src/gpu/GrPath.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "GrPath.h"

 namespace {
 // Verb count limit for generating path key from content of a volatile path.
 // The value should accomodate at least simple rects and rrects.
 static const int kSimpleVolatilePathVerbLimit = 10;

 inline static bool compute_key_for_line_path(const SkPath& path, const GrStrokeInfo& stroke,
                                              GrUniqueKey* key) {
     SkPoint pts[2];
     if (!path.isLine(pts)) {
         return false;
     }
     static_assert((sizeof(pts) % sizeof(uint32_t)) == 0 && sizeof(pts) > sizeof(uint32_t),
                   "pts_needs_padding");

     const int kBaseData32Cnt = 1 + sizeof(pts) / sizeof(uint32_t);
     int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
     static const GrUniqueKey::Domain kOvalPathDomain = GrUniqueKey::GenerateDomain();
     GrUniqueKey::Builder builder(key, kOvalPathDomain, kBaseData32Cnt + strokeDataCnt);
     builder[0] = path.getFillType();
     memcpy(&builder[1], &pts, sizeof(pts));
     if (strokeDataCnt > 0) {
         stroke.asUniqueKeyFragment(&builder[kBaseData32Cnt]);
     }
     return true;
 }

 inline static bool compute_key_for_oval_path(const SkPath& path, const GrStrokeInfo& stroke,
                                              GrUniqueKey* key) {
     SkRect rect;
     if (!path.isOval(&rect)) {
         return false;
     }
     static_assert((sizeof(rect) % sizeof(uint32_t)) == 0 && sizeof(rect) > sizeof(uint32_t),
                   "rect_needs_padding");

     const int kBaseData32Cnt = 1 + sizeof(rect) / sizeof(uint32_t);
     int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
     static const GrUniqueKey::Domain kOvalPathDomain = GrUniqueKey::GenerateDomain();
     GrUniqueKey::Builder builder(key, kOvalPathDomain, kBaseData32Cnt + strokeDataCnt);
     builder[0] = path.getFillType();
     memcpy(&builder[1], &rect, sizeof(rect));
     if (strokeDataCnt > 0) {
         stroke.asUniqueKeyFragment(&builder[kBaseData32Cnt]);
     }
     return true;
 }

 // Encodes the full path data to the unique key for very small, volatile paths. This is typically
 // hit when clipping stencils the clip stack. Intention is that this handles rects too, since
 // SkPath::isRect seems to do non-trivial amount of work.
 inline static bool compute_key_for_simple_path(const SkPath& path, const GrStrokeInfo& stroke,
                                                GrUniqueKey* key) {
     if (!path.isVolatile()) {
         return false;
     }
     // The check below should take care of negative values casted positive.
     const int verbCnt = path.countVerbs();
     if (verbCnt > kSimpleVolatilePathVerbLimit) {
         return false;
     }

     // If somebody goes wild with the constant, it might cause an overflow.
     static_assert(kSimpleVolatilePathVerbLimit <= 100,
                   "big_simple_volatile_path_verb_limit_may_cause_overflow");

     const int pointCnt = path.countPoints();
     if (pointCnt < 0) {
         SkASSERT(false);
         return false;
     }

     // Construct counts that align as uint32_t counts.
 #define ARRAY_DATA32_COUNT(array_type, count) \
     static_cast<int>((((count) * sizeof(array_type) + sizeof(uint32_t) - 1) / sizeof(uint32_t)))

     const int verbData32Cnt = ARRAY_DATA32_COUNT(uint8_t, verbCnt);
     const int pointData32Cnt = ARRAY_DATA32_COUNT(SkPoint, pointCnt);

 #undef ARRAY_DATA32_COUNT

     // The unique key data is a "message" with following fragments:
     // 0) domain, key length, uint32_t for fill type and uint32_t for verbCnt
     //   (fragment 0, fixed size)
     // 1) verb and point data (varying size)
     // 2) stroke data (varying size)

     const int baseData32Cnt = 2 + verbData32Cnt + pointData32Cnt;
     const int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
     static const GrUniqueKey::Domain kSimpleVolatilePathDomain = GrUniqueKey::GenerateDomain();
     GrUniqueKey::Builder builder(key, kSimpleVolatilePathDomain, baseData32Cnt + strokeDataCnt);
     int i = 0;
     builder[i++] = path.getFillType();

     // Serialize the verbCnt to make the whole message unambiguous.
     // We serialize two variable length fragments to the message:
     // * verb and point data (fragment 1)
     // * stroke data (fragment 2)
     // "Proof:"
     // Verb count establishes unambiguous verb data.
     // Unambiguous verb data establishes unambiguous point data, making fragment 1 unambiguous.
     // Unambiguous fragment 1 establishes unambiguous fragment 2, since the length of the message
     // has been established.

     builder[i++] = SkToU32(verbCnt); // The path limit is compile-asserted above, so the cast is ok.

     // Fill the last uint32_t with 0 first, since the last uint8_ts of the uint32_t may be
     // uninitialized. This does not produce ambiguous verb data, since we have serialized the exact
     // verb count.
     if (verbData32Cnt != static_cast<int>((verbCnt * sizeof(uint8_t) / sizeof(uint32_t)))) {
         builder[i + verbData32Cnt - 1] = 0;
     }
     path.getVerbs(reinterpret_cast<uint8_t*>(&builder[i]), verbCnt);
     i += verbData32Cnt;

     static_assert(((sizeof(SkPoint) % sizeof(uint32_t)) == 0) && sizeof(SkPoint) > sizeof(uint32_t),
                   "skpoint_array_needs_padding");

     // Here we assume getPoints does a memcpy, so that we do not need to worry about the alignment.
     path.getPoints(reinterpret_cast<SkPoint*>(&builder[i]), pointCnt);
     SkDEBUGCODE(i += pointData32Cnt);

     SkASSERT(i == baseData32Cnt);
     if (strokeDataCnt > 0) {
         stroke.asUniqueKeyFragment(&builder[baseData32Cnt]);
     }
     return true;
 }

 inline static void compute_key_for_general_path(const SkPath& path, const GrStrokeInfo& stroke,
                                                 GrUniqueKey* key) {
     const int kBaseData32Cnt = 2;
     int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
     static const GrUniqueKey::Domain kGeneralPathDomain = GrUniqueKey::GenerateDomain();
     GrUniqueKey::Builder builder(key, kGeneralPathDomain, kBaseData32Cnt + strokeDataCnt);
     builder[0] = path.getGenerationID();
     builder[1] = path.getFillType();
     if (strokeDataCnt > 0) {
         stroke.asUniqueKeyFragment(&builder[kBaseData32Cnt]);
     }
 }

 }

 void GrPath::ComputeKey(const SkPath& path, const GrStrokeInfo& stroke, GrUniqueKey* key,
                         bool* outIsVolatile) {
     if (compute_key_for_line_path(path, stroke, key)) {
         *outIsVolatile = false;
         return;
     }

     if (compute_key_for_oval_path(path, stroke, key)) {
         *outIsVolatile = false;
         return;
     }

     if (compute_key_for_simple_path(path, stroke, key)) {
         *outIsVolatile = false;
         return;
     }

     compute_key_for_general_path(path, stroke, key);
     *outIsVolatile = path.isVolatile();
 }
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "GrPath.h"

	namespace {
	// Verb count limit for generating path key from content of a volatile path.
	// The value should accomodate at least simple rects and rrects.
	static const int kSimpleVolatilePathVerbLimit = 10;

	inline static bool compute_key_for_line_path(const SkPath& path, const GrStrokeInfo& stroke,
	GrUniqueKey* key) {
	SkPoint pts[2];
	if (!path.isLine(pts)) {
	return false;
	}
	static_assert((sizeof(pts) % sizeof(uint32_t)) == 0 && sizeof(pts) > sizeof(uint32_t),
	"pts_needs_padding");

	const int kBaseData32Cnt = 1 + sizeof(pts) / sizeof(uint32_t);
	int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
	static const GrUniqueKey::Domain kOvalPathDomain = GrUniqueKey::GenerateDomain();
	GrUniqueKey::Builder builder(key, kOvalPathDomain, kBaseData32Cnt + strokeDataCnt);
	builder[0] = path.getFillType();
	memcpy(&builder[1], &pts, sizeof(pts));
	if (strokeDataCnt > 0) {
	stroke.asUniqueKeyFragment(&builder[kBaseData32Cnt]);
	}
	return true;
	}

	inline static bool compute_key_for_oval_path(const SkPath& path, const GrStrokeInfo& stroke,
	GrUniqueKey* key) {
	SkRect rect;
	if (!path.isOval(&rect)) {
	return false;
	}
	static_assert((sizeof(rect) % sizeof(uint32_t)) == 0 && sizeof(rect) > sizeof(uint32_t),
	"rect_needs_padding");

	const int kBaseData32Cnt = 1 + sizeof(rect) / sizeof(uint32_t);
	int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
	static const GrUniqueKey::Domain kOvalPathDomain = GrUniqueKey::GenerateDomain();
	GrUniqueKey::Builder builder(key, kOvalPathDomain, kBaseData32Cnt + strokeDataCnt);
	builder[0] = path.getFillType();
	memcpy(&builder[1], &rect, sizeof(rect));
	if (strokeDataCnt > 0) {
	stroke.asUniqueKeyFragment(&builder[kBaseData32Cnt]);
	}
	return true;
	}

	// Encodes the full path data to the unique key for very small, volatile paths. This is typically
	// hit when clipping stencils the clip stack. Intention is that this handles rects too, since
	// SkPath::isRect seems to do non-trivial amount of work.
	inline static bool compute_key_for_simple_path(const SkPath& path, const GrStrokeInfo& stroke,
	GrUniqueKey* key) {
	if (!path.isVolatile()) {
	return false;
	}
	// The check below should take care of negative values casted positive.
	const int verbCnt = path.countVerbs();
	if (verbCnt > kSimpleVolatilePathVerbLimit) {
	return false;
	}

	// If somebody goes wild with the constant, it might cause an overflow.
	static_assert(kSimpleVolatilePathVerbLimit <= 100,
	"big_simple_volatile_path_verb_limit_may_cause_overflow");

	const int pointCnt = path.countPoints();
	if (pointCnt < 0) {
	SkASSERT(false);
	return false;
	}

	// Construct counts that align as uint32_t counts.
	#define ARRAY_DATA32_COUNT(array_type, count) \
	static_cast<int>((((count) * sizeof(array_type) + sizeof(uint32_t) - 1) / sizeof(uint32_t)))

	const int verbData32Cnt = ARRAY_DATA32_COUNT(uint8_t, verbCnt);
	const int pointData32Cnt = ARRAY_DATA32_COUNT(SkPoint, pointCnt);

	#undef ARRAY_DATA32_COUNT

	// The unique key data is a "message" with following fragments:
	// 0) domain, key length, uint32_t for fill type and uint32_t for verbCnt
	// (fragment 0, fixed size)
	// 1) verb and point data (varying size)
	// 2) stroke data (varying size)

	const int baseData32Cnt = 2 + verbData32Cnt + pointData32Cnt;
	const int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
	static const GrUniqueKey::Domain kSimpleVolatilePathDomain = GrUniqueKey::GenerateDomain();
	GrUniqueKey::Builder builder(key, kSimpleVolatilePathDomain, baseData32Cnt + strokeDataCnt);
	int i = 0;
	builder[i++] = path.getFillType();

	// Serialize the verbCnt to make the whole message unambiguous.
	// We serialize two variable length fragments to the message:
	// * verb and point data (fragment 1)
	// * stroke data (fragment 2)
	// "Proof:"
	// Verb count establishes unambiguous verb data.
	// Unambiguous verb data establishes unambiguous point data, making fragment 1 unambiguous.
	// Unambiguous fragment 1 establishes unambiguous fragment 2, since the length of the message
	// has been established.

	builder[i++] = SkToU32(verbCnt); // The path limit is compile-asserted above, so the cast is ok.

	// Fill the last uint32_t with 0 first, since the last uint8_ts of the uint32_t may be
	// uninitialized. This does not produce ambiguous verb data, since we have serialized the exact
	// verb count.
	if (verbData32Cnt != static_cast<int>((verbCnt * sizeof(uint8_t) / sizeof(uint32_t)))) {
	builder[i + verbData32Cnt - 1] = 0;
	}
	path.getVerbs(reinterpret_cast<uint8_t*>(&builder[i]), verbCnt);
	i += verbData32Cnt;

	static_assert(((sizeof(SkPoint) % sizeof(uint32_t)) == 0) && sizeof(SkPoint) > sizeof(uint32_t),
	"skpoint_array_needs_padding");

	// Here we assume getPoints does a memcpy, so that we do not need to worry about the alignment.
	path.getPoints(reinterpret_cast<SkPoint*>(&builder[i]), pointCnt);
	SkDEBUGCODE(i += pointData32Cnt);

	SkASSERT(i == baseData32Cnt);
	if (strokeDataCnt > 0) {
	stroke.asUniqueKeyFragment(&builder[baseData32Cnt]);
	}
	return true;
	}

	inline static void compute_key_for_general_path(const SkPath& path, const GrStrokeInfo& stroke,
	GrUniqueKey* key) {
	const int kBaseData32Cnt = 2;
	int strokeDataCnt = stroke.computeUniqueKeyFragmentData32Cnt();
	static const GrUniqueKey::Domain kGeneralPathDomain = GrUniqueKey::GenerateDomain();
	GrUniqueKey::Builder builder(key, kGeneralPathDomain, kBaseData32Cnt + strokeDataCnt);
	builder[0] = path.getGenerationID();
	builder[1] = path.getFillType();
	if (strokeDataCnt > 0) {
	stroke.asUniqueKeyFragment(&builder[kBaseData32Cnt]);
	}
	}

	}

	void GrPath::ComputeKey(const SkPath& path, const GrStrokeInfo& stroke, GrUniqueKey* key,
	bool* outIsVolatile) {
	if (compute_key_for_line_path(path, stroke, key)) {
	*outIsVolatile = false;
	return;
	}

	if (compute_key_for_oval_path(path, stroke, key)) {
	*outIsVolatile = false;
	return;
	}

	if (compute_key_for_simple_path(path, stroke, key)) {
	*outIsVolatile = false;
	return;
	}

	compute_key_for_general_path(path, stroke, key);
	*outIsVolatile = path.isVolatile();
	}