cmds/screenrecord/TextRenderer.cpp - LeafOS-Project/android_frameworks_av - Gitiles

 /*
  * Copyright 2013 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #define LOG_TAG "ScreenRecord"
 //#define LOG_NDEBUG 0
 #include <utils/Log.h>

 #include "TextRenderer.h"

 #include <assert.h>
 #include <malloc.h>
 #include <string.h>

 namespace android {
 #include "FontBitmap.h"
 };

 using namespace android;

 const char TextRenderer::kWhitespace[] = " \t\n\r";

 bool TextRenderer::mInitialized = false;
 uint32_t TextRenderer::mXOffset[FontBitmap::numGlyphs];

 void TextRenderer::initOnce() {
     if (!mInitialized) {
         initXOffset();
         mInitialized = true;
     }
 }

 void TextRenderer::initXOffset() {
     // Generate a table of X offsets.  They start at zero and reset whenever
     // we move down a line (i.e. the Y offset changes).  The offset increases
     // by one pixel more than the width because the generator left a gap to
     // avoid reading pixels from adjacent glyphs in the texture filter.
     uint16_t offset = 0;
     uint16_t prevYOffset = (int16_t) -1;
     for (unsigned int i = 0; i < FontBitmap::numGlyphs; i++) {
         if (prevYOffset != FontBitmap::yoffset[i]) {
             prevYOffset = FontBitmap::yoffset[i];
             offset = 0;
         }
         mXOffset[i] = offset;
         offset += FontBitmap::glyphWidth[i] + 1;
     }
 }

 static bool isPowerOfTwo(uint32_t val) {
     // a/k/a "is exactly one bit set"; note returns true for 0
     return (val & (val -1)) == 0;
 }

 static uint32_t powerOfTwoCeil(uint32_t val) {
     // drop it, smear the bits across, pop it
     val--;
     val |= val >> 1;
     val |= val >> 2;
     val |= val >> 4;
     val |= val >> 8;
     val |= val >> 16;
     val++;

     return val;
 }

 float TextRenderer::getGlyphHeight() const {
     return FontBitmap::maxGlyphHeight;
 }

 status_t TextRenderer::loadIntoTexture() {
     ALOGV("Font::loadIntoTexture");

     glGenTextures(1, &mTextureName);
     if (mTextureName == 0) {
         ALOGE("glGenTextures failed: %#x", glGetError());
         return UNKNOWN_ERROR;
     }
     glBindTexture(GL_TEXTURE_2D, mTextureName);
     glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
     glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);

     // The pixel data is stored as combined color+alpha, 8 bits per pixel.
     // It's guaranteed to be a power-of-two wide, but we cut off the height
     // where the data ends.  We want to expand it to a power-of-two bitmap
     // with ARGB data and hand that to glTexImage2D.

     if (!isPowerOfTwo(FontBitmap::width)) {
         ALOGE("npot glyph bitmap width %u", FontBitmap::width);
         return UNKNOWN_ERROR;
     }

     uint32_t potHeight = powerOfTwoCeil(FontBitmap::height);
     uint8_t* rgbaPixels = new uint8_t[FontBitmap::width * potHeight * 4];
     memset(rgbaPixels, 0, FontBitmap::width * potHeight * 4);
     uint8_t* pix = rgbaPixels;

     for (unsigned int i = 0; i < FontBitmap::width * FontBitmap::height; i++) {
         uint8_t alpha, color;
         if ((FontBitmap::pixels[i] & 1) == 0) {
             // black pixel with varying alpha
             color = 0x00;
             alpha = FontBitmap::pixels[i] & ~1;
         } else {
             // opaque grey pixel
             color = FontBitmap::pixels[i] & ~1;
             alpha = 0xff;
         }
         *pix++ = color;
         *pix++ = color;
         *pix++ = color;
         *pix++ = alpha;
     }

     glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, FontBitmap::width, potHeight, 0,
             GL_RGBA, GL_UNSIGNED_BYTE, rgbaPixels);
     delete[] rgbaPixels;
     GLint glErr = glGetError();
     if (glErr != 0) {
         ALOGE("glTexImage2D failed: %#x", glErr);
         return UNKNOWN_ERROR;
     }
     return NO_ERROR;
 }

 void TextRenderer::setProportionalScale(float linesPerScreen) {
     if (mScreenWidth == 0 || mScreenHeight == 0) {
         ALOGW("setFontScale: can't set scale for width=%d height=%d",
                 mScreenWidth, mScreenHeight);
         return;
     }
     float tallest = mScreenWidth > mScreenHeight ? mScreenWidth : mScreenHeight;
     setScale(tallest / (linesPerScreen * getGlyphHeight()));
 }

 float TextRenderer::computeScaledStringWidth(const String8& str8) const {
     // String8.length() isn't documented, but I'm assuming it will return
     // the number of characters rather than the number of bytes.  Since
     // we can only display ASCII we want to ignore anything else, so we
     // just convert to char* -- but String8 doesn't document what it does
     // with values outside 0-255.  So just convert to char* and use strlen()
     // to see what we get.
     const char* str = str8.c_str();
     return computeScaledStringWidth(str, strlen(str));
 }

 size_t TextRenderer::glyphIndex(char ch) const {
     size_t chi = ch - FontBitmap::firstGlyphChar;
     if (chi >= FontBitmap::numGlyphs) {
         chi = '?' - FontBitmap::firstGlyphChar;
     }
     assert(chi < FontBitmap::numGlyphs);
     return chi;
 }

 float TextRenderer::computeScaledStringWidth(const char* str,
         size_t len) const {
     float width = 0.0f;
     for (size_t i = 0; i < len; i++) {
         size_t chi = glyphIndex(str[i]);
         float glyphWidth = FontBitmap::glyphWidth[chi];
         width += (glyphWidth - 1 - FontBitmap::outlineWidth) * mScale;
     }

     return width;
 }

 void TextRenderer::drawString(const Program& program, const float* texMatrix,
         float x, float y, const String8& str8) const {
     ALOGV("drawString %.3f,%.3f '%s' (scale=%.3f)", x, y, str8.c_str(),mScale);
     initOnce();

     // We want to draw the entire string with a single GLES call.  We
     // generate two arrays, one with screen coordinates, one with texture
     // coordinates.  Need two triangles per character.
     const char* str = str8.c_str();
     size_t len = strlen(str);       // again, unsure about String8 handling

     const size_t quadCoords =
             2 /*triangles*/ * 3 /*vertex/tri*/ * 2 /*coord/vertex*/;
     float vertices[len * quadCoords];
     float texes[len * quadCoords];

     float fullTexWidth = FontBitmap::width;
     float fullTexHeight = powerOfTwoCeil(FontBitmap::height);
     for (size_t i = 0; i < len; i++) {
         size_t chi = glyphIndex(str[i]);
         float glyphWidth = FontBitmap::glyphWidth[chi];
         float glyphHeight = FontBitmap::maxGlyphHeight;

         float vertLeft = x;
         float vertRight = x + glyphWidth * mScale;
         float vertTop = y;
         float vertBottom = y + glyphHeight * mScale;

         // Lowest-numbered glyph is in top-left of bitmap, which puts it at
         // the bottom-left in texture coordinates.
         float texLeft = mXOffset[chi] / fullTexWidth;
         float texRight = (mXOffset[chi] + glyphWidth) / fullTexWidth;
         float texTop = FontBitmap::yoffset[chi] / fullTexHeight;
         float texBottom = (FontBitmap::yoffset[chi] + glyphHeight) /
                 fullTexHeight;

         size_t off = i * quadCoords;
         vertices[off +  0] = vertLeft;
         vertices[off +  1] = vertBottom;
         vertices[off +  2] = vertRight;
         vertices[off +  3] = vertBottom;
         vertices[off +  4] = vertLeft;
         vertices[off +  5] = vertTop;
         vertices[off +  6] = vertLeft;
         vertices[off +  7] = vertTop;
         vertices[off +  8] = vertRight;
         vertices[off +  9] = vertBottom;
         vertices[off + 10] = vertRight;
         vertices[off + 11] = vertTop;
         texes[off +  0] = texLeft;
         texes[off +  1] = texBottom;
         texes[off +  2] = texRight;
         texes[off +  3] = texBottom;
         texes[off +  4] = texLeft;
         texes[off +  5] = texTop;
         texes[off +  6] = texLeft;
         texes[off +  7] = texTop;
         texes[off +  8] = texRight;
         texes[off +  9] = texBottom;
         texes[off + 10] = texRight;
         texes[off + 11] = texTop;

         // We added 1-pixel padding in the texture, so we want to advance by
         // one less.  Also, each glyph is surrounded by a black outline, which
         // we want to merge.
         x += (glyphWidth - 1 - FontBitmap::outlineWidth) * mScale;
     }

     program.drawTriangles(mTextureName, texMatrix, vertices, texes,
             len * quadCoords / 2);
 }

 float TextRenderer::drawWrappedString(const Program& texRender,
         float xpos, float ypos, const String8& str) {
     ALOGV("drawWrappedString %.3f,%.3f '%s'", xpos, ypos, str.c_str());
     initOnce();

     if (mScreenWidth == 0 || mScreenHeight == 0) {
         ALOGW("drawWrappedString: can't wrap with width=%d height=%d",
                 mScreenWidth, mScreenHeight);
         return ypos;
     }

     const float indentWidth = mIndentMult * getScale();
     if (xpos < mBorderWidth) {
         xpos = mBorderWidth;
     }
     if (ypos < mBorderWidth) {
         ypos = mBorderWidth;
     }

     const size_t maxWidth = (mScreenWidth - mBorderWidth) - xpos;
     if (maxWidth < 1) {
         ALOGE("Unable to render text: xpos=%.3f border=%.3f width=%u",
                 xpos, mBorderWidth, mScreenWidth);
         return ypos;
     }
     float stringWidth = computeScaledStringWidth(str);
     if (stringWidth <= maxWidth) {
         // Trivial case.
         drawString(texRender, Program::kIdentity, xpos, ypos, str);
         ypos += getScaledGlyphHeight();
     } else {
         // We need to break the string into pieces, ideally at whitespace
         // boundaries.
         char* mangle = strdup(str.c_str());
         char* start = mangle;
         while (start != NULL) {
             float xposAdj = (start == mangle) ? xpos : xpos + indentWidth;
             char* brk = breakString(start,
                     (float) (mScreenWidth - mBorderWidth - xposAdj));
             if (brk == NULL) {
                 // draw full string
                 drawString(texRender, Program::kIdentity, xposAdj, ypos,
                         String8(start));
                 start = NULL;
             } else {
                 // draw partial string
                 char ch = *brk;
                 *brk = '\0';
                 drawString(texRender, Program::kIdentity, xposAdj, ypos,
                         String8(start));
                 *brk = ch;
                 start = brk;
                 if (strchr(kWhitespace, ch) != NULL) {
                     // if we broke on whitespace, skip past it
                     start++;
                 }
             }
             ypos += getScaledGlyphHeight();
         }
         free(mangle);
     }

     return ypos;
 }

 char* TextRenderer::breakString(const char* str, float maxWidth) const {
     // Ideally we'd do clever things like binary search.  Not bothering.
     ALOGV("breakString '%s' %.3f", str, maxWidth);

     size_t len = strlen(str);
     if (len == 0) {
         // Caller should detect this and not advance ypos.
         return NULL;
     }

     float stringWidth = computeScaledStringWidth(str, len);
     if (stringWidth <= maxWidth) {
         return NULL;        // trivial -- use full string
     }

     // Find the longest string that will fit.
     size_t goodPos = 0;
     for (size_t i = 0; i < len; i++) {
         stringWidth = computeScaledStringWidth(str, i);
         if (stringWidth < maxWidth) {
             goodPos = i;
         } else {
             break;  // too big
         }
     }
     if (goodPos == 0) {
         // space is too small to hold any glyph; output a single char
         ALOGW("Couldn't find a nonzero prefix that fit from '%s'", str);
         goodPos = 1;
     }

     // Scan back for whitespace.  If we can't find any we'll just have
     // an ugly mid-word break.
     for (size_t i = goodPos; i > 0; i--) {
         if (strchr(kWhitespace, str[i]) != NULL) {
             goodPos = i;
             break;
         }
     }

     ALOGV("goodPos=%zu for str='%s'", goodPos, str);
     return const_cast<char*>(str + goodPos);
 }
	/*
	* Copyright 2013 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#define LOG_TAG "ScreenRecord"
	//#define LOG_NDEBUG 0
	#include <utils/Log.h>

	#include "TextRenderer.h"

	#include <assert.h>
	#include <malloc.h>
	#include <string.h>

	namespace android {
	#include "FontBitmap.h"
	};

	using namespace android;

	const char TextRenderer::kWhitespace[] = " \t\n\r";

	bool TextRenderer::mInitialized = false;
	uint32_t TextRenderer::mXOffset[FontBitmap::numGlyphs];

	void TextRenderer::initOnce() {
	if (!mInitialized) {
	initXOffset();
	mInitialized = true;
	}
	}

	void TextRenderer::initXOffset() {
	// Generate a table of X offsets. They start at zero and reset whenever
	// we move down a line (i.e. the Y offset changes). The offset increases
	// by one pixel more than the width because the generator left a gap to
	// avoid reading pixels from adjacent glyphs in the texture filter.
	uint16_t offset = 0;
	uint16_t prevYOffset = (int16_t) -1;
	for (unsigned int i = 0; i < FontBitmap::numGlyphs; i++) {
	if (prevYOffset != FontBitmap::yoffset[i]) {
	prevYOffset = FontBitmap::yoffset[i];
	offset = 0;
	}
	mXOffset[i] = offset;
	offset += FontBitmap::glyphWidth[i] + 1;
	}
	}

	static bool isPowerOfTwo(uint32_t val) {
	// a/k/a "is exactly one bit set"; note returns true for 0
	return (val & (val -1)) == 0;
	}

	static uint32_t powerOfTwoCeil(uint32_t val) {
	// drop it, smear the bits across, pop it
	val--;
	val \|= val >> 1;
	val \|= val >> 2;
	val \|= val >> 4;
	val \|= val >> 8;
	val \|= val >> 16;
	val++;

	return val;
	}

	float TextRenderer::getGlyphHeight() const {
	return FontBitmap::maxGlyphHeight;
	}

	status_t TextRenderer::loadIntoTexture() {
	ALOGV("Font::loadIntoTexture");

	glGenTextures(1, &mTextureName);
	if (mTextureName == 0) {
	ALOGE("glGenTextures failed: %#x", glGetError());
	return UNKNOWN_ERROR;
	}
	glBindTexture(GL_TEXTURE_2D, mTextureName);
	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
	glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);

	// The pixel data is stored as combined color+alpha, 8 bits per pixel.
	// It's guaranteed to be a power-of-two wide, but we cut off the height
	// where the data ends. We want to expand it to a power-of-two bitmap
	// with ARGB data and hand that to glTexImage2D.

	if (!isPowerOfTwo(FontBitmap::width)) {
	ALOGE("npot glyph bitmap width %u", FontBitmap::width);
	return UNKNOWN_ERROR;
	}

	uint32_t potHeight = powerOfTwoCeil(FontBitmap::height);
	uint8_t* rgbaPixels = new uint8_t[FontBitmap::width * potHeight * 4];
	memset(rgbaPixels, 0, FontBitmap::width * potHeight * 4);
	uint8_t* pix = rgbaPixels;

	for (unsigned int i = 0; i < FontBitmap::width * FontBitmap::height; i++) {
	uint8_t alpha, color;
	if ((FontBitmap::pixels[i] & 1) == 0) {
	// black pixel with varying alpha
	color = 0x00;
	alpha = FontBitmap::pixels[i] & ~1;
	} else {
	// opaque grey pixel
	color = FontBitmap::pixels[i] & ~1;
	alpha = 0xff;
	}
	*pix++ = color;
	*pix++ = color;
	*pix++ = color;
	*pix++ = alpha;
	}

	glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, FontBitmap::width, potHeight, 0,
	GL_RGBA, GL_UNSIGNED_BYTE, rgbaPixels);
	delete[] rgbaPixels;
	GLint glErr = glGetError();
	if (glErr != 0) {
	ALOGE("glTexImage2D failed: %#x", glErr);
	return UNKNOWN_ERROR;
	}
	return NO_ERROR;
	}

	void TextRenderer::setProportionalScale(float linesPerScreen) {
	if (mScreenWidth == 0 \|\| mScreenHeight == 0) {
	ALOGW("setFontScale: can't set scale for width=%d height=%d",
	mScreenWidth, mScreenHeight);
	return;
	}
	float tallest = mScreenWidth > mScreenHeight ? mScreenWidth : mScreenHeight;
	setScale(tallest / (linesPerScreen * getGlyphHeight()));
	}

	float TextRenderer::computeScaledStringWidth(const String8& str8) const {
	// String8.length() isn't documented, but I'm assuming it will return
	// the number of characters rather than the number of bytes. Since
	// we can only display ASCII we want to ignore anything else, so we
	// just convert to char* -- but String8 doesn't document what it does
	// with values outside 0-255. So just convert to char* and use strlen()
	// to see what we get.
	const char* str = str8.c_str();
	return computeScaledStringWidth(str, strlen(str));
	}

	size_t TextRenderer::glyphIndex(char ch) const {
	size_t chi = ch - FontBitmap::firstGlyphChar;
	if (chi >= FontBitmap::numGlyphs) {
	chi = '?' - FontBitmap::firstGlyphChar;
	}
	assert(chi < FontBitmap::numGlyphs);
	return chi;
	}

	float TextRenderer::computeScaledStringWidth(const char* str,
	size_t len) const {
	float width = 0.0f;
	for (size_t i = 0; i < len; i++) {
	size_t chi = glyphIndex(str[i]);
	float glyphWidth = FontBitmap::glyphWidth[chi];
	width += (glyphWidth - 1 - FontBitmap::outlineWidth) * mScale;
	}

	return width;
	}

	void TextRenderer::drawString(const Program& program, const float* texMatrix,
	float x, float y, const String8& str8) const {
	ALOGV("drawString %.3f,%.3f '%s' (scale=%.3f)", x, y, str8.c_str(),mScale);
	initOnce();

	// We want to draw the entire string with a single GLES call. We
	// generate two arrays, one with screen coordinates, one with texture
	// coordinates. Need two triangles per character.
	const char* str = str8.c_str();
	size_t len = strlen(str); // again, unsure about String8 handling

	const size_t quadCoords =
	2 /triangles/ * 3 /vertex/tri/ * 2 /coord/vertex/;
	float vertices[len * quadCoords];
	float texes[len * quadCoords];

	float fullTexWidth = FontBitmap::width;
	float fullTexHeight = powerOfTwoCeil(FontBitmap::height);
	for (size_t i = 0; i < len; i++) {
	size_t chi = glyphIndex(str[i]);
	float glyphWidth = FontBitmap::glyphWidth[chi];
	float glyphHeight = FontBitmap::maxGlyphHeight;

	float vertLeft = x;
	float vertRight = x + glyphWidth * mScale;
	float vertTop = y;
	float vertBottom = y + glyphHeight * mScale;

	// Lowest-numbered glyph is in top-left of bitmap, which puts it at
	// the bottom-left in texture coordinates.
	float texLeft = mXOffset[chi] / fullTexWidth;
	float texRight = (mXOffset[chi] + glyphWidth) / fullTexWidth;
	float texTop = FontBitmap::yoffset[chi] / fullTexHeight;
	float texBottom = (FontBitmap::yoffset[chi] + glyphHeight) /
	fullTexHeight;

	size_t off = i * quadCoords;
	vertices[off + 0] = vertLeft;
	vertices[off + 1] = vertBottom;
	vertices[off + 2] = vertRight;
	vertices[off + 3] = vertBottom;
	vertices[off + 4] = vertLeft;
	vertices[off + 5] = vertTop;
	vertices[off + 6] = vertLeft;
	vertices[off + 7] = vertTop;
	vertices[off + 8] = vertRight;
	vertices[off + 9] = vertBottom;
	vertices[off + 10] = vertRight;
	vertices[off + 11] = vertTop;
	texes[off + 0] = texLeft;
	texes[off + 1] = texBottom;
	texes[off + 2] = texRight;
	texes[off + 3] = texBottom;
	texes[off + 4] = texLeft;
	texes[off + 5] = texTop;
	texes[off + 6] = texLeft;
	texes[off + 7] = texTop;
	texes[off + 8] = texRight;
	texes[off + 9] = texBottom;
	texes[off + 10] = texRight;
	texes[off + 11] = texTop;

	// We added 1-pixel padding in the texture, so we want to advance by
	// one less. Also, each glyph is surrounded by a black outline, which
	// we want to merge.
	x += (glyphWidth - 1 - FontBitmap::outlineWidth) * mScale;
	}

	program.drawTriangles(mTextureName, texMatrix, vertices, texes,
	len * quadCoords / 2);
	}

	float TextRenderer::drawWrappedString(const Program& texRender,
	float xpos, float ypos, const String8& str) {
	ALOGV("drawWrappedString %.3f,%.3f '%s'", xpos, ypos, str.c_str());
	initOnce();

	if (mScreenWidth == 0 \|\| mScreenHeight == 0) {
	ALOGW("drawWrappedString: can't wrap with width=%d height=%d",
	mScreenWidth, mScreenHeight);
	return ypos;
	}

	const float indentWidth = mIndentMult * getScale();
	if (xpos < mBorderWidth) {
	xpos = mBorderWidth;
	}
	if (ypos < mBorderWidth) {
	ypos = mBorderWidth;
	}

	const size_t maxWidth = (mScreenWidth - mBorderWidth) - xpos;
	if (maxWidth < 1) {
	ALOGE("Unable to render text: xpos=%.3f border=%.3f width=%u",
	xpos, mBorderWidth, mScreenWidth);
	return ypos;
	}
	float stringWidth = computeScaledStringWidth(str);
	if (stringWidth <= maxWidth) {
	// Trivial case.
	drawString(texRender, Program::kIdentity, xpos, ypos, str);
	ypos += getScaledGlyphHeight();
	} else {
	// We need to break the string into pieces, ideally at whitespace
	// boundaries.
	char* mangle = strdup(str.c_str());
	char* start = mangle;
	while (start != NULL) {
	float xposAdj = (start == mangle) ? xpos : xpos + indentWidth;
	char* brk = breakString(start,
	(float) (mScreenWidth - mBorderWidth - xposAdj));
	if (brk == NULL) {
	// draw full string
	drawString(texRender, Program::kIdentity, xposAdj, ypos,
	String8(start));
	start = NULL;
	} else {
	// draw partial string
	char ch = *brk;
	*brk = '\0';
	drawString(texRender, Program::kIdentity, xposAdj, ypos,
	String8(start));
	*brk = ch;
	start = brk;
	if (strchr(kWhitespace, ch) != NULL) {
	// if we broke on whitespace, skip past it
	start++;
	}
	}
	ypos += getScaledGlyphHeight();
	}
	free(mangle);
	}

	return ypos;
	}

	char* TextRenderer::breakString(const char* str, float maxWidth) const {
	// Ideally we'd do clever things like binary search. Not bothering.
	ALOGV("breakString '%s' %.3f", str, maxWidth);

	size_t len = strlen(str);
	if (len == 0) {
	// Caller should detect this and not advance ypos.
	return NULL;
	}

	float stringWidth = computeScaledStringWidth(str, len);
	if (stringWidth <= maxWidth) {
	return NULL; // trivial -- use full string
	}

	// Find the longest string that will fit.
	size_t goodPos = 0;
	for (size_t i = 0; i < len; i++) {
	stringWidth = computeScaledStringWidth(str, i);
	if (stringWidth < maxWidth) {
	goodPos = i;
	} else {
	break; // too big
	}
	}
	if (goodPos == 0) {
	// space is too small to hold any glyph; output a single char
	ALOGW("Couldn't find a nonzero prefix that fit from '%s'", str);
	goodPos = 1;
	}

	// Scan back for whitespace. If we can't find any we'll just have
	// an ugly mid-word break.
	for (size_t i = goodPos; i > 0; i--) {
	if (strchr(kWhitespace, str[i]) != NULL) {
	goodPos = i;
	break;
	}
	}

	ALOGV("goodPos=%zu for str='%s'", goodPos, str);
	return const_cast<char*>(str + goodPos);
	}