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author | Daniel Wilhelm <daniel@wili.li> | 2014-04-18 17:19:49 +0200 |
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committer | Daniel Wilhelm <daniel@wili.li> | 2014-04-18 17:19:49 +0200 |
commit | c8e0e909b4a8d18319fc65434a10dc446434817c (patch) | |
tree | eee91e7d2ce229dd043811eae8f1e2bd78061916 /lib/perf_check.cpp | |
parent | 5.2 (diff) | |
download | FreeFileSync-c8e0e909b4a8d18319fc65434a10dc446434817c.tar.gz FreeFileSync-c8e0e909b4a8d18319fc65434a10dc446434817c.tar.bz2 FreeFileSync-c8e0e909b4a8d18319fc65434a10dc446434817c.zip |
5.3
Diffstat (limited to 'lib/perf_check.cpp')
-rw-r--r-- | lib/perf_check.cpp | 259 |
1 files changed, 259 insertions, 0 deletions
diff --git a/lib/perf_check.cpp b/lib/perf_check.cpp new file mode 100644 index 00000000..897be12c --- /dev/null +++ b/lib/perf_check.cpp @@ -0,0 +1,259 @@ +// ************************************************************************** +// * This file is part of the FreeFileSync project. It is distributed under * +// * GNU General Public License: http://www.gnu.org/licenses/gpl.html * +// * Copyright (C) ZenJu (zhnmju123 AT gmx DOT de) - All Rights Reserved * +// ************************************************************************** + +#include "perf_check.h" + +#include <limits> +//#include <wx/ffile.h> +#include <zen/basic_math.h> +#include <zen/i18n.h> +#include <wx+/format_unit.h> + +using namespace zen; + + +PerfCheck::PerfCheck(unsigned windowSizeRemainingTime, + unsigned windowSizeBytesPerSecond) : + windowSizeRemTime(windowSizeRemainingTime), + windowSizeBPS(windowSizeBytesPerSecond), + windowMax(std::max(windowSizeRemainingTime, windowSizeBytesPerSecond)) {} + + +PerfCheck::~PerfCheck() +{ + /* + //write samples to a file + wxFFile outputFile(wxT("statistics.dat"), wxT("w")); + + outputFile.Write(wxT("Time(ms);Objects;Data\n")); + + for (auto iter = samples.begin(); iter != samples.end(); ++iter) + { + outputFile.Write(numberTo<wxString>(iter->first)); + outputFile.Write(wxT(";")); + outputFile.Write(numberTo<wxString>(iter->second.objCount_)); + outputFile.Write(wxT(";")); + outputFile.Write(numberTo<wxString>(iter->second.data_)); + outputFile.Write(wxT("\n")); + } + */ +} + + +void PerfCheck::addSample(int objectsCurrent, double dataCurrent, long timeMs) +{ + samples.insert(samples.end(), std::make_pair(timeMs, Record(objectsCurrent, dataCurrent))); //use fact that time is monotonously ascending + + //remove all records earlier than "now - windowMax" + const long newBegin = timeMs - windowMax; + auto iterWindowBegin = samples.upper_bound(newBegin); + if (iterWindowBegin != samples.begin()) + samples.erase(samples.begin(), --iterWindowBegin); //keep one point before newBegin in order to handle "measurement holes" +} + + +wxString PerfCheck::getRemainingTime(double dataRemaining) const +{ + if (!samples.empty()) + { + const auto& recordBack = *samples.rbegin(); + //find start of records "window" + auto iterFront = samples.upper_bound(recordBack.first - windowSizeRemTime); + if (iterFront != samples.begin()) + --iterFront; //one point before window begin in order to handle "measurement holes" + + const auto& recordFront = *iterFront; + //----------------------------------------------------------------------------------------------- + const double timeDelta = recordBack.first - recordFront.first; + const double dataDelta = recordBack.second.data_ - recordFront.second.data_; + + //objects do *NOT* correspond to disk accesses, so we better play safe and use "bytes" only! + //https://sourceforge.net/tracker/index.php?func=detail&aid=3452469&group_id=234430&atid=1093083 + + if (!numeric::isNull(dataDelta)) //sign(dataRemaining) != sign(dataDelta) usually an error, so show it! + { + int remTimeSec = dataRemaining * timeDelta / (1000.0 * dataDelta); + return zen::remainingTimeToShortString(remTimeSec); + } + } + return wxT("-"); //fallback +} + + +wxString PerfCheck::getBytesPerSecond() const +{ + if (!samples.empty()) + { + const auto& recordBack = *samples.rbegin(); + //find start of records "window" + auto iterFront = samples.upper_bound(recordBack.first - windowSizeBPS); + if (iterFront != samples.begin()) + --iterFront; //one point before window begin in order to handle "measurement holes" + + const auto& recordFront = *iterFront; + //----------------------------------------------------------------------------------------------- + const double timeDelta = recordBack.first - recordFront.first; + const double dataDelta = recordBack.second.data_ - recordFront.second.data_; + + if (!numeric::isNull(timeDelta)) + if (dataDelta > 0) //may be negative if user cancels copying + return zen::filesizeToShortString(zen::Int64(dataDelta * 1000 / timeDelta)) + _("/sec"); + } + return wxT("-"); //fallback +} + + +wxString PerfCheck::getOverallBytesPerSecond() const //for all samples +{ + if (!samples.empty()) + { + const auto& recordBack = *samples.rbegin(); + const auto& recordFront = *samples.begin(); + //----------------------------------------------------------------------------------------------- + const double timeDelta = recordBack.first - recordFront.first; + const double dataDelta = recordBack.second.data_ - recordFront.second.data_; + + if (!numeric::isNull(timeDelta)) + if (dataDelta > 0) //may be negative if user cancels copying + return zen::filesizeToShortString(zen::Int64(dataDelta * 1000 / timeDelta)) + _("/sec"); + } + return wxT("-"); //fallback +} + + +/* +class for calculation of remaining time: +---------------------------------------- +"filesize |-> time" is an affine linear function f(x) = z_1 + z_2 x + +For given n measurements, sizes x_0, ..., x_n and times f_0, ..., f_n, the function f (as a polynom of degree 1) can be lineary approximated by + +z_1 = (r - s * q / p) / ((n + 1) - s * s / p) +z_2 = (q - s * z_1) / p = (r - (n + 1) z_1) / s + +with +p := x_0^2 + ... + x_n^2 +q := f_0 x_0 + ... + f_n x_n +r := f_0 + ... + f_n +s := x_0 + ... + x_n + +=> the time to process N files with amount of data D is: N * z_1 + D * z_2 + +Problem: +-------- +Times f_0, ..., f_n can be very small so that precision of the PC clock is poor. +=> Times have to be accumulated to enhance precision: +Copying of m files with sizes x_i and times f_i (i = 1, ..., m) takes sum_i f(x_i) := m * z_1 + z_2 * sum x_i = sum f_i +With X defined as the accumulated sizes and F the accumulated times this gives: (in theory...) +m * z_1 + z_2 * X = F <=> +z_1 + z_2 * X / m = F / m + +=> we obtain a new (artificial) measurement with size X / m and time F / m to be used in the linear approximation above + + +Statistics::Statistics(const int totalObjectCount, const double totalDataAmount, const unsigned recordCount) : + objectsTotal(totalObjectCount), + dataTotal(totalDataAmount), + recordsMax(recordCount), + objectsLast(0), + dataLast(0), + timeLast(wxGetLocalTimeMillis()), + z1_current(0), + z2_current(0), + dummyRecordPresent(false) {} + + +wxString Statistics::getRemainingTime(const int objectsCurrent, const double dataCurrent) +{ + //add new measurement point + const int m = objectsCurrent - objectsLast; + if (m != 0) + { + objectsLast = objectsCurrent; + + const double X = dataCurrent - dataLast; + dataLast = dataCurrent; + + const zen::Int64 timeCurrent = wxGetLocalTimeMillis(); + const double F = (timeCurrent - timeLast).ToDouble(); + timeLast = timeCurrent; + + record newEntry; + newEntry.x_i = X / m; + newEntry.f_i = F / m; + + //remove dummy record + if (dummyRecordPresent) + { + measurements.pop_back(); + dummyRecordPresent = false; + } + + //insert new record + measurements.push_back(newEntry); + if (measurements.size() > recordsMax) + measurements.pop_front(); + } + else //dataCurrent increased without processing new objects: + { //modify last measurement until m != 0 + const double X = dataCurrent - dataLast; //do not set dataLast, timeLast variables here, but write dummy record instead + if (!isNull(X)) + { + const zen::Int64 timeCurrent = wxGetLocalTimeMillis(); + const double F = (timeCurrent - timeLast).ToDouble(); + + record modifyEntry; + modifyEntry.x_i = X; + modifyEntry.f_i = F; + + //insert dummy record + if (!dummyRecordPresent) + { + measurements.push_back(modifyEntry); + if (measurements.size() > recordsMax) + measurements.pop_front(); + dummyRecordPresent = true; + } + else //modify dummy record + measurements.back() = modifyEntry; + } + } + + //calculate remaining time based on stored measurement points + double p = 0; + double q = 0; + double r = 0; + double s = 0; + for (std::list<record>::const_iterator i = measurements.begin(); i != measurements.end(); ++i) + { + const double x_i = i->x_i; + const double f_i = i->f_i; + p += x_i * x_i; + q += f_i * x_i; + r += f_i; + s += x_i; + } + + if (!isNull(p)) + { + const double n = measurements.size(); + const double tmp = (n - s * s / p); + + if (!isNull(tmp) && !isNull(s)) + { + const double z1 = (r - s * q / p) / tmp; + const double z2 = (r - n * z1) / s; //not (n + 1) here, since n already is the number of measurements + + //refresh current values for z1, z2 + z1_current = z1; + z2_current = z2; + } + } + + return formatRemainingTime((objectsTotal - objectsCurrent) * z1_current + (dataTotal - dataCurrent) * z2_current); +} + +*/ |