core/src/fxge/skia/fx_skia_device.cpp - pdfium - Git at Google

 // Copyright 2014 PDFium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "../../../include/fxge/fx_ge.h"
 //#define _SKIA_SUPPORT_
 #if defined(_SKIA_SUPPORT_)
 #include "../../../include/fxcodec/fx_codec.h"


 //#define _FOXIT_DEBUG_
 //#define _FOXIT_BENCHMARK_

 extern "C" {
 	extern void FX_OUTPUT_LOG_FUNC(const char*, ...);
 	extern int FX_GET_TICK_FUNC();
 };

 #ifdef _FOXIT_DEBUG_
 #define FOXIT_DEBUG1(msg) FX_OUTPUT_LOG_FUNC(msg)
 #define FOXIT_DEBUG2(msg,para) FX_OUTPUT_LOG_FUNC(msg,para)
 #define FOXIT_DEBUG3(msg,para1,para2) FX_OUTPUT_LOG_FUNC(msg,para1,para2)
 #define FOXIT_DEBUG4(msg,para1,para2,para3) FX_OUTPUT_LOG_FUNC(msg,para1,para2,para3)
 #define FOXIT_DEBUG5(msg,para1,para2,para3,param4) FX_OUTPUT_LOG_FUNC(msg,para1,para2,para3,param4)
 #else
 #define FOXIT_DEBUG1(msg)
 #define FOXIT_DEBUG2(msg,para)
 #define FOXIT_DEBUG3(msg,para1,para2)
 #define FOXIT_DEBUG4(msg,para1,para2,para3)
 #define FOXIT_DEBUG5(msg,para1,para2,para3,param4)
 #endif

 #include "SkDashPathEffect.h"
 #include "SkTLazy.h"
 #include "SkScan.h"
 #include "SkRasterClip.h"
 #include "SkStroke.h"


 #include "fx_skia_blitter_new.h"
 #include "../agg/fx_agg_driver.h"
 #include "fx_skia_device.h"
 /// Run-length-encoded supersampling antialiased blitter.
 class SuperBlitter_skia
 {
 public:
 	static void DrawPath(const SkPath& srcPath, SkBlitter* blitter,  const SkRasterClip& rect, const SkPaint& origPaint);
 };
 FX_BOOL FxSkDrawTreatAsHairline(const SkPaint& paint, SkScalar* coverage) {
 	if (SkPaint::kStroke_Style != paint.getStyle())
 		return FALSE;
 	FXSYS_assert(coverage);
 	SkScalar strokeWidth = paint.getStrokeWidth();
 	if (0 == strokeWidth) {
 		*coverage = SK_Scalar1;
 		return TRUE;
 	}
 	// if we get here, we need to try to fake a thick-stroke with a modulated
 	// hairline
 	if (!paint.isAntiAlias())
 		return FALSE;
 	if (strokeWidth <= SK_Scalar1) {
 		*coverage = strokeWidth;
 		return TRUE;
 	}
 	return FALSE;
 }

 void SuperBlitter_skia::DrawPath(const SkPath& srcPath, SkBlitter* blitter, const SkRasterClip& rect, const SkPaint& origPaint)
 {
 	SkPath*		pathPtr = (SkPath*)&srcPath;
 	bool		doFill = true;
 	SkPath		tmpPath;
 	SkTCopyOnFirstWrite<SkPaint> paint(origPaint);
 	{
 		SkScalar coverage;
 		if (FxSkDrawTreatAsHairline(origPaint, &coverage)) {
 			if (SK_Scalar1 == coverage) {
 				paint.writable()->setStrokeWidth(0);
 			} else if (1) {//xfermodeSupportsCoverageAsAlpha(xfer), we not use blend mode here, xfer aways NULL.
 				U8CPU newAlpha;
 				// this is the old technique, which we preserve for now so
 				// we don't change previous results (testing)
 				// the new way seems fine, its just (a tiny bit) different
 				int scale = (int)SkScalarMul(coverage, 256);
 				newAlpha = origPaint.getAlpha() * scale >> 8;
 				SkPaint* writablePaint = paint.writable();
 				writablePaint->setStrokeWidth(0);
 				writablePaint->setAlpha(newAlpha);
 			}
 		}
 	}
 	if (paint->getPathEffect() || paint->getStyle() != SkPaint::kFill_Style) {
 		SkIRect devBounds = rect.getBounds();
 		// outset to have slop for antialasing and hairlines
 		devBounds.outset(1, 1);
 		SkRect cullRect = SkRect::Make(devBounds);
 		doFill = paint->getFillPath(*pathPtr, &tmpPath, &cullRect);
 		pathPtr = &tmpPath;
 	}
 	// avoid possibly allocating a new path in transform if we can
 	SkPath* devPathPtr = pathPtr;
 	void (*proc)(const SkPath&, const SkRasterClip&, SkBlitter*);
 	if (doFill) {
 		if (paint->isAntiAlias()) {
 			proc = SkScan::AntiFillPath;
 		} else {
 			proc = SkScan::FillPath;
 		}
 	} else {	// hairline
 		if (paint->isAntiAlias()) {
 			proc = SkScan::AntiHairPath;
 		} else {
 			proc = SkScan::HairPath;
 		}
 	}
 	proc(*devPathPtr, rect, blitter);
 }

 class CSkia_PathData
 {
 public:
 	CSkia_PathData() {}
 	~CSkia_PathData() {}
 	SkPath			m_PathData;

 	void			BuildPath(const CFX_PathData* pPathData, const CFX_AffineMatrix* pObject2Device);
 };

 void CSkia_PathData::BuildPath(const CFX_PathData* pPathData, const CFX_AffineMatrix* pObject2Device)
 {
 	const CFX_PathData* pFPath = pPathData;
 	int nPoints = pFPath->GetPointCount();
 	FX_PATHPOINT* pPoints = pFPath->GetPoints();
 	for (int i = 0; i < nPoints; i ++) {
 		FX_FIXFLOAT x = pPoints[i].m_PointX, y = pPoints[i].m_PointY;
 		if (pObject2Device) pObject2Device->Transform(x, y);
 		int point_type = pPoints[i].m_Flag & FXPT_TYPE;
 		if (point_type == FXPT_MOVETO) {
 			m_PathData.moveTo(x, y);
 		} else if (point_type == FXPT_LINETO) {
 			if (pPoints[i-1].m_Flag == FXPT_MOVETO && (i == nPoints-1 || pPoints[i+1].m_Flag == FXPT_MOVETO) &&
 					FXSYS_abs(pPoints[i].m_PointX - pPoints[i-1].m_PointX) < 0.4f && FXSYS_abs(pPoints[i].m_PointY - pPoints[i-1].m_PointY)< 0.4f)
 				// PDF line includes the destination point, unlike Windows line.
 				// We received some PDF which actually draws zero length lines. TESTDOC: summer cha show.pdf
 				// Therefore, we have to extend the line by 0.4 pixel here.
 				// But only for standalone segment. TESTDOC: bug #1434 - maze.pdf; TESTDOC: bug#1508 di704P_QIG_111.pdf
 				x += 0.4;
 			// TODO: we should actually tell skia vertex generator to process zero length stroked line
 			// (only butts are drawn)
 			m_PathData.lineTo(x, y);
 		} else if (point_type == FXPT_BEZIERTO) {
 			FX_FIXFLOAT x2 = pPoints[i+1].m_PointX, y2 = pPoints[i+1].m_PointY;
 			FX_FIXFLOAT x3 = pPoints[i+2].m_PointX, y3 = pPoints[i+2].m_PointY;
 			if (pObject2Device){
 				pObject2Device->Transform(x2, y2);
 				pObject2Device->Transform(x3, y3);
 			}
 			m_PathData.cubicTo(x, y, x2, y2, x3, y3);
 			i += 2;
 		}
 		if (pPoints[i].m_Flag & FXPT_CLOSEFIGURE) m_PathData.close();
 	}
 }

 // convert a stroking path to scanlines
 static void SkRasterizeStroke(SkPaint& spaint, SkPath* dstPathData, SkPath& path_data,
 					 const CFX_AffineMatrix* pObject2Device,
 					 const CFX_GraphStateData* pGraphState, FX_FIXFLOAT scale = FIX8_ONE,
 					 FX_BOOL bStrokeAdjust = FALSE, FX_BOOL bTextMode = FALSE)
 {
 	SkPaint::Cap cap;
 	switch (pGraphState->m_LineCap) {
 		case CFX_GraphStateData::LineCapRound:
 			cap = SkPaint::kRound_Cap;
 			break;
 		case CFX_GraphStateData::LineCapSquare:
 			cap = SkPaint::kSquare_Cap;
 			break;
 		default:
 			cap = SkPaint::kButt_Cap;
 			break;
 	}
 	SkPaint::Join join;
 	switch (pGraphState->m_LineJoin) {
 		case CFX_GraphStateData::LineJoinRound:
 			join = SkPaint::kRound_Join;
 			break;
 		case CFX_GraphStateData::LineJoinBevel:
 			join = SkPaint::kBevel_Join;
 			break;
 		default:
 			join = SkPaint::kMiter_Join;
 			break;
 	}
 	FX_FIXFLOAT width = pGraphState->m_LineWidth*scale;
 	FX_FIXFLOAT unit = fix32_to_8(fixdiv_8_8_to_32(FIX8_ONE, (pObject2Device->GetXUnit() + pObject2Device->GetYUnit()) / 2));
 	if (width <= unit) width = unit;

 	if (pGraphState->m_DashArray == NULL) {
 		SkStroke stroker;
 		stroker.setCap(cap);
 		stroker.setJoin(join);
 		stroker.setMiterLimit(pGraphState->m_MiterLimit);
 		stroker.setWidth(width);
 		stroker.setDoFill(FALSE);
 		stroker.strokePath(path_data, dstPathData);
 		SkMatrix smatrix;
 		smatrix.setAll(pObject2Device->a, pObject2Device->c, pObject2Device->e, pObject2Device->b, pObject2Device->d, pObject2Device->f, 0, 0, 1);
 		dstPathData->transform(smatrix);
 	} else {
 		int count = (pGraphState->m_DashCount+1)/2;
 		SkScalar* intervals = FX_Alloc2D(SkScalar, count, sizeof(SkScalar));
 		// Set dash pattern
 		for (int i = 0; i < count; i ++) {
 			FX_FIXFLOAT on = pGraphState->m_DashArray[i*2];
 			if (on <= 0.000001f) on = FIX8_ONE/10;
 			FX_FIXFLOAT off = i*2+1 == pGraphState->m_DashCount ? on :
 					pGraphState->m_DashArray[i*2+1];
 			if (off < 0) off = 0;
 			intervals[i*2]=on*scale;
 			intervals[i*2+1]=off*scale;
 		}
 		SkDashPathEffect* pEffect = new SkDashPathEffect(intervals,count*2, pGraphState->m_DashPhase*scale);
 		spaint.setPathEffect(pEffect)->unref();
 		spaint.setStrokeWidth(width);
 		spaint.setStrokeMiter(pGraphState->m_MiterLimit);
 		spaint.setStrokeCap(cap);
 		spaint.setStrokeJoin(join);
 		spaint.getFillPath(path_data, dstPathData);
 		SkMatrix smatrix;
 		smatrix.setAll(pObject2Device->a, pObject2Device->c, pObject2Device->e, pObject2Device->b, pObject2Device->d, pObject2Device->f, 0, 0, 1);
 		dstPathData->transform(smatrix);
 		FX_Free(intervals);
 	}
 }

 CFX_SkiaDeviceDriver::CFX_SkiaDeviceDriver(CFX_DIBitmap* pBitmap, int dither_bits, FX_BOOL bRgbByteOrder, CFX_DIBitmap* pOriDevice, FX_BOOL bGroupKnockout)
 {
 	m_pAggDriver = new CFX_AggDeviceDriver(pBitmap, dither_bits, bRgbByteOrder, pOriDevice, bGroupKnockout);
 }
 CFX_SkiaDeviceDriver::~CFX_SkiaDeviceDriver()
 {
     delete m_pAggDriver;
 }
 FX_BOOL CFX_SkiaDeviceDriver::DrawDeviceText(int nChars, const FXTEXT_CHARPOS* pCharPos, CFX_Font* pFont,
 		CFX_FontCache* pCache, const CFX_AffineMatrix* pObject2Device, FX_FIXFLOAT font_size, FX_DWORD color,
 		int alpha_flag, void* pIccTransform)
 {
 	return m_pAggDriver->DrawDeviceText(nChars, pCharPos, pFont,pCache, pObject2Device, font_size, color,
 		alpha_flag, pIccTransform);
 }
 int CFX_SkiaDeviceDriver::GetDeviceCaps(int caps_id)
 {
 	return m_pAggDriver->GetDeviceCaps(caps_id);
 }
 void CFX_SkiaDeviceDriver::SaveState()
 {
 	m_pAggDriver->SaveState();
 }

 void CFX_SkiaDeviceDriver::RestoreState(FX_BOOL bKeepSaved)
 {
 	m_pAggDriver->RestoreState(bKeepSaved);
 }
 void CFX_SkiaDeviceDriver::SetClipMask(rasterizer_scanline_aa& rasterizer)
 {
 	m_pAggDriver->SetClipMask(rasterizer);
 }
 void CFX_SkiaDeviceDriver::SetClipMask(SkPath& skPath, SkPaint* spaint)
 {
 	SkIRect clip_box;
 	clip_box.set(0, 0, fix0_to_8(GetDeviceCaps(FXDC_PIXEL_WIDTH)), fix0_to_8(GetDeviceCaps(FXDC_PIXEL_HEIGHT)));
 	clip_box.intersect(m_pAggDriver->m_pClipRgn->GetBox().left, m_pAggDriver->m_pClipRgn->GetBox().top,
 		m_pAggDriver->m_pClipRgn->GetBox().right, m_pAggDriver->m_pClipRgn->GetBox().bottom);

 	SkPath* pathPtr = &skPath;

 	SkRect path_rect = skPath.getBounds();

 	clip_box.intersect(FXSYS_floor(path_rect.fLeft), FXSYS_floor(path_rect.fTop), FXSYS_floor(path_rect.fRight)+1, FXSYS_floor(path_rect.fBottom)+1);
 	CFX_DIBitmapRef mask;
 	CFX_DIBitmap* pThisLayer = mask.New();
 	pThisLayer->Create(clip_box.width(), clip_box.height(), FXDIB_8bppMask);
 	pThisLayer->Clear(0);

 	CFX_SkiaA8Renderer render;
 	render.Init(pThisLayer, clip_box.fLeft, clip_box.fTop);

 	SkRasterClip rasterClip(clip_box);
 	SuperBlitter_skia::DrawPath(skPath, (SkBlitter*)&render, rasterClip, *spaint);

 	// Finally, we have got the mask that we need, intersect with current clip region
 	m_pAggDriver->m_pClipRgn->IntersectMaskF(clip_box.fLeft, clip_box.fTop, mask);

 }
 FX_BOOL CFX_SkiaDeviceDriver::SetClip_PathFill(const CFX_PathData* pPathData,	// path info
 						const CFX_AffineMatrix* pObject2Device,	// optional transformation
 						int fill_mode	// fill mode, WINDING or ALTERNATE
 						)
 {
 	if (m_pAggDriver->m_pClipRgn == NULL)
 		m_pAggDriver->m_pClipRgn = new CFX_ClipRgn(GetDeviceCaps(FXDC_PIXEL_WIDTH), GetDeviceCaps(FXDC_PIXEL_HEIGHT));

 	if (pPathData->GetPointCount() == 5 || pPathData->GetPointCount() == 4) {
 		CFX_FloatRect rectf;
 		if (pPathData->IsRect(pObject2Device, &rectf)) {
 			rectf.Intersect(CFX_FloatRect(0, 0, (FX_FIXFLOAT)GetDeviceCaps(FXDC_PIXEL_WIDTH), (FX_FIXFLOAT)GetDeviceCaps(FXDC_PIXEL_HEIGHT)));
 			FX_RECT rect = rectf.GetOutterRect();
 			m_pAggDriver->m_pClipRgn->IntersectRect(rect);
 			return TRUE;
 		}
 	}
 	CSkia_PathData path_data;
 	path_data.BuildPath(pPathData, pObject2Device);
 	path_data.m_PathData.close();
 	path_data.m_PathData.setFillType((fill_mode&3) == FXFILL_WINDING? SkPath::kWinding_FillType:SkPath::kEvenOdd_FillType);

 	SkPaint spaint;
 	spaint.setColor(0xffffffff);
 	spaint.setAntiAlias(TRUE);
 	spaint.setStyle(SkPaint::kFill_Style);

 	SetClipMask(path_data.m_PathData, &spaint);

 	return TRUE;
 }

 FX_BOOL CFX_SkiaDeviceDriver::SetClip_PathStroke(const CFX_PathData* pPathData,	// path info
 						const CFX_AffineMatrix* pObject2Device,	// optional transformation
 						const CFX_GraphStateData* pGraphState	// graphic state, for pen attributes
 					)
 {
 	if (m_pAggDriver->m_pClipRgn == NULL)
 		m_pAggDriver->m_pClipRgn = new CFX_ClipRgn(GetDeviceCaps(FXDC_PIXEL_WIDTH), GetDeviceCaps(FXDC_PIXEL_HEIGHT));

 	// build path data
 	CSkia_PathData path_data;
 	path_data.BuildPath(pPathData, NULL);
 	path_data.m_PathData.setFillType(SkPath::kWinding_FillType);

 	SkPaint spaint;
 	spaint.setColor(0xffffffff);
 	spaint.setStyle(SkPaint::kStroke_Style);
 	spaint.setAntiAlias(TRUE);

 	SkPath dst_path;
 	SkRasterizeStroke(spaint, &dst_path, path_data.m_PathData, pObject2Device, pGraphState, 1, FALSE, 0);
 	spaint.setStyle(SkPaint::kFill_Style);
 	SetClipMask(dst_path, &spaint);

 	return TRUE;
 }
 FX_BOOL CFX_SkiaDeviceDriver::RenderRasterizer(rasterizer_scanline_aa& rasterizer, FX_DWORD color, FX_BOOL bFullCover, FX_BOOL bGroupKnockout,
 											  int alpha_flag, void* pIccTransform)
 {
 	return m_pAggDriver->RenderRasterizer(rasterizer, color, bFullCover, bGroupKnockout,alpha_flag, pIccTransform);
 }
 FX_BOOL	CFX_SkiaDeviceDriver::RenderRasterizerSkia(SkPath& skPath, const SkPaint& origPaint, SkIRect& rect, FX_DWORD color, FX_BOOL bFullCover, FX_BOOL bGroupKnockout,
 							int alpha_flag, void* pIccTransform, FX_BOOL bFill)
 {
 	CFX_DIBitmap* pt = bGroupKnockout?m_pAggDriver->GetBackDrop():NULL;
 	CFX_SkiaRenderer render;
 	if (!render.Init(m_pAggDriver->m_pBitmap, pt, m_pAggDriver->m_pClipRgn, color, bFullCover, m_pAggDriver->m_bRgbByteOrder, alpha_flag, pIccTransform))
 		return FALSE;

 	SkRasterClip rasterClip(rect);
 	SuperBlitter_skia::DrawPath(skPath, (SkBlitter*)&render,  rasterClip, origPaint);

 	return TRUE;

 }

 FX_BOOL	CFX_SkiaDeviceDriver::DrawPath(const CFX_PathData* pPathData,	// path info
 						const CFX_AffineMatrix* pObject2Device,	// optional transformation
 						const CFX_GraphStateData* pGraphState,	// graphic state, for pen attributes
 						FX_DWORD fill_color,			// fill color
 						FX_DWORD stroke_color,			// stroke color
 						int fill_mode,					// fill mode, WINDING or ALTERNATE. 0 for not filled
 						int alpha_flag,
 						void* pIccTransform
 						)
 {
 	if (GetBuffer() == NULL) return TRUE;
 	FOXIT_DEBUG1("CFX_SkiaDeviceDriver::DrawPath: entering");
 	SkIRect rect;
 	rect.set(0, 0, GetDeviceCaps(FXDC_PIXEL_WIDTH), GetDeviceCaps(FXDC_PIXEL_HEIGHT));
 	if ((fill_mode & 3) && fill_color) {
 		// We have to transform before building path data, otherwise we'll have flatting problem
 		// when we enlarge a small path (flatten before transformed)
 		// TESTDOC: Bug #5115 - DS_S1Dimpact_lr.pdf
 		// build path data
 		CSkia_PathData path_data;
 		path_data.BuildPath(pPathData, pObject2Device);
 		//path_data.m_PathData.close();
 		path_data.m_PathData.setFillType((fill_mode&3) == FXFILL_WINDING? SkPath::kWinding_FillType:SkPath::kEvenOdd_FillType);

 		SkPaint spaint;
 		spaint.setAntiAlias(TRUE);
 		spaint.setStyle(SkPaint::kFill_Style);
 		spaint.setColor(fill_color);
 		if (!RenderRasterizerSkia(path_data.m_PathData, spaint, rect, fill_color, fill_mode & FXFILL_FULLCOVER, FALSE, alpha_flag, pIccTransform))
 			return FALSE;
 	}

 	int stroke_alpha = FXGETFLAG_COLORTYPE(alpha_flag) ? FXGETFLAG_ALPHA_STROKE(alpha_flag) : FXARGB_A(stroke_color);

 	if (pGraphState && stroke_alpha) {
 		// We split the matrix into two parts: first part doing the scaling, so we won't have the
 		// flatness problem, second part doing the transformation, so we don't have stroking geo problem.
 		// TESTDOC: Bug #5253 - test[1].pdf
 		CFX_AffineMatrix matrix1, matrix2;
 		if (pObject2Device) {
 			matrix1.a = FXSYS_fabs(pObject2Device->a) > FXSYS_fabs(pObject2Device->b) ?
 					FXSYS_fabs(pObject2Device->a) : FXSYS_fabs(pObject2Device->b);
 			matrix1.d = matrix1.a;//FXSYS_fabs(pObject2Device->c) > FXSYS_fabs(pObject2Device->d) ?
 					//pObject2Device->c : pObject2Device->d;
 			matrix2.Set(pObject2Device->a/matrix1.a, pObject2Device->b/matrix1.a,
 					pObject2Device->c/matrix1.d, pObject2Device->d/matrix1.d,
 					pObject2Device->e, pObject2Device->f);
 		}
 		// build path data
 		CSkia_PathData path_data;
 		path_data.BuildPath(pPathData, &matrix1);
 		path_data.m_PathData.setFillType(SkPath::kWinding_FillType);

 		SkPaint spaint;
 		spaint.setColor(stroke_color);
 		spaint.setStyle(SkPaint::kStroke_Style);
 		spaint.setAntiAlias(TRUE);
 		SkPath dst_path;
 		SkRasterizeStroke(spaint, &dst_path, path_data.m_PathData, &matrix2, pGraphState, matrix1.a, FALSE, 0);
 		spaint.setStyle(SkPaint::kFill_Style);
 		int fill_flag = FXGETFLAG_COLORTYPE(alpha_flag)<<8 | FXGETFLAG_ALPHA_STROKE(alpha_flag);

 		if (!RenderRasterizerSkia(dst_path, spaint, rect, stroke_color, fill_mode & FXFILL_FULLCOVER, FALSE, fill_flag, pIccTransform, FALSE))
 			return FALSE;

 	}

 	return TRUE;
 }

 FX_BOOL CFX_SkiaDeviceDriver::SetPixel(int x, int y, FX_DWORD color,
 						int alpha_flag, void* pIccTransform)
 {
 	return m_pAggDriver->SetPixel(x, y, color, alpha_flag, pIccTransform);
 }

 FX_BOOL CFX_SkiaDeviceDriver::FillRect(const FX_RECT* pRect, FX_DWORD fill_color, int alpha_flag, void* pIccTransform)
 {
 	return m_pAggDriver->FillRect(pRect, fill_color, alpha_flag, pIccTransform);
 }

 FX_BOOL CFX_SkiaDeviceDriver::GetClipBox(FX_RECT* pRect)
 {
 	return m_pAggDriver->GetClipBox(pRect);
 }

 FX_BOOL	CFX_SkiaDeviceDriver::GetDIBits(CFX_DIBitmap* pBitmap, int left, int top, void* pIccTransform, FX_BOOL bDEdge)
 {
 	return m_pAggDriver->GetDIBits(pBitmap, left, top, pIccTransform, bDEdge);
 }

 FX_BOOL	CFX_SkiaDeviceDriver::SetDIBits(const CFX_DIBSource* pBitmap, FX_DWORD argb, const FX_RECT* pSrcRect, int left, int top, int blend_type,
 									   int alpha_flag, void* pIccTransform)
 {
 	return m_pAggDriver->SetDIBits(pBitmap, argb, pSrcRect, left, top, blend_type, alpha_flag, pIccTransform);
 }

 FX_BOOL	CFX_SkiaDeviceDriver::StretchDIBits(const CFX_DIBSource* pSource, FX_DWORD argb, int dest_left, int dest_top,
 							int dest_width, int dest_height, const FX_RECT* pClipRect, FX_DWORD flags,
 							int alpha_flag, void* pIccTransform)
 {
 	return m_pAggDriver->StretchDIBits(pSource, argb, dest_left, dest_top,
 							dest_width, dest_height, pClipRect, flags,
 							alpha_flag, pIccTransform);
 }

 FX_BOOL	CFX_SkiaDeviceDriver::StartDIBits(const CFX_DIBSource* pSource, int bitmap_alpha, FX_DWORD argb,
 						const CFX_AffineMatrix* pMatrix, FX_DWORD render_flags, void*& handle,
 						int alpha_flag, void* pIccTransform)
 {
 	return m_pAggDriver->StartDIBits(pSource, bitmap_alpha, argb,
 						pMatrix, render_flags, handle, alpha_flag, pIccTransform);
 }

 FX_BOOL	CFX_SkiaDeviceDriver::ContinueDIBits(void* pHandle, IFX_Pause* pPause)
 {
 	return m_pAggDriver->ContinueDIBits(pHandle, pPause);
 }

 void CFX_SkiaDeviceDriver::CancelDIBits(void* pHandle)
 {
 	m_pAggDriver->CancelDIBits(pHandle);
 }

 CFX_SkiaDevice::CFX_SkiaDevice()
 {
 	m_bOwnedBitmap = FALSE;
 }

 FX_BOOL CFX_SkiaDevice::Attach(CFX_DIBitmap* pBitmap, int dither_bits, FX_BOOL bRgbByteOrder, CFX_DIBitmap* pOriDevice, FX_BOOL bGroupKnockout)
 {
 	if (pBitmap == NULL)
 		return FALSE;
 	SetBitmap(pBitmap);
 	CFX_SkiaDeviceDriver* pDriver = new CFX_SkiaDeviceDriver(pBitmap, dither_bits, bRgbByteOrder, pOriDevice, bGroupKnockout);
 	SetDeviceDriver(pDriver);
 	return TRUE;
 }

 FX_BOOL CFX_SkiaDevice::Create(int width, int height, FXDIB_Format format, int dither_bits, CFX_DIBitmap* pOriDevice)
 {
 	m_bOwnedBitmap = TRUE;
 	CFX_DIBitmap* pBitmap = new CFX_DIBitmap;
 	if (!pBitmap->Create(width, height, format)) {
 		delete pBitmap;
 		return FALSE;
 	}
 	SetBitmap(pBitmap);
 	CFX_SkiaDeviceDriver* pDriver =  new CFX_SkiaDeviceDriver(pBitmap, dither_bits, FALSE, pOriDevice, FALSE);
 	SetDeviceDriver(pDriver);
 	return TRUE;
 }
 CFX_SkiaDevice::~CFX_SkiaDevice()
 {
 	if (m_bOwnedBitmap && GetBitmap()) delete GetBitmap();
 }

 #endif
	// Copyright 2014 PDFium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "../../../include/fxge/fx_ge.h"
	//#define _SKIA_SUPPORT_
	#if defined(_SKIA_SUPPORT_)
	#include "../../../include/fxcodec/fx_codec.h"


	//#define _FOXIT_DEBUG_
	//#define _FOXIT_BENCHMARK_

	extern "C" {
	extern void FX_OUTPUT_LOG_FUNC(const char*, ...);
	extern int FX_GET_TICK_FUNC();
	};

	#ifdef _FOXIT_DEBUG_
	#define FOXIT_DEBUG1(msg) FX_OUTPUT_LOG_FUNC(msg)
	#define FOXIT_DEBUG2(msg,para) FX_OUTPUT_LOG_FUNC(msg,para)
	#define FOXIT_DEBUG3(msg,para1,para2) FX_OUTPUT_LOG_FUNC(msg,para1,para2)
	#define FOXIT_DEBUG4(msg,para1,para2,para3) FX_OUTPUT_LOG_FUNC(msg,para1,para2,para3)
	#define FOXIT_DEBUG5(msg,para1,para2,para3,param4) FX_OUTPUT_LOG_FUNC(msg,para1,para2,para3,param4)
	#else
	#define FOXIT_DEBUG1(msg)
	#define FOXIT_DEBUG2(msg,para)
	#define FOXIT_DEBUG3(msg,para1,para2)
	#define FOXIT_DEBUG4(msg,para1,para2,para3)
	#define FOXIT_DEBUG5(msg,para1,para2,para3,param4)
	#endif

	#include "SkDashPathEffect.h"
	#include "SkTLazy.h"
	#include "SkScan.h"
	#include "SkRasterClip.h"
	#include "SkStroke.h"


	#include "fx_skia_blitter_new.h"
	#include "../agg/fx_agg_driver.h"
	#include "fx_skia_device.h"
	/// Run-length-encoded supersampling antialiased blitter.
	class SuperBlitter_skia
	{
	public:
	static void DrawPath(const SkPath& srcPath, SkBlitter* blitter, const SkRasterClip& rect, const SkPaint& origPaint);
	};
	FX_BOOL FxSkDrawTreatAsHairline(const SkPaint& paint, SkScalar* coverage) {
	if (SkPaint::kStroke_Style != paint.getStyle())
	return FALSE;
	FXSYS_assert(coverage);
	SkScalar strokeWidth = paint.getStrokeWidth();
	if (0 == strokeWidth) {
	*coverage = SK_Scalar1;
	return TRUE;
	}
	// if we get here, we need to try to fake a thick-stroke with a modulated
	// hairline
	if (!paint.isAntiAlias())
	return FALSE;
	if (strokeWidth <= SK_Scalar1) {
	*coverage = strokeWidth;
	return TRUE;
	}
	return FALSE;
	}

	void SuperBlitter_skia::DrawPath(const SkPath& srcPath, SkBlitter* blitter, const SkRasterClip& rect, const SkPaint& origPaint)
	{
	SkPath* pathPtr = (SkPath*)&srcPath;
	bool doFill = true;
	SkPath tmpPath;
	SkTCopyOnFirstWrite<SkPaint> paint(origPaint);
	{
	SkScalar coverage;
	if (FxSkDrawTreatAsHairline(origPaint, &coverage)) {
	if (SK_Scalar1 == coverage) {
	paint.writable()->setStrokeWidth(0);
	} else if (1) {//xfermodeSupportsCoverageAsAlpha(xfer), we not use blend mode here, xfer aways NULL.
	U8CPU newAlpha;
	// this is the old technique, which we preserve for now so
	// we don't change previous results (testing)
	// the new way seems fine, its just (a tiny bit) different
	int scale = (int)SkScalarMul(coverage, 256);
	newAlpha = origPaint.getAlpha() * scale >> 8;
	SkPaint* writablePaint = paint.writable();
	writablePaint->setStrokeWidth(0);
	writablePaint->setAlpha(newAlpha);
	}
	}
	}
	if (paint->getPathEffect() \|\| paint->getStyle() != SkPaint::kFill_Style) {
	SkIRect devBounds = rect.getBounds();
	// outset to have slop for antialasing and hairlines
	devBounds.outset(1, 1);
	SkRect cullRect = SkRect::Make(devBounds);
	doFill = paint->getFillPath(*pathPtr, &tmpPath, &cullRect);
	pathPtr = &tmpPath;
	}
	// avoid possibly allocating a new path in transform if we can
	SkPath* devPathPtr = pathPtr;
	void (proc)(const SkPath&, const SkRasterClip&, SkBlitter);
	if (doFill) {
	if (paint->isAntiAlias()) {
	proc = SkScan::AntiFillPath;
	} else {
	proc = SkScan::FillPath;
	}
	} else { // hairline
	if (paint->isAntiAlias()) {
	proc = SkScan::AntiHairPath;
	} else {
	proc = SkScan::HairPath;
	}
	}
	proc(*devPathPtr, rect, blitter);
	}

	class CSkia_PathData
	{
	public:
	CSkia_PathData() {}
	~CSkia_PathData() {}
	SkPath m_PathData;

	void BuildPath(const CFX_PathData* pPathData, const CFX_AffineMatrix* pObject2Device);
	};

	void CSkia_PathData::BuildPath(const CFX_PathData* pPathData, const CFX_AffineMatrix* pObject2Device)
	{
	const CFX_PathData* pFPath = pPathData;
	int nPoints = pFPath->GetPointCount();
	FX_PATHPOINT* pPoints = pFPath->GetPoints();
	for (int i = 0; i < nPoints; i ++) {
	FX_FIXFLOAT x = pPoints[i].m_PointX, y = pPoints[i].m_PointY;
	if (pObject2Device) pObject2Device->Transform(x, y);
	int point_type = pPoints[i].m_Flag & FXPT_TYPE;
	if (point_type == FXPT_MOVETO) {
	m_PathData.moveTo(x, y);
	} else if (point_type == FXPT_LINETO) {
	if (pPoints[i-1].m_Flag == FXPT_MOVETO && (i == nPoints-1 \|\| pPoints[i+1].m_Flag == FXPT_MOVETO) &&
	FXSYS_abs(pPoints[i].m_PointX - pPoints[i-1].m_PointX) < 0.4f && FXSYS_abs(pPoints[i].m_PointY - pPoints[i-1].m_PointY)< 0.4f)
	// PDF line includes the destination point, unlike Windows line.
	// We received some PDF which actually draws zero length lines. TESTDOC: summer cha show.pdf
	// Therefore, we have to extend the line by 0.4 pixel here.
	// But only for standalone segment. TESTDOC: bug #1434 - maze.pdf; TESTDOC: bug#1508 di704P_QIG_111.pdf
	x += 0.4;
	// TODO: we should actually tell skia vertex generator to process zero length stroked line
	// (only butts are drawn)
	m_PathData.lineTo(x, y);
	} else if (point_type == FXPT_BEZIERTO) {
	FX_FIXFLOAT x2 = pPoints[i+1].m_PointX, y2 = pPoints[i+1].m_PointY;
	FX_FIXFLOAT x3 = pPoints[i+2].m_PointX, y3 = pPoints[i+2].m_PointY;
	if (pObject2Device){
	pObject2Device->Transform(x2, y2);
	pObject2Device->Transform(x3, y3);
	}
	m_PathData.cubicTo(x, y, x2, y2, x3, y3);
	i += 2;
	}
	if (pPoints[i].m_Flag & FXPT_CLOSEFIGURE) m_PathData.close();
	}
	}

	// convert a stroking path to scanlines
	static void SkRasterizeStroke(SkPaint& spaint, SkPath* dstPathData, SkPath& path_data,
	const CFX_AffineMatrix* pObject2Device,
	const CFX_GraphStateData* pGraphState, FX_FIXFLOAT scale = FIX8_ONE,
	FX_BOOL bStrokeAdjust = FALSE, FX_BOOL bTextMode = FALSE)
	{
	SkPaint::Cap cap;
	switch (pGraphState->m_LineCap) {
	case CFX_GraphStateData::LineCapRound:
	cap = SkPaint::kRound_Cap;
	break;
	case CFX_GraphStateData::LineCapSquare:
	cap = SkPaint::kSquare_Cap;
	break;
	default:
	cap = SkPaint::kButt_Cap;
	break;
	}
	SkPaint::Join join;
	switch (pGraphState->m_LineJoin) {
	case CFX_GraphStateData::LineJoinRound:
	join = SkPaint::kRound_Join;
	break;
	case CFX_GraphStateData::LineJoinBevel:
	join = SkPaint::kBevel_Join;
	break;
	default:
	join = SkPaint::kMiter_Join;
	break;
	}
	FX_FIXFLOAT width = pGraphState->m_LineWidth*scale;
	FX_FIXFLOAT unit = fix32_to_8(fixdiv_8_8_to_32(FIX8_ONE, (pObject2Device->GetXUnit() + pObject2Device->GetYUnit()) / 2));
	if (width <= unit) width = unit;

	if (pGraphState->m_DashArray == NULL) {
	SkStroke stroker;
	stroker.setCap(cap);
	stroker.setJoin(join);
	stroker.setMiterLimit(pGraphState->m_MiterLimit);
	stroker.setWidth(width);
	stroker.setDoFill(FALSE);
	stroker.strokePath(path_data, dstPathData);
	SkMatrix smatrix;
	smatrix.setAll(pObject2Device->a, pObject2Device->c, pObject2Device->e, pObject2Device->b, pObject2Device->d, pObject2Device->f, 0, 0, 1);
	dstPathData->transform(smatrix);
	} else {
	int count = (pGraphState->m_DashCount+1)/2;
	SkScalar* intervals = FX_Alloc2D(SkScalar, count, sizeof(SkScalar));
	// Set dash pattern
	for (int i = 0; i < count; i ++) {
	FX_FIXFLOAT on = pGraphState->m_DashArray[i*2];
	if (on <= 0.000001f) on = FIX8_ONE/10;
	FX_FIXFLOAT off = i*2+1 == pGraphState->m_DashCount ? on :
	pGraphState->m_DashArray[i*2+1];
	if (off < 0) off = 0;
	intervals[i2]=onscale;
	intervals[i2+1]=offscale;
	}
	SkDashPathEffect* pEffect = new SkDashPathEffect(intervals,count2, pGraphState->m_DashPhasescale);
	spaint.setPathEffect(pEffect)->unref();
	spaint.setStrokeWidth(width);
	spaint.setStrokeMiter(pGraphState->m_MiterLimit);
	spaint.setStrokeCap(cap);
	spaint.setStrokeJoin(join);
	spaint.getFillPath(path_data, dstPathData);
	SkMatrix smatrix;
	smatrix.setAll(pObject2Device->a, pObject2Device->c, pObject2Device->e, pObject2Device->b, pObject2Device->d, pObject2Device->f, 0, 0, 1);
	dstPathData->transform(smatrix);
	FX_Free(intervals);
	}
	}

	CFX_SkiaDeviceDriver::CFX_SkiaDeviceDriver(CFX_DIBitmap* pBitmap, int dither_bits, FX_BOOL bRgbByteOrder, CFX_DIBitmap* pOriDevice, FX_BOOL bGroupKnockout)
	{
	m_pAggDriver = new CFX_AggDeviceDriver(pBitmap, dither_bits, bRgbByteOrder, pOriDevice, bGroupKnockout);
	}
	CFX_SkiaDeviceDriver::~CFX_SkiaDeviceDriver()
	{
	delete m_pAggDriver;
	}
	FX_BOOL CFX_SkiaDeviceDriver::DrawDeviceText(int nChars, const FXTEXT_CHARPOS* pCharPos, CFX_Font* pFont,
	CFX_FontCache* pCache, const CFX_AffineMatrix* pObject2Device, FX_FIXFLOAT font_size, FX_DWORD color,
	int alpha_flag, void* pIccTransform)
	{
	return m_pAggDriver->DrawDeviceText(nChars, pCharPos, pFont,pCache, pObject2Device, font_size, color,
	alpha_flag, pIccTransform);
	}
	int CFX_SkiaDeviceDriver::GetDeviceCaps(int caps_id)
	{
	return m_pAggDriver->GetDeviceCaps(caps_id);
	}
	void CFX_SkiaDeviceDriver::SaveState()
	{
	m_pAggDriver->SaveState();
	}

	void CFX_SkiaDeviceDriver::RestoreState(FX_BOOL bKeepSaved)
	{
	m_pAggDriver->RestoreState(bKeepSaved);
	}
	void CFX_SkiaDeviceDriver::SetClipMask(rasterizer_scanline_aa& rasterizer)
	{
	m_pAggDriver->SetClipMask(rasterizer);
	}
	void CFX_SkiaDeviceDriver::SetClipMask(SkPath& skPath, SkPaint* spaint)
	{
	SkIRect clip_box;
	clip_box.set(0, 0, fix0_to_8(GetDeviceCaps(FXDC_PIXEL_WIDTH)), fix0_to_8(GetDeviceCaps(FXDC_PIXEL_HEIGHT)));
	clip_box.intersect(m_pAggDriver->m_pClipRgn->GetBox().left, m_pAggDriver->m_pClipRgn->GetBox().top,
	m_pAggDriver->m_pClipRgn->GetBox().right, m_pAggDriver->m_pClipRgn->GetBox().bottom);

	SkPath* pathPtr = &skPath;

	SkRect path_rect = skPath.getBounds();

	clip_box.intersect(FXSYS_floor(path_rect.fLeft), FXSYS_floor(path_rect.fTop), FXSYS_floor(path_rect.fRight)+1, FXSYS_floor(path_rect.fBottom)+1);
	CFX_DIBitmapRef mask;
	CFX_DIBitmap* pThisLayer = mask.New();
	pThisLayer->Create(clip_box.width(), clip_box.height(), FXDIB_8bppMask);
	pThisLayer->Clear(0);

	CFX_SkiaA8Renderer render;
	render.Init(pThisLayer, clip_box.fLeft, clip_box.fTop);

	SkRasterClip rasterClip(clip_box);
	SuperBlitter_skia::DrawPath(skPath, (SkBlitter)&render, rasterClip, spaint);

	// Finally, we have got the mask that we need, intersect with current clip region
	m_pAggDriver->m_pClipRgn->IntersectMaskF(clip_box.fLeft, clip_box.fTop, mask);

	}
	FX_BOOL CFX_SkiaDeviceDriver::SetClip_PathFill(const CFX_PathData* pPathData, // path info
	const CFX_AffineMatrix* pObject2Device, // optional transformation
	int fill_mode // fill mode, WINDING or ALTERNATE
	)
	{
	if (m_pAggDriver->m_pClipRgn == NULL)
	m_pAggDriver->m_pClipRgn = new CFX_ClipRgn(GetDeviceCaps(FXDC_PIXEL_WIDTH), GetDeviceCaps(FXDC_PIXEL_HEIGHT));

	if (pPathData->GetPointCount() == 5 \|\| pPathData->GetPointCount() == 4) {
	CFX_FloatRect rectf;
	if (pPathData->IsRect(pObject2Device, &rectf)) {
	rectf.Intersect(CFX_FloatRect(0, 0, (FX_FIXFLOAT)GetDeviceCaps(FXDC_PIXEL_WIDTH), (FX_FIXFLOAT)GetDeviceCaps(FXDC_PIXEL_HEIGHT)));
	FX_RECT rect = rectf.GetOutterRect();
	m_pAggDriver->m_pClipRgn->IntersectRect(rect);
	return TRUE;
	}
	}
	CSkia_PathData path_data;
	path_data.BuildPath(pPathData, pObject2Device);
	path_data.m_PathData.close();
	path_data.m_PathData.setFillType((fill_mode&3) == FXFILL_WINDING? SkPath::kWinding_FillType:SkPath::kEvenOdd_FillType);

	SkPaint spaint;
	spaint.setColor(0xffffffff);
	spaint.setAntiAlias(TRUE);
	spaint.setStyle(SkPaint::kFill_Style);

	SetClipMask(path_data.m_PathData, &spaint);

	return TRUE;
	}

	FX_BOOL CFX_SkiaDeviceDriver::SetClip_PathStroke(const CFX_PathData* pPathData, // path info
	const CFX_AffineMatrix* pObject2Device, // optional transformation
	const CFX_GraphStateData* pGraphState // graphic state, for pen attributes
	)
	{
	if (m_pAggDriver->m_pClipRgn == NULL)
	m_pAggDriver->m_pClipRgn = new CFX_ClipRgn(GetDeviceCaps(FXDC_PIXEL_WIDTH), GetDeviceCaps(FXDC_PIXEL_HEIGHT));

	// build path data
	CSkia_PathData path_data;
	path_data.BuildPath(pPathData, NULL);
	path_data.m_PathData.setFillType(SkPath::kWinding_FillType);

	SkPaint spaint;
	spaint.setColor(0xffffffff);
	spaint.setStyle(SkPaint::kStroke_Style);
	spaint.setAntiAlias(TRUE);

	SkPath dst_path;
	SkRasterizeStroke(spaint, &dst_path, path_data.m_PathData, pObject2Device, pGraphState, 1, FALSE, 0);
	spaint.setStyle(SkPaint::kFill_Style);
	SetClipMask(dst_path, &spaint);

	return TRUE;
	}
	FX_BOOL CFX_SkiaDeviceDriver::RenderRasterizer(rasterizer_scanline_aa& rasterizer, FX_DWORD color, FX_BOOL bFullCover, FX_BOOL bGroupKnockout,
	int alpha_flag, void* pIccTransform)
	{
	return m_pAggDriver->RenderRasterizer(rasterizer, color, bFullCover, bGroupKnockout,alpha_flag, pIccTransform);
	}
	FX_BOOL CFX_SkiaDeviceDriver::RenderRasterizerSkia(SkPath& skPath, const SkPaint& origPaint, SkIRect& rect, FX_DWORD color, FX_BOOL bFullCover, FX_BOOL bGroupKnockout,
	int alpha_flag, void* pIccTransform, FX_BOOL bFill)
	{
	CFX_DIBitmap* pt = bGroupKnockout?m_pAggDriver->GetBackDrop():NULL;
	CFX_SkiaRenderer render;
	if (!render.Init(m_pAggDriver->m_pBitmap, pt, m_pAggDriver->m_pClipRgn, color, bFullCover, m_pAggDriver->m_bRgbByteOrder, alpha_flag, pIccTransform))
	return FALSE;

	SkRasterClip rasterClip(rect);
	SuperBlitter_skia::DrawPath(skPath, (SkBlitter*)&render, rasterClip, origPaint);

	return TRUE;

	}

	FX_BOOL CFX_SkiaDeviceDriver::DrawPath(const CFX_PathData* pPathData, // path info
	const CFX_AffineMatrix* pObject2Device, // optional transformation
	const CFX_GraphStateData* pGraphState, // graphic state, for pen attributes
	FX_DWORD fill_color, // fill color
	FX_DWORD stroke_color, // stroke color
	int fill_mode, // fill mode, WINDING or ALTERNATE. 0 for not filled
	int alpha_flag,
	void* pIccTransform
	)
	{
	if (GetBuffer() == NULL) return TRUE;
	FOXIT_DEBUG1("CFX_SkiaDeviceDriver::DrawPath: entering");
	SkIRect rect;
	rect.set(0, 0, GetDeviceCaps(FXDC_PIXEL_WIDTH), GetDeviceCaps(FXDC_PIXEL_HEIGHT));
	if ((fill_mode & 3) && fill_color) {
	// We have to transform before building path data, otherwise we'll have flatting problem
	// when we enlarge a small path (flatten before transformed)
	// TESTDOC: Bug #5115 - DS_S1Dimpact_lr.pdf
	// build path data
	CSkia_PathData path_data;
	path_data.BuildPath(pPathData, pObject2Device);
	//path_data.m_PathData.close();
	path_data.m_PathData.setFillType((fill_mode&3) == FXFILL_WINDING? SkPath::kWinding_FillType:SkPath::kEvenOdd_FillType);

	SkPaint spaint;
	spaint.setAntiAlias(TRUE);
	spaint.setStyle(SkPaint::kFill_Style);
	spaint.setColor(fill_color);
	if (!RenderRasterizerSkia(path_data.m_PathData, spaint, rect, fill_color, fill_mode & FXFILL_FULLCOVER, FALSE, alpha_flag, pIccTransform))
	return FALSE;
	}

	int stroke_alpha = FXGETFLAG_COLORTYPE(alpha_flag) ? FXGETFLAG_ALPHA_STROKE(alpha_flag) : FXARGB_A(stroke_color);

	if (pGraphState && stroke_alpha) {
	// We split the matrix into two parts: first part doing the scaling, so we won't have the
	// flatness problem, second part doing the transformation, so we don't have stroking geo problem.
	// TESTDOC: Bug #5253 - test[1].pdf
	CFX_AffineMatrix matrix1, matrix2;
	if (pObject2Device) {
	matrix1.a = FXSYS_fabs(pObject2Device->a) > FXSYS_fabs(pObject2Device->b) ?
	FXSYS_fabs(pObject2Device->a) : FXSYS_fabs(pObject2Device->b);
	matrix1.d = matrix1.a;//FXSYS_fabs(pObject2Device->c) > FXSYS_fabs(pObject2Device->d) ?
	//pObject2Device->c : pObject2Device->d;
	matrix2.Set(pObject2Device->a/matrix1.a, pObject2Device->b/matrix1.a,
	pObject2Device->c/matrix1.d, pObject2Device->d/matrix1.d,
	pObject2Device->e, pObject2Device->f);
	}
	// build path data
	CSkia_PathData path_data;
	path_data.BuildPath(pPathData, &matrix1);
	path_data.m_PathData.setFillType(SkPath::kWinding_FillType);

	SkPaint spaint;
	spaint.setColor(stroke_color);
	spaint.setStyle(SkPaint::kStroke_Style);
	spaint.setAntiAlias(TRUE);
	SkPath dst_path;
	SkRasterizeStroke(spaint, &dst_path, path_data.m_PathData, &matrix2, pGraphState, matrix1.a, FALSE, 0);
	spaint.setStyle(SkPaint::kFill_Style);
	int fill_flag = FXGETFLAG_COLORTYPE(alpha_flag)<<8 \| FXGETFLAG_ALPHA_STROKE(alpha_flag);

	if (!RenderRasterizerSkia(dst_path, spaint, rect, stroke_color, fill_mode & FXFILL_FULLCOVER, FALSE, fill_flag, pIccTransform, FALSE))
	return FALSE;

	}

	return TRUE;
	}

	FX_BOOL CFX_SkiaDeviceDriver::SetPixel(int x, int y, FX_DWORD color,
	int alpha_flag, void* pIccTransform)
	{
	return m_pAggDriver->SetPixel(x, y, color, alpha_flag, pIccTransform);
	}

	FX_BOOL CFX_SkiaDeviceDriver::FillRect(const FX_RECT* pRect, FX_DWORD fill_color, int alpha_flag, void* pIccTransform)
	{
	return m_pAggDriver->FillRect(pRect, fill_color, alpha_flag, pIccTransform);
	}

	FX_BOOL CFX_SkiaDeviceDriver::GetClipBox(FX_RECT* pRect)
	{
	return m_pAggDriver->GetClipBox(pRect);
	}

	FX_BOOL CFX_SkiaDeviceDriver::GetDIBits(CFX_DIBitmap* pBitmap, int left, int top, void* pIccTransform, FX_BOOL bDEdge)
	{
	return m_pAggDriver->GetDIBits(pBitmap, left, top, pIccTransform, bDEdge);
	}

	FX_BOOL CFX_SkiaDeviceDriver::SetDIBits(const CFX_DIBSource* pBitmap, FX_DWORD argb, const FX_RECT* pSrcRect, int left, int top, int blend_type,
	int alpha_flag, void* pIccTransform)
	{
	return m_pAggDriver->SetDIBits(pBitmap, argb, pSrcRect, left, top, blend_type, alpha_flag, pIccTransform);
	}

	FX_BOOL CFX_SkiaDeviceDriver::StretchDIBits(const CFX_DIBSource* pSource, FX_DWORD argb, int dest_left, int dest_top,
	int dest_width, int dest_height, const FX_RECT* pClipRect, FX_DWORD flags,
	int alpha_flag, void* pIccTransform)
	{
	return m_pAggDriver->StretchDIBits(pSource, argb, dest_left, dest_top,
	dest_width, dest_height, pClipRect, flags,
	alpha_flag, pIccTransform);
	}

	FX_BOOL CFX_SkiaDeviceDriver::StartDIBits(const CFX_DIBSource* pSource, int bitmap_alpha, FX_DWORD argb,
	const CFX_AffineMatrix* pMatrix, FX_DWORD render_flags, void*& handle,
	int alpha_flag, void* pIccTransform)
	{
	return m_pAggDriver->StartDIBits(pSource, bitmap_alpha, argb,
	pMatrix, render_flags, handle, alpha_flag, pIccTransform);
	}

	FX_BOOL CFX_SkiaDeviceDriver::ContinueDIBits(void* pHandle, IFX_Pause* pPause)
	{
	return m_pAggDriver->ContinueDIBits(pHandle, pPause);
	}

	void CFX_SkiaDeviceDriver::CancelDIBits(void* pHandle)
	{
	m_pAggDriver->CancelDIBits(pHandle);
	}

	CFX_SkiaDevice::CFX_SkiaDevice()
	{
	m_bOwnedBitmap = FALSE;
	}

	FX_BOOL CFX_SkiaDevice::Attach(CFX_DIBitmap* pBitmap, int dither_bits, FX_BOOL bRgbByteOrder, CFX_DIBitmap* pOriDevice, FX_BOOL bGroupKnockout)
	{
	if (pBitmap == NULL)
	return FALSE;
	SetBitmap(pBitmap);
	CFX_SkiaDeviceDriver* pDriver = new CFX_SkiaDeviceDriver(pBitmap, dither_bits, bRgbByteOrder, pOriDevice, bGroupKnockout);
	SetDeviceDriver(pDriver);
	return TRUE;
	}

	FX_BOOL CFX_SkiaDevice::Create(int width, int height, FXDIB_Format format, int dither_bits, CFX_DIBitmap* pOriDevice)
	{
	m_bOwnedBitmap = TRUE;
	CFX_DIBitmap* pBitmap = new CFX_DIBitmap;
	if (!pBitmap->Create(width, height, format)) {
	delete pBitmap;
	return FALSE;
	}
	SetBitmap(pBitmap);
	CFX_SkiaDeviceDriver* pDriver = new CFX_SkiaDeviceDriver(pBitmap, dither_bits, FALSE, pOriDevice, FALSE);
	SetDeviceDriver(pDriver);
	return TRUE;
	}
	CFX_SkiaDevice::~CFX_SkiaDevice()
	{
	if (m_bOwnedBitmap && GetBitmap()) delete GetBitmap();
	}

	#endif