Exemple #1
0
void TimerData::print()
{
    static ctime_t tmargin = CTime::getTicksPerSec() / 100000;
    std::ostream& out = std::cout;
    out << "==== " << id << " ====\n\n";
    if (!records.empty())
    {
        out << "Trace of last iteration :\n";
        ctime_t t0 = records[0].time;
        ctime_t last_t = 0;
        int level = 0;
        for (unsigned int ri = 1; ri < records.size(); ++ri)
        {
            const Record& r = records[ri];
            out << "  * ";
            if (ri > 0 && ri < records.size()-1 && r.time <= last_t + tmargin)
            {
                printNoVal(out);
                out << "   ";
            }
            else
            {
                printTime(out, r.time - t0);
                out << " ms";
                last_t = r.time;
            }
            out << " ";
            if (r.type == Record::REND || r.type == Record::RSTEP_END) --level;
            for (int l=0; l<level; ++l)
                out << "  ";
            switch(r.type)
            {
            case Record::RNONE:
                out << "NONE";
                break;
            case Record::RSTEP_BEGIN:
                out << "> begin " << AdvancedTimer::IdStep(r.id);
                if (r.obj)
                    out << " on " << AdvancedTimer::IdObj(r.obj);
                break;
            case Record::RSTEP_END:
                out << "< end   " << AdvancedTimer::IdStep(r.id);
                if (r.obj)
                    out << " on " << AdvancedTimer::IdObj(r.obj);
                break;
            case Record::RSTEP:
                out << "- step  " << AdvancedTimer::IdStep(r.id);
                if (r.obj)
                    out << " on " << AdvancedTimer::IdObj(r.obj);
                break;
            case Record::RVAL_SET:
                out << ": var   " << AdvancedTimer::IdVal(r.id);
                out << "  = " << r.val;
                break;
            case Record::RVAL_ADD:
                out << ": var   " << AdvancedTimer::IdVal(r.id);
                out << " += " << r.val;
                break;
            case Record::REND:
                out << "END";
                break;
            default:
                out << "UNKNOWN RECORD TYPE" << (int)r.type;
            }
            out << std::endl;
            if (r.type == Record::RBEGIN || r.type == Record::RSTEP_BEGIN) ++level;
        }
    }
    if (!steps.empty())
    {
        out << "\nSteps Duration Statistics (in ms) :\n";
        out << " LEVEL\t START\t  NUM\t   MIN\t   MAX\t MEAN\t  DEV\t TOTAL\tPERCENT\tID\n";
        ctime_t ttotal = stepData[AdvancedTimer::IdStep()].ttotal;
        for (unsigned int s=0; s<steps.size(); ++s)
        {
            StepData& data = stepData[steps[s]];
            printVal(out, data.level);
            out << '\t';
            printTime(out, data.tstart, data.numIt);
            out << '\t';
            printVal(out, data.num, (s == 0) ? 1 : nbIter);
            out << '\t';
            printTime(out, data.tmin);
            out << '\t';
            printTime(out, data.tmax);
            out << '\t';
            double mean = (double)data.ttotal / data.num;
            printTime(out, (ctime_t)mean);
            out << '\t';
            printTime(out, (ctime_t)(sqrt((double)data.ttotal2/data.num - mean*mean)));
            out << '\t';
            printTime(out, data.ttotal, (s == 0) ? 1 : nbIter);
            out << '\t';
            printVal(out, 100.0*data.ttotal / (double) ttotal);
            out << '\t';
            if (s == 0)
                out << "TOTAL";
            else
            {
                for(int ii=0; ii<data.level; ii++) out<<".";  // indentation to show the hierarchy level
                out << steps[s];
            }
            out << std::endl;
        }
    }
    if (!vals.empty())
    {
        out << "\nValues Statistics :\n";
        out << " NUM\t  MIN\t  MAX\t MEAN\t  DEV\t TOTAL\tID\n";
        for (unsigned int s=0; s<vals.size(); ++s)
        {
            ValData& data = valData[vals[s]];
            printVal(out, data.num, nbIter);
            out << '\t';
            printVal(out, data.vmin);
            out << '\t';
            printVal(out, data.vmax);
            out << '\t';
            double mean = data.vtotal / data.num;
            printVal(out, mean);
            out << '\t';
            printVal(out, sqrt(data.vtotal2/data.num - mean*mean) );
            out << '\t';
            printVal(out, data.vtotal, nbIter);
            out << '\t';
            out << vals[s];
            out << std::endl;
        }
    }
    out << "\n iteration : " << getCurRecords()->size();
    out << "\n==== END ====\n";
    out << std::endl;
}
Exemple #2
0
json TimerData::getLightJson(std::string stepNumber)
{
    json jsonOutput;
    std::vector<std::string> deepthTree;
    std::string jsonObjectName = stepNumber;
    std::string father;
    int componantLevel = 0;
    int subComponantLevel = 0;
    std::stringstream ComposantId;

    if (!steps.empty())
    {
        // Clean the streamString
        ComposantId.str("");
        componantLevel = 0;
        subComponantLevel = 0;

        // Create the JSON container
        jsonOutput[jsonObjectName];

        for (unsigned int s=0; s<steps.size(); s++)
        {
            // Clean the streamString
            ComposantId.str("");

            StepData& data = stepData[steps[s]];

            if (s == 0)
            {
                ComposantId << "TOTAL";
                deepthTree.push_back(ComposantId.str());
                subComponantLevel = 0;
                jsonOutput[jsonObjectName][ComposantId.str()]["Father"] = "None";
                jsonOutput[jsonObjectName][ComposantId.str()]["Values"] = createJSONArray(s, jsonOutput[jsonObjectName][ComposantId.str()]["Values"], data);
            }
            else
            {
                for(int ii=0; ii<data.level; ii++) ++subComponantLevel;  // indentation to show the hierarchy level

                // If the level increment
                if(componantLevel < subComponantLevel)
                {
                    father = deepthTree.at(deepthTree.size()-1);
                    ComposantId << steps[s];
                    deepthTree.push_back(ComposantId.str());
                    jsonOutput[jsonObjectName][ComposantId.str()]["Father"] = father;
                    jsonOutput[jsonObjectName][ComposantId.str()]["Values"] = createJSONArray(s, jsonOutput[jsonObjectName][ComposantId.str()]["Values"], data);;

                }
                // If the level decrement
                else if(componantLevel > subComponantLevel)
                {
                    deepthTree.pop_back();
                    father = deepthTree.at(deepthTree.size()-1);
                    ComposantId << steps[s];

                    jsonOutput[jsonObjectName][ComposantId.str()]["Father"] = father;
                    jsonOutput[jsonObjectName][ComposantId.str()]["Values"] = createJSONArray(s, jsonOutput[jsonObjectName][ComposantId.str()]["Values"], data);

                }

                // If the level stay the same
                else if (componantLevel == subComponantLevel)
                {
                    ComposantId << steps[s];

                    jsonOutput[jsonObjectName][ComposantId.str()]["Father"] = father;
                    jsonOutput[jsonObjectName][ComposantId.str()]["Values"] = createJSONArray(s, jsonOutput[jsonObjectName][ComposantId.str()]["Values"], data);
                }

            }

            componantLevel = subComponantLevel;
            subComponantLevel = 0;


        }
    }

    return jsonOutput;
}
Exemple #3
0
void TimerData::process()
{
    if (records.empty()) return;
    ++nbIter;
    if (nbIter == 0) return; // do not keep stats on very first iteration

    ctime_t t0 = records[0].time;
    //ctime_t last_t = 0;
    int level = 0;
    for (unsigned int ri = 0; ri < records.size(); ++ri)
    {
        const Record& r = records[ri];
        ctime_t t = r.time - t0;
        //last_t = r.time;
        if (r.type == Record::REND || r.type == Record::RSTEP_END) --level;
        switch (r.type)
        {
        case Record::RNONE:
            break;
        case Record::RBEGIN:
        case Record::RSTEP_BEGIN:
        case Record::RSTEP:
        {
            AdvancedTimer::IdStep id;
            if (r.type != Record::RBEGIN) id = AdvancedTimer::IdStep(r.id);
            if (stepData.find(id) == stepData.end())
                steps.push_back(id);
            StepData& data = stepData[id];
            data.level = level;
            if (data.lastIt != nbIter)
            {
                data.lastIt = nbIter;
                data.tstart += t;
                ++data.numIt;
            }
            data.lastTime = t;
            ++data.num;
            break;
        }
        case Record::REND:
        case Record::RSTEP_END:
        {
            AdvancedTimer::IdStep id;
            if (r.type != Record::REND) id = AdvancedTimer::IdStep(r.id);
            StepData& data = stepData[id];
            if (data.lastIt == nbIter)
            {
                ctime_t dur = t - data.lastTime;
                data.ttotal += dur;
                data.ttotal2 += dur*dur;
                if (data.num == 1 || dur > data.tmax) data.tmax = dur;
                if (data.num == 1 || dur < data.tmin) data.tmin = dur;
            }
            break;
        }
        case Record::RVAL_SET:
        case Record::RVAL_ADD:
        {
            AdvancedTimer::IdVal id = AdvancedTimer::IdVal(r.id);
            if (valData.find(id) == valData.end())
                vals.push_back(id);
            ValData& data = valData[id];
            if (r.type == Record::RVAL_SET || (data.lastIt != nbIter))
            {
                // update vmin and vmax
                if (data.num == 1 || data.vtotalIt < data.vmin) data.vmin = data.vtotalIt;
                if (data.num == 1 || data.vtotalIt > data.vmax) data.vmax = data.vtotalIt;
            }
            if (data.lastIt != nbIter)
            {
                data.lastIt = nbIter;
                data.vtotalIt = r.val;
                data.vtotal += r.val;
                data.vtotal2 += r.val*r.val;
                ++data.numIt;
                ++data.num;
            }
            else if (r.type == Record::RVAL_SET)
            {
                data.vtotalIt = r.val;
                data.vtotal += r.val;
                data.vtotal2 += r.val*r.val;
                ++data.num;
            }
            else
            {
                data.vtotalIt += r.val;
                data.vtotal += r.val;
                data.vtotal2 += r.val*r.val;
            }
            break;
        }
        }

        if (r.type == Record::RBEGIN || r.type == Record::RSTEP_BEGIN) ++level;
    }

    for (unsigned int vi=0; vi < vals.size(); ++vi)
    {
        AdvancedTimer::IdVal id = vals[vi];
        ValData& data = valData[id];
        if (data.num > 0)
        {
            // update vmin and vmax
            if (data.num == 1 || data.vtotalIt < data.vmin) data.vmin = data.vtotalIt;
            if (data.num == 1 || data.vtotalIt > data.vmax) data.vmax = data.vtotalIt;
        }
    }
}
Exemple #4
0
void TimerData::print(std::ostream& result)
{
    //static ctime_t tmargin = CTime::getTicksPerSec() / 100000;
    std::ostream& out = result;
    out << "Timer: " << id << "\n";
    if (!steps.empty())
    {
        //out << "\nSteps Duration Statistics (in ms) :\n";
        out << " LEVEL      START       NUM         MIN        MAX       MEAN       DEV        TOTAL     PERCENT     ID\n";
        ctime_t ttotal = stepData[AdvancedTimer::IdStep()].ttotal;
        for (unsigned int s=0; s<steps.size(); ++s)
        {
            StepData& data = stepData[steps[s]];
            printVal(out, data.level);
            out << "    ";
            printTime(out, data.tstart, data.numIt);
            out << "    ";
            printVal(out, data.num, (s == 0) ? 1 : nbIter);
            out << "    ";
            printTime(out, data.tmin);
            out << "    ";
            printTime(out, data.tmax);
            out << "    ";
            double mean = (double)data.ttotal / data.num;
            printTime(out, (ctime_t)mean);
            out << "    ";
            printTime(out, (ctime_t)(sqrt((double)data.ttotal2/data.num - mean*mean)));
            out << "    ";
            printTime(out, data.ttotal, (s == 0) ? 1 : nbIter);
            out << "    ";
            printVal(out, 100.0*data.ttotal / (double) ttotal);
            out << "    ";
            if (s == 0)
                out << "TOTAL";
            else
            {
                for(int ii=0; ii<data.level; ii++) out<<".";  // indentation to show the hierarchy level
                out << steps[s];
            }
            out << std::endl;
        }
    }
    if (!vals.empty())
    {
        out << "\nValues Statistics :\n";
        out << " NUM\t  MIN\t  MAX\t MEAN\t  DEV\t TOTAL\tID\n";
        for (unsigned int s=0; s<vals.size(); ++s)
        {
            ValData& data = valData[vals[s]];
            printVal(out, data.num, nbIter);
            out << '\t';
            printVal(out, data.vmin);
            out << '\t';
            printVal(out, data.vmax);
            out << '\t';
            double mean = data.vtotal / data.num;
            printVal(out, mean);
            out << '\t';
            printVal(out, sqrt(data.vtotal2/data.num - mean*mean) );
            out << '\t';
            printVal(out, data.vtotal, nbIter);
            out << '\t';
            out << vals[s];
            out << std::endl;
        }
    }

    //out << "\n==== END ====\n";
    out << std::endl;
}