ostream.hpp>
#include <boost/log/utility/formatting_ostream.hpp>
#include <boost/parameter/keyword.hpp>
#include <cstdint>
#include <memory>
#include <string>
#include <utility>
#include <vector>

#include "../../../common/include/cacheentry.h"
#include "../../../common/include/logging.h"
#include "../../../common/include/sensorbase.h"
#include "../../../common/include/timestamp.h"
#include "../../includes/DerivedMetrics.h"
#include "../../includes/QueryEngine.h"
#include "../../includes/UnitTemplate.h"
#include "SKXPMUMetrics.h"

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SMUCNGPerfOperator::SMUCNGPerfOperator(const std::string& name): OperatorTemplate(name) {
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    _buffers.resize(64);
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}

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SMUCNGPerfOperator::~SMUCNGPerfOperator() {
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}

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SMUCNGPerfOperator::SMUCNGPerfOperator(const SMUCNGPerfOperator& other) : OperatorTemplate(other){
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    copy(other);
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}

SMUCNGPerfOperator& SMUCNGPerfOperator::operator=(const SMUCNGPerfOperator& other){
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    OperatorTemplate::operator =(other);
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    copy(other);
    return *this;
}

void SMUCNGPerfOperator::copy(const SMUCNGPerfOperator& other){
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    this->_buffers = other._buffers;
    this->_metricToPosition = other._metricToPosition;
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    //this->_measurement_interval = other._measurement_interval;
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}

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void SMUCNGPerfOperator::printConfig(LOG_LEVEL ll) {
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    OperatorTemplate<SMUCSensorBase>::printConfig(ll);
    LOG_VAR(ll) << " metric to position map: ";
    for(auto &kv : _metricToPosition){
    	LOG_VAR(ll) << "Metric = " << kv.first << "Position = " << kv.second;
    }
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}

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void SMUCNGPerfOperator::compute(U_Ptr unit) {
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	auto inputs = unit->getInputs();
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	auto timestamp = getTimestamp() - 10e9 ; //ToDo timestamp minus some time...
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	for(auto& outSensor : unit->getOutputs()){
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		if( outSensor->getMetric() == SMUCSensorBase::CPI) {
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			computeCPI(inputs, outSensor, timestamp);
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		} else if (outSensor->getMetric() == SMUCSensorBase::FREQUENCY) {
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			computeFREQUENCY(inputs, outSensor, timestamp);
		} else if (outSensor->getMetric() == SMUCSensorBase::FLOPS || outSensor->getMetric() == SMUCSensorBase::PACKED_FLOPS ||
				outSensor->getMetric() == SMUCSensorBase::AVX512_TOVECTORIZED_RATIO || outSensor->getMetric() == SMUCSensorBase::VECTORIZED_RATIO ||
				outSensor->getMetric() == SMUCSensorBase::SINGLE_PRECISION_TO_TOTAL_RATIO) {
			computeFLOPS(inputs, outSensor, timestamp);
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		}
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		resetBuffers();
	}
}

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void SMUCNGPerfOperator::query(const std::string & sensor_name, const uint64_t timestamp, vector<reading_t> &buffer){
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	_queryEngine.querySensor(sensor_name, timestamp, timestamp, buffer, false); //use absolute timestamp and always false
}

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void SMUCNGPerfOperator::resetBuffers(){
	for(auto &buffer: _buffers){
		buffer.clear();
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	}
}
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void SMUCNGPerfOperator::computeCPI(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr &outSensor, const uint64_t timestamp){
	std::vector<reading_t> & instructions = _buffers[0];
	std::vector<reading_t> & clocks = _buffers[1];
	query(inputs[_metricToPosition[SMUCSensorBase::INSTRUCTIONS]]->getName(), timestamp, instructions);
	query(inputs[_metricToPosition[SMUCSensorBase::CLOCKS]]->getName(), timestamp, clocks);
	bool wascalced = false;
	reading_t cpi;
	if (instructions.size() > 0 && clocks.size() > 0 && calculateMetricRatio(clocks[0], instructions[0], outSensor->getScalingFactor(), cpi)) {
		outSensor->storeReading(cpi);
	}
}

void SMUCNGPerfOperator::computeFREQUENCY(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor, const uint64_t timestamp) {
	std::vector<reading_t> & clocks = _buffers[0];
	std::vector<reading_t> & clocks_ref = _buffers[1];
	query(inputs[_metricToPosition[SMUCSensorBase::CLOCKS]]->getName(), timestamp, clocks);
	query(inputs[_metricToPosition[SMUCSensorBase::CLOCKS_REF]]->getName(), timestamp, clocks_ref);
	reading_t frequency;
	if( clocks.size() > 0 && clocks_ref.size() > 0 && calculateFrequency(clocks_ref[0],clocks[0], MIN_FREQ_MHZ, MAX_FREQ_MHZ, frequency)) {
		outSensor->storeReading(frequency);
	}
}

void SMUCNGPerfOperator::computeFLOPS(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor, const uint64_t timestamp) {
	SMUCSensorBase::Metric_t flop_metric = outSensor->getMetric();
	std::vector<reading_t> & fp_arith_scalar_double = _buffers[0];
	std::vector<reading_t> & fp_arith_scalar_single = _buffers[1];
	std::vector<reading_t> & fp_arith_128b_packed_double = _buffers[2];
	std::vector<reading_t> & fp_arith_128b_packed_single = _buffers[3];
	std::vector<reading_t> & fp_arith_256b_packed_double = _buffers[4];
	std::vector<reading_t> & fp_arith_256b_packed_single = _buffers[5];
	std::vector<reading_t> & fp_arith_512b_packed_double = _buffers[6];
	std::vector<reading_t> & fp_arith_512b_packed_single = _buffers[7];


	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_SCALAR_DOUBLE]]->getName(), timestamp, fp_arith_scalar_double);
	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_SCALAR_SINGLE]]->getName(), timestamp, fp_arith_scalar_single);
	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_128B_PACKED_DOUBLE]]->getName(), timestamp, fp_arith_128b_packed_double);
	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_128B_PACKED_SINGLE]]->getName(), timestamp, fp_arith_128b_packed_single);
	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_256B_PACKED_DOUBLE]]->getName(), timestamp, fp_arith_256b_packed_double);
	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_256B_PACKED_SINGLE]]->getName(), timestamp, fp_arith_256b_packed_single);
	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_512B_PACKED_DOUBLE]]->getName(), timestamp, fp_arith_512b_packed_double);
	query(inputs[_metricToPosition[SMUCSensorBase::FP_ARITH_512B_PACKED_SINGLE]]->getName(), timestamp, fp_arith_512b_packed_single);
	reading_t empty;
	empty.value = 0;
	empty.timestamp = 0;
	reading_t & scalar_double = fp_arith_scalar_double.size() > 0 ? fp_arith_scalar_double[0]: empty;
	reading_t & scalar_single = fp_arith_scalar_single.size() > 0 ? fp_arith_scalar_single[0]: empty;
	reading_t & packed128_double = fp_arith_128b_packed_double.size() > 0 ? fp_arith_128b_packed_double[0] : empty;
	reading_t & packed128_single = fp_arith_128b_packed_single.size() > 0 ? fp_arith_128b_packed_single[0] : empty;
	reading_t & packed256_double =  fp_arith_256b_packed_double.size() > 0 ?  fp_arith_256b_packed_double[0] : empty;
	reading_t & packed256_single = fp_arith_256b_packed_single.size() > 0 ? fp_arith_256b_packed_single[0] : empty;
	reading_t & packed512_double =  fp_arith_512b_packed_double.size() > 0 ?  fp_arith_512b_packed_double[0] :empty;
	reading_t & packed512_single = fp_arith_512b_packed_single.size() > 0 ? fp_arith_512b_packed_single[0] : empty;

	reading_t result;
	if(flop_metric == SMUCSensorBase::FLOPS) {
		if (calculateFlops(scalar_double, scalar_single, packed128_double,
				packed128_single, packed256_double, packed256_single,
				packed512_double, packed512_single, result) ) {
			outSensor->storeReading(result);
		}
	} else if(flop_metric == SMUCSensorBase::PACKED_FLOPS){
		if(calculatePackedFlops(packed128_double,packed128_single,packed256_double,packed256_single,packed512_double,packed512_single, result)){
			outSensor->storeReading(result);
		}
	} else if(flop_metric == SMUCSensorBase::VECTORIZED_RATIO) {
		if(calculateVectorizationRatio(scalar_double, scalar_single, packed128_double,
				packed128_single, packed256_double, packed256_single,
				packed512_double, packed512_single, result)) {
			outSensor->storeReading(result);
		}
	} else if (flop_metric == SMUCSensorBase::AVX512_TOVECTORIZED_RATIO) {
		if (calculateAVX512FlopsToVectorizedRatio(packed128_double,
				packed128_single, packed256_double, packed256_single,
				packed512_double, packed512_single, result)) {
			outSensor->storeReading(result);
		}
	} else if (flop_metric == SMUCSensorBase::SINGLE_PRECISION_TO_TOTAL_RATIO) {
		if(calculateSP_TO_TOTAL_RATIO(scalar_double, scalar_single, packed128_double,
				packed128_single, packed256_double, packed256_single,
				packed512_double, packed512_single, result)){
			outSensor->storeReading(result);

		}
	}
}



/*void SMUCNGPerfOperator::computeINSTR_INTRA_NODE_LOADIMBALANCE(std::vector<SMUCNGPtr>& inputs,
		SMUCNGPtr& outSensor, const uint64_t timestamp) {
}*/

void SMUCNGPerfOperator::computeL3_TO_INSTRUCTIONS_RATIO(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor,
		const uint64_t timestamp) {
}

void SMUCNGPerfOperator::computeL3_BANDWIDTH(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor,
		const uint64_t timestamp) {
}

void SMUCNGPerfOperator::computeL3HIT_TO_L3MISS_RATIO(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor,
		const uint64_t timestamp) {
}

void SMUCNGPerfOperator::computeLOADS_TO_STORES(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor,
		const uint64_t timestamp) {
}

void SMUCNGPerfOperator::computeLOADS_TOL3MISS_RATIO(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor,
		const uint64_t timestamp) {
}

void SMUCNGPerfOperator::computeBRANCH_PER_INSTRUCTIONS(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor) {
}

void SMUCNGPerfOperator::computeMISSBRANCHES_TO_TOTAL_BRANCH_RATIO(std::vector<SMUCNGPtr>& inputs,
		SMUCNGPtr& outSensor, const uint64_t timestamp) {
}

void SMUCNGPerfOperator::computeMEMORY_BANDWIDTH(std::vector<SMUCNGPtr>& inputs, SMUCNGPtr& outSensor,
		const uint64_t timestamp) {
}