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skia / skia / chrome/m38_2125 / . / src / core / SkPicturePlayback.cpp
blob: 6197d88d6655e3d46ea07aee6a0852f8bda6fd97 [file] [log] [blame]
/*
* Copyright 2014 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "SkCanvas.h"
#include "SkPatchUtils.h"
#include "SkPictureData.h"
#include "SkPicturePlayback.h"
#include "SkPictureRecord.h"
#include "SkPictureStateTree.h"
#include "SkReader32.h"
#include "SkTDArray.h"
#include "SkTypes.h"
/*
* Read the next op code and chunk size from 'reader'. The returned size
* is the entire size of the chunk (including the opcode). Thus, the
* offset just prior to calling ReadOpAndSize + 'size' is the offset
* to the next chunk's op code. This also means that the size of a chunk
* with no arguments (just an opcode) will be 4.
*/
DrawType SkPicturePlayback::ReadOpAndSize(SkReader32* reader, uint32_t* size) {
uint32_t temp = reader->readInt();
uint32_t op;
if (((uint8_t)temp) == temp) {
// old skp file - no size information
op = temp;
*size = 0;
} else {
UNPACK_8_24(temp, op, *size);
if (MASK_24 == *size) {
*size = reader->readInt();
}
}
return (DrawType)op;
}
static const SkRect* get_rect_ptr(SkReader32* reader) {
if (reader->readBool()) {
return &reader->skipT<SkRect>();
} else {
return NULL;
}
}
class TextContainer {
public:
size_t length() { return fByteLength; }
const void* text() { return (const void*)fText; }
size_t fByteLength;
const char* fText;
};
void get_text(SkReader32* reader, TextContainer* text) {
size_t length = text->fByteLength = reader->readInt();
text->fText = (const char*)reader->skip(length);
}
// FIXME: SkBitmaps are stateful, so we need to copy them to play back in multiple threads.
static SkBitmap shallow_copy(const SkBitmap& bitmap) {
return bitmap;
}
const SkPicture::OperationList* SkPicturePlayback::getActiveOps(const SkCanvas* canvas) {
if (fUseBBH) {
SkRect clipBounds;
if (canvas->getClipBounds(&clipBounds)) {
SkIRect query;
clipBounds.roundOut(&query);
return fPictureData->getActiveOps(query);
}
}
return NULL;
}
// Initialize the state tree iterator. Return false if there is nothing left to draw.
bool SkPicturePlayback::initIterator(SkPictureStateTree::Iterator* iter,
SkCanvas* canvas,
const SkPicture::OperationList *activeOpsList) {
if (NULL != activeOpsList) {
if (0 == activeOpsList->numOps()) {
return false; // nothing to draw
}
fPictureData->initIterator(iter, activeOpsList->fOps, canvas);
}
return true;
}
// If 'iter' is valid use it to skip forward through the picture.
void SkPicturePlayback::StepIterator(SkPictureStateTree::Iterator* iter, SkReader32* reader) {
if (iter->isValid()) {
uint32_t skipTo = iter->nextDraw();
if (SkPictureStateTree::Iterator::kDrawComplete == skipTo) {
reader->setOffset(reader->size()); // skip to end
} else {
reader->setOffset(skipTo);
}
}
}
// Update the iterator and state tree to catch up with the skipped ops.
void SkPicturePlayback::SkipIterTo(SkPictureStateTree::Iterator* iter,
SkReader32* reader,
uint32_t skipTo) {
SkASSERT(skipTo <= reader->size());
SkASSERT(reader->offset() <= skipTo); // should only be skipping forward
if (iter->isValid()) {
// If using a bounding box hierarchy, advance the state tree
// iterator until at or after skipTo
uint32_t adjustedSkipTo;
do {
adjustedSkipTo = iter->nextDraw();
} while (adjustedSkipTo < skipTo);
skipTo = adjustedSkipTo;
}
if (SkPictureStateTree::Iterator::kDrawComplete == skipTo) {
reader->setOffset(reader->size()); // skip to end
} else {
reader->setOffset(skipTo);
}
}
void SkPicturePlayback::draw(SkCanvas* canvas, SkDrawPictureCallback* callback) {
AutoResetOpID aroi(this);
SkASSERT(0 == fCurOffset);
SkAutoTDelete<const SkPicture::OperationList> activeOpsList(this->getActiveOps(canvas));
SkPictureStateTree::Iterator it;
if (!this->initIterator(&it, canvas, activeOpsList.get())) {
return; // nothing to draw
}
SkReader32 reader(fPictureData->opData()->bytes(), fPictureData->opData()->size());
StepIterator(&it, &reader);
// Record this, so we can concat w/ it if we encounter a setMatrix()
SkMatrix initialMatrix = canvas->getTotalMatrix();
SkAutoCanvasRestore acr(canvas, false);
while (!reader.eof()) {
if (NULL != callback && callback->abortDrawing()) {
return;
}
fCurOffset = reader.offset();
uint32_t size;
DrawType op = ReadOpAndSize(&reader, &size);
if (NOOP == op) {
// NOOPs are to be ignored - do not propagate them any further
SkipIterTo(&it, &reader, fCurOffset + size);
continue;
}
this->handleOp(&reader, op, size, canvas, initialMatrix);
StepIterator(&it, &reader);
}
}
void SkPicturePlayback::handleOp(SkReader32* reader,
DrawType op,
uint32_t size,
SkCanvas* canvas,
const SkMatrix& initialMatrix) {
switch (op) {
case CLIP_PATH: {
const SkPath& path = fPictureData->getPath(reader);
uint32_t packed = reader->readInt();
SkRegion::Op regionOp = ClipParams_unpackRegionOp(packed);
bool doAA = ClipParams_unpackDoAA(packed);
size_t offsetToRestore = reader->readInt();
SkASSERT(!offsetToRestore || offsetToRestore >= reader->offset());
canvas->clipPath(path, regionOp, doAA);
if (canvas->isClipEmpty() && offsetToRestore) {
reader->setOffset(offsetToRestore);
}
} break;
case CLIP_REGION: {
SkRegion region;
reader->readRegion(&region);
uint32_t packed = reader->readInt();
SkRegion::Op regionOp = ClipParams_unpackRegionOp(packed);
size_t offsetToRestore = reader->readInt();
SkASSERT(!offsetToRestore || offsetToRestore >= reader->offset());
canvas->clipRegion(region, regionOp);
if (canvas->isClipEmpty() && offsetToRestore) {
reader->setOffset(offsetToRestore);
}
} break;
case CLIP_RECT: {
const SkRect& rect = reader->skipT<SkRect>();
uint32_t packed = reader->readInt();
SkRegion::Op regionOp = ClipParams_unpackRegionOp(packed);
bool doAA = ClipParams_unpackDoAA(packed);
size_t offsetToRestore = reader->readInt();
SkASSERT(!offsetToRestore || offsetToRestore >= reader->offset());
canvas->clipRect(rect, regionOp, doAA);
if (canvas->isClipEmpty() && offsetToRestore) {
reader->setOffset(offsetToRestore);
}
} break;
case CLIP_RRECT: {
SkRRect rrect;
reader->readRRect(&rrect);
uint32_t packed = reader->readInt();
SkRegion::Op regionOp = ClipParams_unpackRegionOp(packed);
bool doAA = ClipParams_unpackDoAA(packed);
size_t offsetToRestore = reader->readInt();
SkASSERT(!offsetToRestore || offsetToRestore >= reader->offset());
canvas->clipRRect(rrect, regionOp, doAA);
if (canvas->isClipEmpty() && offsetToRestore) {
reader->setOffset(offsetToRestore);
}
} break;
case PUSH_CULL: {
const SkRect& cullRect = reader->skipT<SkRect>();
size_t offsetToRestore = reader->readInt();
if (offsetToRestore && canvas->quickReject(cullRect)) {
reader->setOffset(offsetToRestore);
} else {
canvas->pushCull(cullRect);
}
} break;
case POP_CULL:
canvas->popCull();
break;
case CONCAT: {
SkMatrix matrix;
reader->readMatrix(&matrix);
canvas->concat(matrix);
break;
}
case DRAW_BITMAP: {
const SkPaint* paint = fPictureData->getPaint(reader);
const SkBitmap bitmap = shallow_copy(fPictureData->getBitmap(reader));
const SkPoint& loc = reader->skipT<SkPoint>();
canvas->drawBitmap(bitmap, loc.fX, loc.fY, paint);
} break;
case DRAW_BITMAP_RECT_TO_RECT: {
const SkPaint* paint = fPictureData->getPaint(reader);
const SkBitmap bitmap = shallow_copy(fPictureData->getBitmap(reader));
const SkRect* src = get_rect_ptr(reader); // may be null
const SkRect& dst = reader->skipT<SkRect>(); // required
SkCanvas::DrawBitmapRectFlags flags;
flags = (SkCanvas::DrawBitmapRectFlags) reader->readInt();
canvas->drawBitmapRectToRect(bitmap, src, dst, paint, flags);
} break;
case DRAW_BITMAP_MATRIX: {
const SkPaint* paint = fPictureData->getPaint(reader);
const SkBitmap bitmap = shallow_copy(fPictureData->getBitmap(reader));
SkMatrix matrix;
reader->readMatrix(&matrix);
canvas->drawBitmapMatrix(bitmap, matrix, paint);
} break;
case DRAW_BITMAP_NINE: {
const SkPaint* paint = fPictureData->getPaint(reader);
const SkBitmap bitmap = shallow_copy(fPictureData->getBitmap(reader));
const SkIRect& src = reader->skipT<SkIRect>();
const SkRect& dst = reader->skipT<SkRect>();
canvas->drawBitmapNine(bitmap, src, dst, paint);
} break;
case DRAW_CLEAR:
canvas->clear(reader->readInt());
break;
case DRAW_DATA: {
size_t length = reader->readInt();
canvas->drawData(reader->skip(length), length);
// skip handles padding the read out to a multiple of 4
} break;
case DRAW_DRRECT: {
const SkPaint& paint = *fPictureData->getPaint(reader);
SkRRect outer, inner;
reader->readRRect(&outer);
reader->readRRect(&inner);
canvas->drawDRRect(outer, inner, paint);
} break;
case BEGIN_COMMENT_GROUP: {
const char* desc = reader->readString();
canvas->beginCommentGroup(desc);
} break;
case COMMENT: {
const char* kywd = reader->readString();
const char* value = reader->readString();
canvas->addComment(kywd, value);
} break;
case END_COMMENT_GROUP: {
canvas->endCommentGroup();
} break;
case DRAW_OVAL: {
const SkPaint& paint = *fPictureData->getPaint(reader);
canvas->drawOval(reader->skipT<SkRect>(), paint);
} break;
case DRAW_PAINT:
canvas->drawPaint(*fPictureData->getPaint(reader));
break;
case DRAW_PATCH: {
const SkPaint& paint = *fPictureData->getPaint(reader);
const SkPoint* cubics = (const SkPoint*)reader->skip(SkPatchUtils::kNumCtrlPts *
sizeof(SkPoint));
uint32_t flag = reader->readInt();
const SkColor* colors = NULL;
if (flag & DRAW_VERTICES_HAS_COLORS) {
colors = (const SkColor*)reader->skip(SkPatchUtils::kNumCorners * sizeof(SkColor));
}
const SkPoint* texCoords = NULL;
if (flag & DRAW_VERTICES_HAS_TEXS) {
texCoords = (const SkPoint*)reader->skip(SkPatchUtils::kNumCorners *
sizeof(SkPoint));
}
SkAutoTUnref<SkXfermode> xfer;
if (flag & DRAW_VERTICES_HAS_XFER) {
int mode = reader->readInt();
if (mode < 0 || mode > SkXfermode::kLastMode) {
mode = SkXfermode::kModulate_Mode;
}
xfer.reset(SkXfermode::Create((SkXfermode::Mode)mode));
}
canvas->drawPatch(cubics, colors, texCoords, xfer, paint);
} break;
case DRAW_PATH: {
const SkPaint& paint = *fPictureData->getPaint(reader);
canvas->drawPath(fPictureData->getPath(reader), paint);
} break;
case DRAW_PICTURE:
canvas->drawPicture(fPictureData->getPicture(reader));
break;
case DRAW_PICTURE_MATRIX_PAINT: {
const SkPaint* paint = fPictureData->getPaint(reader);
SkMatrix matrix;
reader->readMatrix(&matrix);
const SkPicture* pic = fPictureData->getPicture(reader);
canvas->drawPicture(pic, &matrix, paint);
} break;
case DRAW_POINTS: {
const SkPaint& paint = *fPictureData->getPaint(reader);
SkCanvas::PointMode mode = (SkCanvas::PointMode)reader->readInt();
size_t count = reader->readInt();
const SkPoint* pts = (const SkPoint*)reader->skip(sizeof(SkPoint)* count);
canvas->drawPoints(mode, count, pts, paint);
} break;
case DRAW_POS_TEXT: {
const SkPaint& paint = *fPictureData->getPaint(reader);
TextContainer text;
get_text(reader, &text);
size_t points = reader->readInt();
const SkPoint* pos = (const SkPoint*)reader->skip(points * sizeof(SkPoint));
canvas->drawPosText(text.text(), text.length(), pos, paint);
} break;
case DRAW_POS_TEXT_TOP_BOTTOM: {
const SkPaint& paint = *fPictureData->getPaint(reader);
TextContainer text;
get_text(reader, &text);
size_t points = reader->readInt();
const SkPoint* pos = (const SkPoint*)reader->skip(points * sizeof(SkPoint));
const SkScalar top = reader->readScalar();
const SkScalar bottom = reader->readScalar();
if (!canvas->quickRejectY(top, bottom)) {
canvas->drawPosText(text.text(), text.length(), pos, paint);
}
} break;
case DRAW_POS_TEXT_H: {
const SkPaint& paint = *fPictureData->getPaint(reader);
TextContainer text;
get_text(reader, &text);
size_t xCount = reader->readInt();
const SkScalar constY = reader->readScalar();
const SkScalar* xpos = (const SkScalar*)reader->skip(xCount * sizeof(SkScalar));
canvas->drawPosTextH(text.text(), text.length(), xpos, constY, paint);
} break;
case DRAW_POS_TEXT_H_TOP_BOTTOM: {
const SkPaint& paint = *fPictureData->getPaint(reader);
TextContainer text;
get_text(reader, &text);
size_t xCount = reader->readInt();
const SkScalar* xpos = (const SkScalar*)reader->skip((3 + xCount) * sizeof(SkScalar));
const SkScalar top = *xpos++;
const SkScalar bottom = *xpos++;
const SkScalar constY = *xpos++;
if (!canvas->quickRejectY(top, bottom)) {
canvas->drawPosTextH(text.text(), text.length(), xpos, constY, paint);
}
} break;
case DRAW_RECT: {
const SkPaint& paint = *fPictureData->getPaint(reader);
canvas->drawRect(reader->skipT<SkRect>(), paint);
} break;
case DRAW_RRECT: {
const SkPaint& paint = *fPictureData->getPaint(reader);
SkRRect rrect;
reader->readRRect(&rrect);
canvas->drawRRect(rrect, paint);
} break;
case DRAW_SPRITE: {
const SkPaint* paint = fPictureData->getPaint(reader);
const SkBitmap bitmap = shallow_copy(fPictureData->getBitmap(reader));
int left = reader->readInt();
int top = reader->readInt();
canvas->drawSprite(bitmap, left, top, paint);
} break;
case DRAW_TEXT: {
const SkPaint& paint = *fPictureData->getPaint(reader);
TextContainer text;
get_text(reader, &text);
SkScalar x = reader->readScalar();
SkScalar y = reader->readScalar();
canvas->drawText(text.text(), text.length(), x, y, paint);
} break;
case DRAW_TEXT_TOP_BOTTOM: {
const SkPaint& paint = *fPictureData->getPaint(reader);
TextContainer text;
get_text(reader, &text);
const SkScalar* ptr = (const SkScalar*)reader->skip(4 * sizeof(SkScalar));
// ptr[0] == x
// ptr[1] == y
// ptr[2] == top
// ptr[3] == bottom
if (!canvas->quickRejectY(ptr[2], ptr[3])) {
canvas->drawText(text.text(), text.length(), ptr[0], ptr[1], paint);
}
} break;
case DRAW_TEXT_ON_PATH: {
const SkPaint& paint = *fPictureData->getPaint(reader);
TextContainer text;
get_text(reader, &text);
const SkPath& path = fPictureData->getPath(reader);
SkMatrix matrix;
reader->readMatrix(&matrix);
canvas->drawTextOnPath(text.text(), text.length(), path, &matrix, paint);
} break;
case DRAW_VERTICES: {
SkAutoTUnref<SkXfermode> xfer;
const SkPaint& paint = *fPictureData->getPaint(reader);
DrawVertexFlags flags = (DrawVertexFlags)reader->readInt();
SkCanvas::VertexMode vmode = (SkCanvas::VertexMode)reader->readInt();
int vCount = reader->readInt();
const SkPoint* verts = (const SkPoint*)reader->skip(vCount * sizeof(SkPoint));
const SkPoint* texs = NULL;
const SkColor* colors = NULL;
const uint16_t* indices = NULL;
int iCount = 0;
if (flags & DRAW_VERTICES_HAS_TEXS) {
texs = (const SkPoint*)reader->skip(vCount * sizeof(SkPoint));
}
if (flags & DRAW_VERTICES_HAS_COLORS) {
colors = (const SkColor*)reader->skip(vCount * sizeof(SkColor));
}
if (flags & DRAW_VERTICES_HAS_INDICES) {
iCount = reader->readInt();
indices = (const uint16_t*)reader->skip(iCount * sizeof(uint16_t));
}
if (flags & DRAW_VERTICES_HAS_XFER) {
int mode = reader->readInt();
if (mode < 0 || mode > SkXfermode::kLastMode) {
mode = SkXfermode::kModulate_Mode;
}
xfer.reset(SkXfermode::Create((SkXfermode::Mode)mode));
}
canvas->drawVertices(vmode, vCount, verts, texs, colors, xfer, indices, iCount, paint);
} break;
case RESTORE:
canvas->restore();
break;
case ROTATE:
canvas->rotate(reader->readScalar());
break;
case SAVE:
// SKPs with version < 29 also store a SaveFlags param.
if (size > 4) {
SkASSERT(8 == size);
reader->readInt();
}
canvas->save();
break;
case SAVE_LAYER: {
const SkRect* boundsPtr = get_rect_ptr(reader);
const SkPaint* paint = fPictureData->getPaint(reader);
canvas->saveLayer(boundsPtr, paint, (SkCanvas::SaveFlags) reader->readInt());
} break;
case SCALE: {
SkScalar sx = reader->readScalar();
SkScalar sy = reader->readScalar();
canvas->scale(sx, sy);
} break;
case SET_MATRIX: {
SkMatrix matrix;
reader->readMatrix(&matrix);
matrix.postConcat(initialMatrix);
canvas->setMatrix(matrix);
} break;
case SKEW: {
SkScalar sx = reader->readScalar();
SkScalar sy = reader->readScalar();
canvas->skew(sx, sy);
} break;
case TRANSLATE: {
SkScalar dx = reader->readScalar();
SkScalar dy = reader->readScalar();
canvas->translate(dx, dy);
} break;
default:
SkASSERT(0);
}
}