src/core/SkGlyph.h - skia - Git at Google

 /*
  * Copyright 2006 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkGlyph_DEFINED
 #define SkGlyph_DEFINED

 #include "SkChecksum.h"
 #include "SkFixed.h"
 #include "SkMask.h"
 #include "SkPath.h"
 #include "SkTo.h"
 #include "SkTypes.h"

 class SkArenaAlloc;
 class SkStrike;
 class SkScalerContext;

 // needs to be != to any valid SkMask::Format
 #define MASK_FORMAT_UNKNOWN         (0xFF)
 #define MASK_FORMAT_JUST_ADVANCE    MASK_FORMAT_UNKNOWN

 #define kMaxGlyphWidth (1<<13)

 /** (glyph-index or unicode-point) + subpixel-pos */
 struct SkPackedID {
     static constexpr uint32_t kImpossibleID = ~0;
     enum {
         kSubBits = 2,
         kSubMask = ((1 << kSubBits) - 1),
         kSubShift = 24, // must be large enough for glyphs and unichars
         kCodeMask = ((1 << kSubShift) - 1),
         // relative offsets for X and Y subpixel bits
         kSubShiftX = kSubBits,
         kSubShiftY = 0
     };

     SkPackedID(uint32_t code) {
         SkASSERT(code <= kCodeMask);
         SkASSERT(code != kImpossibleID);
         fID = code;
     }

     SkPackedID(uint32_t code, SkFixed x, SkFixed y) {
         SkASSERT(code <= kCodeMask);
         x = FixedToSub(x);
         y = FixedToSub(y);
         uint32_t ID = (x << (kSubShift + kSubShiftX)) |
                       (y << (kSubShift + kSubShiftY)) |
                       code;
         SkASSERT(ID != kImpossibleID);
         fID = ID;
     }

     constexpr SkPackedID() : fID(kImpossibleID) {}

     bool operator==(const SkPackedID& that) const {
         return fID == that.fID;
     }
     bool operator!=(const SkPackedID& that) const {
         return !(*this == that);
     }
     bool operator<(SkPackedID that) const {
         return this->fID < that.fID;
     }

     uint32_t code() const {
         return fID & kCodeMask;
     }

     uint32_t value() const {
         return fID;
     }

     SkFixed getSubXFixed() const {
         return SubToFixed(ID2SubX(fID));
     }

     SkFixed getSubYFixed() const {
         return SubToFixed(ID2SubY(fID));
     }

     uint32_t hash() const {
         return SkChecksum::CheapMix(fID);
     }

     SkString dump() const {
         SkString str;
         str.appendf("code: %d, x: %d, y:%d", code(), getSubXFixed(), getSubYFixed());
         return str;
     }

 private:
     static unsigned ID2SubX(uint32_t id) {
         return id >> (kSubShift + kSubShiftX);
     }

     static unsigned ID2SubY(uint32_t id) {
         return (id >> (kSubShift + kSubShiftY)) & kSubMask;
     }

     static unsigned FixedToSub(SkFixed n) {
         return (n >> (16 - kSubBits)) & kSubMask;
     }

     static SkFixed SubToFixed(unsigned sub) {
         SkASSERT(sub <= kSubMask);
         return sub << (16 - kSubBits);
     }

     uint32_t fID;
 };

 struct SkPackedGlyphID : public SkPackedID {
     SkPackedGlyphID(SkGlyphID code) : SkPackedID(code) { }
     SkPackedGlyphID(SkGlyphID code, SkFixed x, SkFixed y) : SkPackedID(code, x, y) { }
     SkPackedGlyphID(SkGlyphID code, SkIPoint pt) : SkPackedID(code, pt.x(), pt.y()) { }
     constexpr SkPackedGlyphID() = default;
     SkGlyphID code() const {
         return SkTo<SkGlyphID>(SkPackedID::code());
     }
 };

 class SkGlyph {
     struct PathData;

 public:
     constexpr explicit SkGlyph(SkPackedGlyphID id) : fID{id} {}
     static constexpr SkFixed kSubpixelRound = SK_FixedHalf >> SkPackedID::kSubBits;

     bool isEmpty() const { return fWidth == 0 || fHeight == 0; }
     bool isJustAdvance() const { return MASK_FORMAT_JUST_ADVANCE == fMaskFormat; }
     bool isFullMetrics() const { return MASK_FORMAT_JUST_ADVANCE != fMaskFormat; }
     SkGlyphID getGlyphID() const { return fID.code(); }
     SkPackedGlyphID getPackedID() const { return fID; }
     SkFixed getSubXFixed() const { return fID.getSubXFixed(); }
     SkFixed getSubYFixed() const { return fID.getSubYFixed(); }

     size_t formatAlignment() const;
     size_t allocImage(SkArenaAlloc* alloc);
     size_t rowBytes() const;
     size_t computeImageSize() const;
     size_t rowBytesUsingFormat(SkMask::Format format) const;

     // Call this to set all of the metrics fields to 0 (e.g. if the scaler
     // encounters an error measuring a glyph). Note: this does not alter the
     // fImage, fPath, fID, fMaskFormat fields.
     void zeroMetrics();

     bool hasImage() const {
         SkASSERT(fMaskFormat != MASK_FORMAT_UNKNOWN);
         return fImage != nullptr;
     }

     SkMask mask() const;

     SkMask mask(SkPoint position) const;

     SkPath* addPath(SkScalerContext*, SkArenaAlloc*);

     SkPath* path() const {
         return fPathData != nullptr && fPathData->fHasPath ? &fPathData->fPath : nullptr;
     }

     int maxDimension() const {
         // width and height are only defined if a metrics call was made.
         SkASSERT(fMaskFormat != MASK_FORMAT_UNKNOWN);

         return std::max(fWidth, fHeight);
     }

     // Returns the size allocated on the arena.
     size_t copyImageData(const SkGlyph& from, SkArenaAlloc* alloc);

     void*     fImage    = nullptr;

     // Path data has tricky state. If the glyph isEmpty, then fPathData should always be nullptr,
     // else if fPathData is not null, then a path has been requested. The fPath field of fPathData
     // may still be null after the request meaning that there is no path for this glyph.
     PathData* fPathData = nullptr;

     // The advance for this glyph.
     float     fAdvanceX = 0,
               fAdvanceY = 0;

     // The width and height of the glyph mask.
     uint16_t  fWidth  = 0,
               fHeight = 0;

     // The offset from the glyphs origin on the baseline to the top left of the glyph mask.
     int16_t   fTop  = 0,
               fLeft = 0;

     // Used by the GDI scaler to track state.
     int8_t    fForceBW = 0;

     // This is a combination of SkMask::Format and SkGlyph state. The SkGlyph can be in one of two
     // states, just the advances have been calculated, and all the metrics are available. The
     // illegal mask format is used to signal that only the advances are available.
     uint8_t   fMaskFormat = MASK_FORMAT_UNKNOWN;

 private:

     // Support horizontal and vertical skipping strike-through / underlines.
     // The caller walks the linked list looking for a match. For a horizontal underline,
     // the fBounds contains the top and bottom of the underline. The fInterval pair contains the
     // beginning and end of of the intersection of the bounds and the glyph's path.
     // If interval[0] >= interval[1], no intesection was found.
     struct Intercept {
         Intercept* fNext;
         SkScalar   fBounds[2];    // for horz underlines, the boundaries in Y
         SkScalar   fInterval[2];  // the outside intersections of the axis and the glyph
     };

     struct PathData {
         Intercept* fIntercept{nullptr};
         SkPath     fPath;
         bool       fHasPath{false};
     };

     // TODO(herb) remove friend statement after SkStrike cleanup.
     friend class SkStrike;
     SkPackedGlyphID fID;
 };

 #endif
	/*
	* Copyright 2006 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkGlyph_DEFINED
	#define SkGlyph_DEFINED

	#include "SkChecksum.h"
	#include "SkFixed.h"
	#include "SkMask.h"
	#include "SkPath.h"
	#include "SkTo.h"
	#include "SkTypes.h"

	class SkArenaAlloc;
	class SkStrike;
	class SkScalerContext;

	// needs to be != to any valid SkMask::Format
	#define MASK_FORMAT_UNKNOWN (0xFF)
	#define MASK_FORMAT_JUST_ADVANCE MASK_FORMAT_UNKNOWN

	#define kMaxGlyphWidth (1<<13)

	/** (glyph-index or unicode-point) + subpixel-pos */
	struct SkPackedID {
	static constexpr uint32_t kImpossibleID = ~0;
	enum {
	kSubBits = 2,
	kSubMask = ((1 << kSubBits) - 1),
	kSubShift = 24, // must be large enough for glyphs and unichars
	kCodeMask = ((1 << kSubShift) - 1),
	// relative offsets for X and Y subpixel bits
	kSubShiftX = kSubBits,
	kSubShiftY = 0
	};

	SkPackedID(uint32_t code) {
	SkASSERT(code <= kCodeMask);
	SkASSERT(code != kImpossibleID);
	fID = code;
	}

	SkPackedID(uint32_t code, SkFixed x, SkFixed y) {
	SkASSERT(code <= kCodeMask);
	x = FixedToSub(x);
	y = FixedToSub(y);
	uint32_t ID = (x << (kSubShift + kSubShiftX)) \|
	(y << (kSubShift + kSubShiftY)) \|
	code;
	SkASSERT(ID != kImpossibleID);
	fID = ID;
	}

	constexpr SkPackedID() : fID(kImpossibleID) {}

	bool operator==(const SkPackedID& that) const {
	return fID == that.fID;
	}
	bool operator!=(const SkPackedID& that) const {
	return !(*this == that);
	}
	bool operator<(SkPackedID that) const {
	return this->fID < that.fID;
	}

	uint32_t code() const {
	return fID & kCodeMask;
	}

	uint32_t value() const {
	return fID;
	}

	SkFixed getSubXFixed() const {
	return SubToFixed(ID2SubX(fID));
	}

	SkFixed getSubYFixed() const {
	return SubToFixed(ID2SubY(fID));
	}

	uint32_t hash() const {
	return SkChecksum::CheapMix(fID);
	}

	SkString dump() const {
	SkString str;
	str.appendf("code: %d, x: %d, y:%d", code(), getSubXFixed(), getSubYFixed());
	return str;
	}

	private:
	static unsigned ID2SubX(uint32_t id) {
	return id >> (kSubShift + kSubShiftX);
	}

	static unsigned ID2SubY(uint32_t id) {
	return (id >> (kSubShift + kSubShiftY)) & kSubMask;
	}

	static unsigned FixedToSub(SkFixed n) {
	return (n >> (16 - kSubBits)) & kSubMask;
	}

	static SkFixed SubToFixed(unsigned sub) {
	SkASSERT(sub <= kSubMask);
	return sub << (16 - kSubBits);
	}

	uint32_t fID;
	};

	struct SkPackedGlyphID : public SkPackedID {
	SkPackedGlyphID(SkGlyphID code) : SkPackedID(code) { }
	SkPackedGlyphID(SkGlyphID code, SkFixed x, SkFixed y) : SkPackedID(code, x, y) { }
	SkPackedGlyphID(SkGlyphID code, SkIPoint pt) : SkPackedID(code, pt.x(), pt.y()) { }
	constexpr SkPackedGlyphID() = default;
	SkGlyphID code() const {
	return SkTo<SkGlyphID>(SkPackedID::code());
	}
	};

	class SkGlyph {
	struct PathData;

	public:
	constexpr explicit SkGlyph(SkPackedGlyphID id) : fID{id} {}
	static constexpr SkFixed kSubpixelRound = SK_FixedHalf >> SkPackedID::kSubBits;

	bool isEmpty() const { return fWidth == 0 \|\| fHeight == 0; }
	bool isJustAdvance() const { return MASK_FORMAT_JUST_ADVANCE == fMaskFormat; }
	bool isFullMetrics() const { return MASK_FORMAT_JUST_ADVANCE != fMaskFormat; }
	SkGlyphID getGlyphID() const { return fID.code(); }
	SkPackedGlyphID getPackedID() const { return fID; }
	SkFixed getSubXFixed() const { return fID.getSubXFixed(); }
	SkFixed getSubYFixed() const { return fID.getSubYFixed(); }

	size_t formatAlignment() const;
	size_t allocImage(SkArenaAlloc* alloc);
	size_t rowBytes() const;
	size_t computeImageSize() const;
	size_t rowBytesUsingFormat(SkMask::Format format) const;

	// Call this to set all of the metrics fields to 0 (e.g. if the scaler
	// encounters an error measuring a glyph). Note: this does not alter the
	// fImage, fPath, fID, fMaskFormat fields.
	void zeroMetrics();

	bool hasImage() const {
	SkASSERT(fMaskFormat != MASK_FORMAT_UNKNOWN);
	return fImage != nullptr;
	}

	SkMask mask() const;

	SkMask mask(SkPoint position) const;

	SkPath* addPath(SkScalerContext, SkArenaAlloc);

	SkPath* path() const {
	return fPathData != nullptr && fPathData->fHasPath ? &fPathData->fPath : nullptr;
	}

	int maxDimension() const {
	// width and height are only defined if a metrics call was made.
	SkASSERT(fMaskFormat != MASK_FORMAT_UNKNOWN);

	return std::max(fWidth, fHeight);
	}

	// Returns the size allocated on the arena.
	size_t copyImageData(const SkGlyph& from, SkArenaAlloc* alloc);

	void* fImage = nullptr;

	// Path data has tricky state. If the glyph isEmpty, then fPathData should always be nullptr,
	// else if fPathData is not null, then a path has been requested. The fPath field of fPathData
	// may still be null after the request meaning that there is no path for this glyph.
	PathData* fPathData = nullptr;

	// The advance for this glyph.
	float fAdvanceX = 0,
	fAdvanceY = 0;

	// The width and height of the glyph mask.
	uint16_t fWidth = 0,
	fHeight = 0;

	// The offset from the glyphs origin on the baseline to the top left of the glyph mask.
	int16_t fTop = 0,
	fLeft = 0;

	// Used by the GDI scaler to track state.
	int8_t fForceBW = 0;

	// This is a combination of SkMask::Format and SkGlyph state. The SkGlyph can be in one of two
	// states, just the advances have been calculated, and all the metrics are available. The
	// illegal mask format is used to signal that only the advances are available.
	uint8_t fMaskFormat = MASK_FORMAT_UNKNOWN;

	private:

	// Support horizontal and vertical skipping strike-through / underlines.
	// The caller walks the linked list looking for a match. For a horizontal underline,
	// the fBounds contains the top and bottom of the underline. The fInterval pair contains the
	// beginning and end of of the intersection of the bounds and the glyph's path.
	// If interval[0] >= interval[1], no intesection was found.
	struct Intercept {
	Intercept* fNext;
	SkScalar fBounds[2]; // for horz underlines, the boundaries in Y
	SkScalar fInterval[2]; // the outside intersections of the axis and the glyph
	};

	struct PathData {
	Intercept* fIntercept{nullptr};
	SkPath fPath;
	bool fHasPath{false};
	};

	// TODO(herb) remove friend statement after SkStrike cleanup.
	friend class SkStrike;
	SkPackedGlyphID fID;
	};

	#endif