src/gpu/text/GrDistanceFieldAdjustTable.cpp - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/text/GrDistanceFieldAdjustTable.h"

 #include "src/core/SkScalerContext.h"

 SkDEBUGCODE(static const int kExpectedDistanceAdjustTableSize = 8;)

 SkScalar* build_distance_adjust_table(SkScalar paintGamma, SkScalar deviceGamma) {
     // This is used for an approximation of the mask gamma hack, used by raster and bitmap
     // text. The mask gamma hack is based off of guessing what the blend color is going to
     // be, and adjusting the mask so that when run through the linear blend will
     // produce the value closest to the desired result. However, in practice this means
     // that the 'adjusted' mask is just increasing or decreasing the coverage of
     // the mask depending on what it is thought it will blit against. For black (on
     // assumed white) this means that coverages are decreased (on a curve). For white (on
     // assumed black) this means that coverages are increased (on a a curve). At
     // middle (perceptual) gray (which could be blit against anything) the coverages
     // remain the same.
     //
     // The idea here is that instead of determining the initial (real) coverage and
     // then adjusting that coverage, we determine an adjusted coverage directly by
     // essentially manipulating the geometry (in this case, the distance to the glyph
     // edge). So for black (on assumed white) this thins a bit; for white (on
     // assumed black) this fake bolds the geometry a bit.
     //
     // The distance adjustment is calculated by determining the actual coverage value which
     // when fed into in the mask gamma table gives us an 'adjusted coverage' value of 0.5. This
     // actual coverage value (assuming it's between 0 and 1) corresponds to a distance from the
     // actual edge. So by subtracting this distance adjustment and computing without the
     // the coverage adjustment we should get 0.5 coverage at the same point.
     //
     // This has several implications:
     //     For non-gray lcd smoothed text, each subpixel essentially is using a
     //     slightly different geometry.
     //
     //     For black (on assumed white) this may not cover some pixels which were
     //     previously covered; however those pixels would have been only slightly
     //     covered and that slight coverage would have been decreased anyway. Also, some pixels
     //     which were previously fully covered may no longer be fully covered.
     //
     //     For white (on assumed black) this may cover some pixels which weren't
     //     previously covered at all.

     int width, height;
     size_t size;

 #ifdef SK_GAMMA_CONTRAST
     SkScalar contrast = SK_GAMMA_CONTRAST;
 #else
     SkScalar contrast = 0.5f;
 #endif

     size = SkScalerContext::GetGammaLUTSize(contrast, paintGamma, deviceGamma,
         &width, &height);

     SkASSERT(kExpectedDistanceAdjustTableSize == height);
     SkScalar* table = new SkScalar[height];

     SkAutoTArray<uint8_t> data((int)size);
     if (!SkScalerContext::GetGammaLUTData(contrast, paintGamma, deviceGamma, data.get())) {
         // if no valid data is available simply do no adjustment
         for (int row = 0; row < height; ++row) {
             table[row] = 0;
         }
         return table;
     }

     // find the inverse points where we cross 0.5
     // binsearch might be better, but we only need to do this once on creation
     for (int row = 0; row < height; ++row) {
         uint8_t* rowPtr = data.get() + row*width;
         for (int col = 0; col < width - 1; ++col) {
             if (rowPtr[col] <= 127 && rowPtr[col + 1] >= 128) {
                 // compute point where a mask value will give us a result of 0.5
                 float interp = (127.5f - rowPtr[col]) / (rowPtr[col + 1] - rowPtr[col]);
                 float borderAlpha = (col + interp) / 255.f;

                 // compute t value for that alpha
                 // this is an approximate inverse for smoothstep()
                 float t = borderAlpha*(borderAlpha*(4.0f*borderAlpha - 6.0f) + 5.0f) / 3.0f;

                 // compute distance which gives us that t value
                 const float kDistanceFieldAAFactor = 0.65f; // should match SK_DistanceFieldAAFactor
                 float d = 2.0f*kDistanceFieldAAFactor*t - kDistanceFieldAAFactor;

                 table[row] = d;
                 break;
             }
         }
     }

     return table;
 }

 const GrDistanceFieldAdjustTable* GrDistanceFieldAdjustTable::Get() {
     static const GrDistanceFieldAdjustTable* dfat = new GrDistanceFieldAdjustTable;
     return dfat;
 }

 GrDistanceFieldAdjustTable::GrDistanceFieldAdjustTable() {
     fTable = build_distance_adjust_table(SK_GAMMA_EXPONENT, SK_GAMMA_EXPONENT);
     fGammaCorrectTable = build_distance_adjust_table(SK_Scalar1, SK_Scalar1);
 }
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/text/GrDistanceFieldAdjustTable.h"

	#include "src/core/SkScalerContext.h"

	SkDEBUGCODE(static const int kExpectedDistanceAdjustTableSize = 8;)

	SkScalar* build_distance_adjust_table(SkScalar paintGamma, SkScalar deviceGamma) {
	// This is used for an approximation of the mask gamma hack, used by raster and bitmap
	// text. The mask gamma hack is based off of guessing what the blend color is going to
	// be, and adjusting the mask so that when run through the linear blend will
	// produce the value closest to the desired result. However, in practice this means
	// that the 'adjusted' mask is just increasing or decreasing the coverage of
	// the mask depending on what it is thought it will blit against. For black (on
	// assumed white) this means that coverages are decreased (on a curve). For white (on
	// assumed black) this means that coverages are increased (on a a curve). At
	// middle (perceptual) gray (which could be blit against anything) the coverages
	// remain the same.
	//
	// The idea here is that instead of determining the initial (real) coverage and
	// then adjusting that coverage, we determine an adjusted coverage directly by
	// essentially manipulating the geometry (in this case, the distance to the glyph
	// edge). So for black (on assumed white) this thins a bit; for white (on
	// assumed black) this fake bolds the geometry a bit.
	//
	// The distance adjustment is calculated by determining the actual coverage value which
	// when fed into in the mask gamma table gives us an 'adjusted coverage' value of 0.5. This
	// actual coverage value (assuming it's between 0 and 1) corresponds to a distance from the
	// actual edge. So by subtracting this distance adjustment and computing without the
	// the coverage adjustment we should get 0.5 coverage at the same point.
	//
	// This has several implications:
	// For non-gray lcd smoothed text, each subpixel essentially is using a
	// slightly different geometry.
	//
	// For black (on assumed white) this may not cover some pixels which were
	// previously covered; however those pixels would have been only slightly
	// covered and that slight coverage would have been decreased anyway. Also, some pixels
	// which were previously fully covered may no longer be fully covered.
	//
	// For white (on assumed black) this may cover some pixels which weren't
	// previously covered at all.

	int width, height;
	size_t size;

	#ifdef SK_GAMMA_CONTRAST
	SkScalar contrast = SK_GAMMA_CONTRAST;
	#else
	SkScalar contrast = 0.5f;
	#endif

	size = SkScalerContext::GetGammaLUTSize(contrast, paintGamma, deviceGamma,
	&width, &height);

	SkASSERT(kExpectedDistanceAdjustTableSize == height);
	SkScalar* table = new SkScalar[height];

	SkAutoTArray<uint8_t> data((int)size);
	if (!SkScalerContext::GetGammaLUTData(contrast, paintGamma, deviceGamma, data.get())) {
	// if no valid data is available simply do no adjustment
	for (int row = 0; row < height; ++row) {
	table[row] = 0;
	}
	return table;
	}

	// find the inverse points where we cross 0.5
	// binsearch might be better, but we only need to do this once on creation
	for (int row = 0; row < height; ++row) {
	uint8_t* rowPtr = data.get() + row*width;
	for (int col = 0; col < width - 1; ++col) {
	if (rowPtr[col] <= 127 && rowPtr[col + 1] >= 128) {
	// compute point where a mask value will give us a result of 0.5
	float interp = (127.5f - rowPtr[col]) / (rowPtr[col + 1] - rowPtr[col]);
	float borderAlpha = (col + interp) / 255.f;

	// compute t value for that alpha
	// this is an approximate inverse for smoothstep()
	float t = borderAlpha(borderAlpha(4.0f*borderAlpha - 6.0f) + 5.0f) / 3.0f;

	// compute distance which gives us that t value
	const float kDistanceFieldAAFactor = 0.65f; // should match SK_DistanceFieldAAFactor
	float d = 2.0fkDistanceFieldAAFactort - kDistanceFieldAAFactor;

	table[row] = d;
	break;
	}
	}
	}

	return table;
	}

	const GrDistanceFieldAdjustTable* GrDistanceFieldAdjustTable::Get() {
	static const GrDistanceFieldAdjustTable* dfat = new GrDistanceFieldAdjustTable;
	return dfat;
	}

	GrDistanceFieldAdjustTable::GrDistanceFieldAdjustTable() {
	fTable = build_distance_adjust_table(SK_GAMMA_EXPONENT, SK_GAMMA_EXPONENT);
	fGammaCorrectTable = build_distance_adjust_table(SK_Scalar1, SK_Scalar1);
	}