src/utils/SkBlitterTraceCommon.h - skia - Git at Google

 /*
  * Copyright 2022 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  *
  * This is an experimental (and probably temporary) solution that allows
  * to compare performance SkVM blitters vs RasterPipeline blitters.
  * In addition to measuring performance (which is questionable) it also produces
  * other counts (pixels, scanlines) and more detailed traces that
  * can explain the current results (SkVM is slower) and help improve it.
  * The entire code is hidden under build flag skia_compare_vm_vs_rp=true
  * and will not appear at all without it.
  */

 #ifndef SkBlitterTraceCommon_DEFINED
 #define SkBlitterTraceCommon_DEFINED

 #include <inttypes.h>
 #include <unordered_map>

 #define SK_BLITTER_TRACE_NO_CODE do {} while (0)

 #ifdef SKIA_COMPARE_VM_VS_RP

 #include "src/utils/SkCycles.h"

 class SkBlitterTrace {
 /*
  * This class collects information for RasterPipeLine vs SkVM
  * performance comparison.
  * How to get the comparison table:
  * 1. Add to your Release/args.gn an argument: skia_compare_vm_vs_rp=true
  *    Build nanobench.
  * 2. Run nanobench for SkVM:
  *    []/Release/nanobench
  *    --csv --config 8888 --skvm --loops 100 --samples 1
  *    --match $(ls skps | grep --invert-match svg ) 2>&1 | tee VM.data
  * 3. Run nanobench for RasterPipeLine:
  *    []/Release/nanobench
  *    --csv --config 8888 --forceRasterPipeline --loops 100
  *    --samples 1 --match $(ls skps | grep --invert-match svg )
  *    2>&1 | tee RP.data
  * 4. Extract the information side-by-side:
  *    awk 'BEGIN {OFS=","; fileNum = 0} ($2 ~ /MB/) && fileNum == 0
  *    {vmvmcycles[$3] = $6; vmvmscan[$3] = $8; vmvmpixels[$3] = $10;
  *    vmvminterp[$3] = $11;  vmrpcycle[$3] = $14; vmrpscan[$3] = $16;
  *    vmrppixels[$3] = $18} ($2 ~ /MB/) && fileNum == 1  {print $3,
  *    vmvmcycles[$3], vmvmscan[$3], vmvmpixels[$3], vmvminterp[$3], $6, $8,
  *    $10, $11, $14, $16, $18} ENDFILE {fileNum += 1}'
  *    VM.data RP.data > compare.csv
  * 5. Open the compare.csv table in Google Spreadsheets.
  *     You will get columns [A:P]. Add 4 more columns with formulas:
  *     Q: =B/M-1
  *     R: =N-C
  *     S: =O-D
  *     T: =2*(S<>0)+(R<>0)
  *     To be honest R, S, T columns are here for checking only (they all
  *     supposed to have zero values in them)
  *     Column Q shows the actual performance difference. Negative value means
  *     that wins SkVM, positive - RasterPipeLine.
  */
 public:
     SkBlitterTrace(const char* header, bool traceSteps = false)
         : fHeader(header), fTraceSteps(traceSteps) { }

     SkBlitterTrace& operator= (const SkBlitterTrace&) = default;

     void addTrace(const char* name, uint64_t cycles, uint64_t scanLines, uint64_t pixels) {
         fCycles += cycles;
         fScanlines += scanLines;
         fPixels += pixels;
         if (fTraceSteps) {
             printIncrements(name, cycles, scanLines, pixels);
         }
     }

     void reset() {
         fCycles = 0ul;
         fScanlines = 0ul;
         fPixels = 0ul;
     }

     void printIncrements(const char* name,
                          uint64_t cycles,
                          uint64_t scanLines,
                          uint64_t pixels) const {
         SkDebugf("%s %s: cycles=%" PRIu64 "+%" PRIu64
                        " scanlines=%" PRIu64 "+%" PRIu64 " pixels=%" PRIu64,
                  fHeader, name,
                  fCycles - cycles, cycles,
                  fScanlines - scanLines, scanLines,
                  fPixels);
         SkDebugf("\n");
     }

     void printCounts(const char* name) const {
         SkDebugf("%s cycles: %" PRIu64 " "
                  "   scanlines: %" PRIu64 " pixels: %" PRIu64,
                  fHeader,
                  fCycles,
                  fScanlines,
                  fPixels);
         SkDebugf(" ");
     }

     uint64_t getCycles() const { return fCycles; }
     uint64_t getScanlines() const { return fScanlines; }
     uint64_t getPixels() const { return fPixels; }

     class Step {
     public:
         Step(SkBlitterTrace* trace,
              const char* name,
              uint64_t scanlines,
              uint64_t pixels)
             : fTrace(trace)
             , fName(name)
             , fScanlines(scanlines)
             , fPixels(pixels) {
             fStartTime = SkCycles::Now();
         }
         void add(uint64_t scanlines, uint64_t pixels) {
             fScanlines += scanlines;
             fPixels += pixels;
         }
         ~Step() {
             if (fTrace == nullptr) {
                 return;
             }
             auto endTime = SkCycles::Now() - fStartTime;
             fTrace->addTrace(/*name=*/fName,
                              /*cycles=*/endTime,
                              /*scanlines=*/fScanlines,
                              /*pixels=*/fPixels);
         }
     private:
         SkBlitterTrace* fTrace = nullptr;
         const char* fName = "";
         uint64_t fStartTime = 0ul;
         uint64_t fScanlines = 0ul;
         uint64_t fPixels = 0ul;
     };

 private:
     const char* fHeader = "";
     bool fTraceSteps = false;
     uint64_t fCycles = 0ul;
     uint64_t fScanlines = 0ul;
     uint64_t fPixels = 0ul;
 };

 #define SK_BLITTER_TRACE_INIT \
 extern SkBlitterTrace gSkVMBlitterTrace;                        \
 extern SkBlitterTrace gSkRPBlitterTrace;                        \
                                                                 \
 static SkBlitterTrace gSkVMBlitterTraceCapture("VM", false);  \
 static SkBlitterTrace gSkRPBlitterTraceCapture("RP", false);

 #define SK_BLITTER_TRACE_LOCAL_SETUP \
     gSkVMBlitterTrace.reset(); \
     gSkRPBlitterTrace.reset()

 #define SK_BLITTER_TRACE_LOCAL_TEARDOWN \
     gSkVMBlitterTraceCapture = gSkVMBlitterTrace; \
     gSkRPBlitterTraceCapture = gSkRPBlitterTrace

 #define SK_BLITTER_TRACE_PRINT \
     gSkVMBlitterTraceCapture.printCounts("Total"); \
     SkDebugf("0 "); \
     gSkRPBlitterTraceCapture.printCounts("Total")

 #else
 #define SK_BLITTER_TRACE_INIT
 #define SK_BLITTER_TRACE_LOCAL_SETUP SK_BLITTER_TRACE_NO_CODE
 #define SK_BLITTER_TRACE_LOCAL_TEARDOWN SK_BLITTER_TRACE_NO_CODE
 #define SK_BLITTER_TRACE_PRINT SK_BLITTER_TRACE_NO_CODE
 #endif // SKIA_COMPARE_VM_VS_RP

 #endif // SkBlitterTraceCommon_DEFINED
	/*
	* Copyright 2022 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*
	* This is an experimental (and probably temporary) solution that allows
	* to compare performance SkVM blitters vs RasterPipeline blitters.
	* In addition to measuring performance (which is questionable) it also produces
	* other counts (pixels, scanlines) and more detailed traces that
	* can explain the current results (SkVM is slower) and help improve it.
	* The entire code is hidden under build flag skia_compare_vm_vs_rp=true
	* and will not appear at all without it.
	*/

	#ifndef SkBlitterTraceCommon_DEFINED
	#define SkBlitterTraceCommon_DEFINED

	#include <inttypes.h>
	#include <unordered_map>

	#define SK_BLITTER_TRACE_NO_CODE do {} while (0)

	#ifdef SKIA_COMPARE_VM_VS_RP

	#include "src/utils/SkCycles.h"

	class SkBlitterTrace {
	/*
	* This class collects information for RasterPipeLine vs SkVM
	* performance comparison.
	* How to get the comparison table:
	* 1. Add to your Release/args.gn an argument: skia_compare_vm_vs_rp=true
	* Build nanobench.
	* 2. Run nanobench for SkVM:
	* []/Release/nanobench
	* --csv --config 8888 --skvm --loops 100 --samples 1
	* --match $(ls skps \| grep --invert-match svg ) 2>&1 \| tee VM.data
	* 3. Run nanobench for RasterPipeLine:
	* []/Release/nanobench
	* --csv --config 8888 --forceRasterPipeline --loops 100
	* --samples 1 --match $(ls skps \| grep --invert-match svg )
	* 2>&1 \| tee RP.data
	* 4. Extract the information side-by-side:
	* awk 'BEGIN {OFS=","; fileNum = 0} ($2 ~ /MB/) && fileNum == 0
	* {vmvmcycles[$3] = $6; vmvmscan[$3] = $8; vmvmpixels[$3] = $10;
	* vmvminterp[$3] = $11; vmrpcycle[$3] = $14; vmrpscan[$3] = $16;
	* vmrppixels[$3] = $18} ($2 ~ /MB/) && fileNum == 1 {print $3,
	* vmvmcycles[$3], vmvmscan[$3], vmvmpixels[$3], vmvminterp[$3], $6, $8,
	* $10, $11, $14, $16, $18} ENDFILE {fileNum += 1}'
	* VM.data RP.data > compare.csv
	* 5. Open the compare.csv table in Google Spreadsheets.
	* You will get columns [A:P]. Add 4 more columns with formulas:
	* Q: =B/M-1
	* R: =N-C
	* S: =O-D
	* T: =2*(S<>0)+(R<>0)
	* To be honest R, S, T columns are here for checking only (they all
	* supposed to have zero values in them)
	* Column Q shows the actual performance difference. Negative value means
	* that wins SkVM, positive - RasterPipeLine.
	*/
	public:
	SkBlitterTrace(const char* header, bool traceSteps = false)
	: fHeader(header), fTraceSteps(traceSteps) { }

	SkBlitterTrace& operator= (const SkBlitterTrace&) = default;

	void addTrace(const char* name, uint64_t cycles, uint64_t scanLines, uint64_t pixels) {
	fCycles += cycles;
	fScanlines += scanLines;
	fPixels += pixels;
	if (fTraceSteps) {
	printIncrements(name, cycles, scanLines, pixels);
	}
	}

	void reset() {
	fCycles = 0ul;
	fScanlines = 0ul;
	fPixels = 0ul;
	}

	void printIncrements(const char* name,
	uint64_t cycles,
	uint64_t scanLines,
	uint64_t pixels) const {
	SkDebugf("%s %s: cycles=%" PRIu64 "+%" PRIu64
	" scanlines=%" PRIu64 "+%" PRIu64 " pixels=%" PRIu64,
	fHeader, name,
	fCycles - cycles, cycles,
	fScanlines - scanLines, scanLines,
	fPixels);
	SkDebugf("\n");
	}

	void printCounts(const char* name) const {
	SkDebugf("%s cycles: %" PRIu64 " "
	" scanlines: %" PRIu64 " pixels: %" PRIu64,
	fHeader,
	fCycles,
	fScanlines,
	fPixels);
	SkDebugf(" ");
	}

	uint64_t getCycles() const { return fCycles; }
	uint64_t getScanlines() const { return fScanlines; }
	uint64_t getPixels() const { return fPixels; }

	class Step {
	public:
	Step(SkBlitterTrace* trace,
	const char* name,
	uint64_t scanlines,
	uint64_t pixels)
	: fTrace(trace)
	, fName(name)
	, fScanlines(scanlines)
	, fPixels(pixels) {
	fStartTime = SkCycles::Now();
	}
	void add(uint64_t scanlines, uint64_t pixels) {
	fScanlines += scanlines;
	fPixels += pixels;
	}
	~Step() {
	if (fTrace == nullptr) {
	return;
	}
	auto endTime = SkCycles::Now() - fStartTime;
	fTrace->addTrace(/name=/fName,
	/cycles=/endTime,
	/scanlines=/fScanlines,
	/pixels=/fPixels);
	}
	private:
	SkBlitterTrace* fTrace = nullptr;
	const char* fName = "";
	uint64_t fStartTime = 0ul;
	uint64_t fScanlines = 0ul;
	uint64_t fPixels = 0ul;
	};

	private:
	const char* fHeader = "";
	bool fTraceSteps = false;
	uint64_t fCycles = 0ul;
	uint64_t fScanlines = 0ul;
	uint64_t fPixels = 0ul;
	};

	#define SK_BLITTER_TRACE_INIT \
	extern SkBlitterTrace gSkVMBlitterTrace; \
	extern SkBlitterTrace gSkRPBlitterTrace; \
	\
	static SkBlitterTrace gSkVMBlitterTraceCapture("VM", false); \
	static SkBlitterTrace gSkRPBlitterTraceCapture("RP", false);

	#define SK_BLITTER_TRACE_LOCAL_SETUP \
	gSkVMBlitterTrace.reset(); \
	gSkRPBlitterTrace.reset()

	#define SK_BLITTER_TRACE_LOCAL_TEARDOWN \
	gSkVMBlitterTraceCapture = gSkVMBlitterTrace; \
	gSkRPBlitterTraceCapture = gSkRPBlitterTrace

	#define SK_BLITTER_TRACE_PRINT \
	gSkVMBlitterTraceCapture.printCounts("Total"); \
	SkDebugf("0 "); \
	gSkRPBlitterTraceCapture.printCounts("Total")

	#else
	#define SK_BLITTER_TRACE_INIT
	#define SK_BLITTER_TRACE_LOCAL_SETUP SK_BLITTER_TRACE_NO_CODE
	#define SK_BLITTER_TRACE_LOCAL_TEARDOWN SK_BLITTER_TRACE_NO_CODE
	#define SK_BLITTER_TRACE_PRINT SK_BLITTER_TRACE_NO_CODE
	#endif // SKIA_COMPARE_VM_VS_RP

	#endif // SkBlitterTraceCommon_DEFINED