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

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkGammas_DEFINED
 #define SkGammas_DEFINED

 #include "SkColorSpace.h"
 #include "SkData.h"
 #include "SkTemplates.h"

 struct SkGammas : SkRefCnt {

     // There are four possible representations for gamma curves.  kNone_Type is used
     // as a placeholder until the struct is initialized.  It is not a valid value.
     enum class Type {
         kNone_Type,
         kNamed_Type,
         kValue_Type,
         kTable_Type,
         kParam_Type,
     };

     // Contains information for a gamma table.
     struct Table {
         size_t fOffset;
         int    fSize;

         const float* table(const SkGammas* base) const {
             return SkTAddOffset<const float>(base, sizeof(SkGammas) + fOffset);
         }
     };

     // Contains the actual gamma curve information.  Should be interpreted
     // based on the type of the gamma curve.
     union Data {
         Data() : fTable{0, 0} {}

         SkGammaNamed fNamed;
         float        fValue;
         Table        fTable;
         size_t       fParamOffset;

         const SkColorSpaceTransferFn& params(const SkGammas* base) const {
             return *SkTAddOffset<const SkColorSpaceTransferFn>(base,
                                                                sizeof(SkGammas) + fParamOffset);
         }
     };

     bool allChannelsSame() const {
         // All channels are the same type?
         Type type = this->type(0);
         for (int i = 1; i < this->channels(); i++) {
             if (type != this->type(i)) {
                 return false;
             }
         }

         // All data the same?
         auto& first = this->data(0);
         for (int i = 1; i < this->channels(); i++) {
             auto& data = this->data(i);
             switch (type) {
                 case Type:: kNone_Type:                                                    break;
                 case Type::kNamed_Type: if (first.fNamed != data.fNamed) { return false; } break;
                 case Type::kValue_Type: if (first.fValue != data.fValue) { return false; } break;
                 case Type::kTable_Type:
                     if (first.fTable.fOffset != data.fTable.fOffset) { return false; }
                     if (first.fTable.fSize   != data.fTable.fSize  ) { return false; }
                     break;
                 case Type::kParam_Type:
                     if (0 != memcmp(&first.params(this), &data.params(this),
                                     sizeof(SkColorSpaceTransferFn))) {
                         return false;
                     }
                     break;
             }
         }
         return true;
     }

     bool isNamed     (int i) const { return Type::kNamed_Type == this->type(i); }
     bool isValue     (int i) const { return Type::kValue_Type == this->type(i); }
     bool isTable     (int i) const { return Type::kTable_Type == this->type(i); }
     bool isParametric(int i) const { return Type::kParam_Type == this->type(i); }

     const Data& data(int i) const {
         SkASSERT(i >= 0 && i < fChannels);
         return fData[i];
     }

     const float* table(int i) const {
         SkASSERT(this->isTable(i));
         return this->data(i).fTable.table(this);
     }

     int tableSize(int i) const {
         SkASSERT(this->isTable(i));
         return this->data(i).fTable.fSize;
     }

     const SkColorSpaceTransferFn& params(int i) const {
         SkASSERT(this->isParametric(i));
         return this->data(i).params(this);
     }

     Type type(int i) const {
         SkASSERT(i >= 0 && i < fChannels);
         return fType[i];
     }

     int channels() const { return fChannels; }

     SkGammas(int channels) : fChannels(channels) {
         SkASSERT(channels <= (int)SK_ARRAY_COUNT(fType));
         for (Type& t : fType) {
             t = Type::kNone_Type;
         }
     }

     // These fields should only be modified when initializing the struct.
     int  fChannels;
     Data fData[4];
     Type fType[4];

     // Objects of this type are sometimes created in a custom fashion using
     // sk_malloc_throw and therefore must be sk_freed.  We overload new to
     // also call sk_malloc_throw so that memory can be unconditionally released
     // using sk_free in an overloaded delete. Overloading regular new means we
     // must also overload placement new.
     void* operator new(size_t size) { return sk_malloc_throw(size); }
     void* operator new(size_t, void* p) { return p; }
     void operator delete(void* p) { sk_free(p); }
 };

 #endif
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkGammas_DEFINED
	#define SkGammas_DEFINED

	#include "SkColorSpace.h"
	#include "SkData.h"
	#include "SkTemplates.h"

	struct SkGammas : SkRefCnt {

	// There are four possible representations for gamma curves. kNone_Type is used
	// as a placeholder until the struct is initialized. It is not a valid value.
	enum class Type {
	kNone_Type,
	kNamed_Type,
	kValue_Type,
	kTable_Type,
	kParam_Type,
	};

	// Contains information for a gamma table.
	struct Table {
	size_t fOffset;
	int fSize;

	const float* table(const SkGammas* base) const {
	return SkTAddOffset<const float>(base, sizeof(SkGammas) + fOffset);
	}
	};

	// Contains the actual gamma curve information. Should be interpreted
	// based on the type of the gamma curve.
	union Data {
	Data() : fTable{0, 0} {}

	SkGammaNamed fNamed;
	float fValue;
	Table fTable;
	size_t fParamOffset;

	const SkColorSpaceTransferFn& params(const SkGammas* base) const {
	return *SkTAddOffset<const SkColorSpaceTransferFn>(base,
	sizeof(SkGammas) + fParamOffset);
	}
	};

	bool allChannelsSame() const {
	// All channels are the same type?
	Type type = this->type(0);
	for (int i = 1; i < this->channels(); i++) {
	if (type != this->type(i)) {
	return false;
	}
	}

	// All data the same?
	auto& first = this->data(0);
	for (int i = 1; i < this->channels(); i++) {
	auto& data = this->data(i);
	switch (type) {
	case Type:: kNone_Type: break;
	case Type::kNamed_Type: if (first.fNamed != data.fNamed) { return false; } break;
	case Type::kValue_Type: if (first.fValue != data.fValue) { return false; } break;
	case Type::kTable_Type:
	if (first.fTable.fOffset != data.fTable.fOffset) { return false; }
	if (first.fTable.fSize != data.fTable.fSize ) { return false; }
	break;
	case Type::kParam_Type:
	if (0 != memcmp(&first.params(this), &data.params(this),
	sizeof(SkColorSpaceTransferFn))) {
	return false;
	}
	break;
	}
	}
	return true;
	}

	bool isNamed (int i) const { return Type::kNamed_Type == this->type(i); }
	bool isValue (int i) const { return Type::kValue_Type == this->type(i); }
	bool isTable (int i) const { return Type::kTable_Type == this->type(i); }
	bool isParametric(int i) const { return Type::kParam_Type == this->type(i); }

	const Data& data(int i) const {
	SkASSERT(i >= 0 && i < fChannels);
	return fData[i];
	}

	const float* table(int i) const {
	SkASSERT(this->isTable(i));
	return this->data(i).fTable.table(this);
	}

	int tableSize(int i) const {
	SkASSERT(this->isTable(i));
	return this->data(i).fTable.fSize;
	}

	const SkColorSpaceTransferFn& params(int i) const {
	SkASSERT(this->isParametric(i));
	return this->data(i).params(this);
	}

	Type type(int i) const {
	SkASSERT(i >= 0 && i < fChannels);
	return fType[i];
	}

	int channels() const { return fChannels; }

	SkGammas(int channels) : fChannels(channels) {
	SkASSERT(channels <= (int)SK_ARRAY_COUNT(fType));
	for (Type& t : fType) {
	t = Type::kNone_Type;
	}
	}

	// These fields should only be modified when initializing the struct.
	int fChannels;
	Data fData[4];
	Type fType[4];

	// Objects of this type are sometimes created in a custom fashion using
	// sk_malloc_throw and therefore must be sk_freed. We overload new to
	// also call sk_malloc_throw so that memory can be unconditionally released
	// using sk_free in an overloaded delete. Overloading regular new means we
	// must also overload placement new.
	void* operator new(size_t size) { return sk_malloc_throw(size); }
	void* operator new(size_t, void* p) { return p; }
	void operator delete(void* p) { sk_free(p); }
	};

	#endif