gpu/include/GrStencil.h - platform/external/skia - Git at Google

 /*
     Copyright 2011 Google Inc.

     Licensed under the Apache License, Version 2.0 (the "License");
     you may not use this file except in compliance with the License.
     You may obtain a copy of the License at

          http://www.apache.org/licenses/LICENSE-2.0

     Unless required by applicable law or agreed to in writing, software
     distributed under the License is distributed on an "AS IS" BASIS,
     WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
     See the License for the specific language governing permissions and
     limitations under the License.
  */

 #ifndef GrStencil_DEFINED
 #define GrStencil_DEFINED

 #include "GrTypes.h"
 /**
  * Gr uses the stencil buffer to implement complex clipping inside the
  * GrDrawTarget class. The GrDrawTarget makes a subset of the stencil buffer
  * bits available for other uses by external code (clients). Client code can
  * modify these bits. GrDrawTarget will ignore ref, mask, and writemask bits
  * provided by clients that overlap the bits used to implement clipping. The
  * client can use the getUsableStencilBits() function to find out how many
  * client accessible stencil bits are available.
  *
  * When code outside the GrDrawTarget class uses the stencil buffer the contract
  * is as follows:
  *
  * > Normal stencil funcs allow the GrGpu client to modify the client bits of
  *   the stencil buffer outside of the clip.
  * > Special functions allow a test against the clip. These are more limited
  *   than the general stencil functions.
  * > Client can assume all client bits are zero initially.
  * > Client must ensure that after all its passes are finished it has only
  *   written to the color buffer in the region inside the clip. Furthermore, it
  *   must zero all client bits that were modifed (both inside and outside the
  *   clip).
  */

 /**
  * Determines which pixels pass / fail the stencil test.
  * Stencil test passes if (ref & mask) FUNC (stencil & mask) is true
  */
 enum GrStencilFunc {
     kAlways_StencilFunc = 0,
     kNever_StencilFunc,
     kGreater_StencilFunc,
     kGEqual_StencilFunc,
     kLess_StencilFunc,
     kLEqual_StencilFunc,
     kEqual_StencilFunc,
     kNotEqual_StencilFunc,

     // Gr stores the current clip in the
     // stencil buffer in the high bits that
     // are not directly accessible modifiable
     // via the GrDrawTarget interface. The below
     // stencil funcs test against the current
     // clip in addition to the GrDrawTarget
     // client's stencil bits.

     // pass if inside the clip
     kAlwaysIfInClip_StencilFunc,
     kEqualIfInClip_StencilFunc,
     kLessIfInClip_StencilFunc,
     kLEqualIfInClip_StencilFunc,
     kNonZeroIfInClip_StencilFunc, // this one forces the ref to be 0

     // counts
     kStencilFuncCount,
     kClipStencilFuncCount = kNonZeroIfInClip_StencilFunc -
                             kAlwaysIfInClip_StencilFunc + 1,
     kBasicStencilFuncCount = kStencilFuncCount - kClipStencilFuncCount
 };

 /**
  * Operations to perform based on whether stencil test passed failed.
  */
 enum GrStencilOp {
     kKeep_StencilOp = 0,    // preserve existing stencil value
     kReplace_StencilOp,     // replace with reference value from stencl test
     kIncWrap_StencilOp,     // increment and wrap at max
     kIncClamp_StencilOp,    // increment and clamp at max
     kDecWrap_StencilOp,     // decrement and wrap at 0
     kDecClamp_StencilOp,    // decrement and clamp at 0
     kZero_StencilOp,        // zero stencil bits
     kInvert_StencilOp,      // invert stencil bits

     kStencilOpCount
 };

 /**
  * Struct representing stencil state.
  */
 struct GrStencilSettings {
     GrStencilOp   fFrontPassOp;     // op to perform when front faces pass
     GrStencilOp   fBackPassOp;      // op to perform when back faces pass
     GrStencilOp   fFrontFailOp;     // op to perform when front faces fail
     GrStencilOp   fBackFailOp;      // op to perform when back faces fail
     GrStencilFunc fFrontFunc;       // test function for front faces
     GrStencilFunc fBackFunc;        // test function for back faces
     unsigned int fFrontFuncMask;    // mask for front face test
     unsigned int fBackFuncMask;     // mask for back face test
     unsigned int fFrontFuncRef;     // reference value for front face test
     unsigned int fBackFuncRef;      // reference value for back face test
     unsigned int fFrontWriteMask;   // stencil write mask for front faces
     unsigned int fBackWriteMask;    // stencil write mask for back faces

     bool operator == (const GrStencilSettings& s) const {
         // make sure this is tightly packed.
         GR_STATIC_ASSERT(0 == sizeof(GrStencilOp)%4);
         GR_STATIC_ASSERT(0 == sizeof(GrStencilFunc)%4);
         GR_STATIC_ASSERT(sizeof(GrStencilSettings) ==
                         4*sizeof(GrStencilOp) +
                         2*sizeof(GrStencilFunc) +
                         6*sizeof(unsigned int));
         return 0 == memcmp(this, &s, sizeof(GrStencilSettings));
     }

     bool operator != (const GrStencilSettings& s) const {
         return !(*this == s);
     }

     GrStencilSettings& operator =(const GrStencilSettings& s) {
         memcpy(this, &s, sizeof(GrStencilSettings));
         return *this;
     }

     void setSame(GrStencilOp passOp,
                  GrStencilOp failOp,
                  GrStencilFunc func,
                  unsigned int funcMask,
                  unsigned int funcRef,
                  unsigned int writeMask) {
         fFrontPassOp        = passOp;
         fBackPassOp         = passOp;
         fFrontFailOp        = failOp;
         fBackFailOp         = failOp;
         fFrontFunc          = func;
         fBackFunc           = func;
         fFrontFuncMask      = funcMask;
         fBackFuncMask       = funcMask;
         fFrontFuncRef       = funcRef;
         fBackFuncRef        = funcRef;
         fFrontWriteMask     = writeMask;
         fBackWriteMask      = writeMask;
     }

     // canonical value for disabled stenciling
     static const GrStencilSettings gDisabled;
     void setDisabled() {
         *this = gDisabled;
     }
     bool isDisabled() const {
         return kKeep_StencilOp == fFrontPassOp   &&
                kKeep_StencilOp == fBackPassOp    &&
                kKeep_StencilOp == fFrontFailOp   &&
                kKeep_StencilOp == fBackFailOp   &&
                kAlways_StencilFunc == fFrontFunc &&
                kAlways_StencilFunc == fBackFunc;
     }
     void invalidate()  {
         // just write an illegal value to the first member
         fFrontPassOp = (GrStencilOp)-1;
     }

 private:
     friend class GrGpu;

     enum {
         kMaxStencilClipPasses = 2  // maximum number of passes to add a clip
                                    // element to the stencil buffer.
     };

     /**
      * Given a thing to draw into the stencil clip, a fill type, and a set op
      * this function determines:
      *      1. Whether the thing can be draw directly to the stencil clip or
      *      needs to be drawn to the client portion of the stencil first.
      *      2. How many passes are needed.
      *      3. What those passes are.
      *      4. The fill rule that should actually be used to render (will
      *         always be non-inverted).
      *
      * @param op                the set op to combine this element with the
      *                          existing clip
      * @param stencilClipMask   mask with just the stencil bit used for clipping
      *                          enabled.
      * @param invertedFill      is this path inverted
      * @param numPasses         out: the number of passes needed to add the
      *                               element to the clip.
      * @param settings          out: the stencil settings to use for each pass
      *
      * @return true if the clip element's geometry can be drawn directly to the
      *         stencil clip bit. Will only be true if canBeDirect is true.
      *         numPasses will be 1 if return value is true.
      */
     static bool GetClipPasses(GrSetOp op,
                               bool canBeDirect,
                               unsigned int stencilClipMask,
                               bool invertedFill,
                               int* numPasses,
                               GrStencilSettings settings[kMaxStencilClipPasses]);
 };

 #endif
	/*
	Copyright 2011 Google Inc.

	Licensed under the Apache License, Version 2.0 (the "License");
	you may not use this file except in compliance with the License.
	You may obtain a copy of the License at

	http://www.apache.org/licenses/LICENSE-2.0

	Unless required by applicable law or agreed to in writing, software
	distributed under the License is distributed on an "AS IS" BASIS,
	WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	See the License for the specific language governing permissions and
	limitations under the License.
	*/

	#ifndef GrStencil_DEFINED
	#define GrStencil_DEFINED

	#include "GrTypes.h"
	/**
	* Gr uses the stencil buffer to implement complex clipping inside the
	* GrDrawTarget class. The GrDrawTarget makes a subset of the stencil buffer
	* bits available for other uses by external code (clients). Client code can
	* modify these bits. GrDrawTarget will ignore ref, mask, and writemask bits
	* provided by clients that overlap the bits used to implement clipping. The
	* client can use the getUsableStencilBits() function to find out how many
	* client accessible stencil bits are available.
	*
	* When code outside the GrDrawTarget class uses the stencil buffer the contract
	* is as follows:
	*
	* > Normal stencil funcs allow the GrGpu client to modify the client bits of
	* the stencil buffer outside of the clip.
	* > Special functions allow a test against the clip. These are more limited
	* than the general stencil functions.
	* > Client can assume all client bits are zero initially.
	* > Client must ensure that after all its passes are finished it has only
	* written to the color buffer in the region inside the clip. Furthermore, it
	* must zero all client bits that were modifed (both inside and outside the
	* clip).
	*/

	/**
	* Determines which pixels pass / fail the stencil test.
	* Stencil test passes if (ref & mask) FUNC (stencil & mask) is true
	*/
	enum GrStencilFunc {
	kAlways_StencilFunc = 0,
	kNever_StencilFunc,
	kGreater_StencilFunc,
	kGEqual_StencilFunc,
	kLess_StencilFunc,
	kLEqual_StencilFunc,
	kEqual_StencilFunc,
	kNotEqual_StencilFunc,

	// Gr stores the current clip in the
	// stencil buffer in the high bits that
	// are not directly accessible modifiable
	// via the GrDrawTarget interface. The below
	// stencil funcs test against the current
	// clip in addition to the GrDrawTarget
	// client's stencil bits.

	// pass if inside the clip
	kAlwaysIfInClip_StencilFunc,
	kEqualIfInClip_StencilFunc,
	kLessIfInClip_StencilFunc,
	kLEqualIfInClip_StencilFunc,
	kNonZeroIfInClip_StencilFunc, // this one forces the ref to be 0

	// counts
	kStencilFuncCount,
	kClipStencilFuncCount = kNonZeroIfInClip_StencilFunc -
	kAlwaysIfInClip_StencilFunc + 1,
	kBasicStencilFuncCount = kStencilFuncCount - kClipStencilFuncCount
	};

	/**
	* Operations to perform based on whether stencil test passed failed.
	*/
	enum GrStencilOp {
	kKeep_StencilOp = 0, // preserve existing stencil value
	kReplace_StencilOp, // replace with reference value from stencl test
	kIncWrap_StencilOp, // increment and wrap at max
	kIncClamp_StencilOp, // increment and clamp at max
	kDecWrap_StencilOp, // decrement and wrap at 0
	kDecClamp_StencilOp, // decrement and clamp at 0
	kZero_StencilOp, // zero stencil bits
	kInvert_StencilOp, // invert stencil bits

	kStencilOpCount
	};

	/**
	* Struct representing stencil state.
	*/
	struct GrStencilSettings {
	GrStencilOp fFrontPassOp; // op to perform when front faces pass
	GrStencilOp fBackPassOp; // op to perform when back faces pass
	GrStencilOp fFrontFailOp; // op to perform when front faces fail
	GrStencilOp fBackFailOp; // op to perform when back faces fail
	GrStencilFunc fFrontFunc; // test function for front faces
	GrStencilFunc fBackFunc; // test function for back faces
	unsigned int fFrontFuncMask; // mask for front face test
	unsigned int fBackFuncMask; // mask for back face test
	unsigned int fFrontFuncRef; // reference value for front face test
	unsigned int fBackFuncRef; // reference value for back face test
	unsigned int fFrontWriteMask; // stencil write mask for front faces
	unsigned int fBackWriteMask; // stencil write mask for back faces

	bool operator == (const GrStencilSettings& s) const {
	// make sure this is tightly packed.
	GR_STATIC_ASSERT(0 == sizeof(GrStencilOp)%4);
	GR_STATIC_ASSERT(0 == sizeof(GrStencilFunc)%4);
	GR_STATIC_ASSERT(sizeof(GrStencilSettings) ==
	4*sizeof(GrStencilOp) +
	2*sizeof(GrStencilFunc) +
	6*sizeof(unsigned int));
	return 0 == memcmp(this, &s, sizeof(GrStencilSettings));
	}

	bool operator != (const GrStencilSettings& s) const {
	return !(*this == s);
	}

	GrStencilSettings& operator =(const GrStencilSettings& s) {
	memcpy(this, &s, sizeof(GrStencilSettings));
	return *this;
	}

	void setSame(GrStencilOp passOp,
	GrStencilOp failOp,
	GrStencilFunc func,
	unsigned int funcMask,
	unsigned int funcRef,
	unsigned int writeMask) {
	fFrontPassOp = passOp;
	fBackPassOp = passOp;
	fFrontFailOp = failOp;
	fBackFailOp = failOp;
	fFrontFunc = func;
	fBackFunc = func;
	fFrontFuncMask = funcMask;
	fBackFuncMask = funcMask;
	fFrontFuncRef = funcRef;
	fBackFuncRef = funcRef;
	fFrontWriteMask = writeMask;
	fBackWriteMask = writeMask;
	}

	// canonical value for disabled stenciling
	static const GrStencilSettings gDisabled;
	void setDisabled() {
	*this = gDisabled;
	}
	bool isDisabled() const {
	return kKeep_StencilOp == fFrontPassOp &&
	kKeep_StencilOp == fBackPassOp &&
	kKeep_StencilOp == fFrontFailOp &&
	kKeep_StencilOp == fBackFailOp &&
	kAlways_StencilFunc == fFrontFunc &&
	kAlways_StencilFunc == fBackFunc;
	}
	void invalidate() {
	// just write an illegal value to the first member
	fFrontPassOp = (GrStencilOp)-1;
	}

	private:
	friend class GrGpu;

	enum {
	kMaxStencilClipPasses = 2 // maximum number of passes to add a clip
	// element to the stencil buffer.
	};

	/**
	* Given a thing to draw into the stencil clip, a fill type, and a set op
	* this function determines:
	* 1. Whether the thing can be draw directly to the stencil clip or
	* needs to be drawn to the client portion of the stencil first.
	* 2. How many passes are needed.
	* 3. What those passes are.
	* 4. The fill rule that should actually be used to render (will
	* always be non-inverted).
	*
	* @param op the set op to combine this element with the
	* existing clip
	* @param stencilClipMask mask with just the stencil bit used for clipping
	* enabled.
	* @param invertedFill is this path inverted
	* @param numPasses out: the number of passes needed to add the
	* element to the clip.
	* @param settings out: the stencil settings to use for each pass
	*
	* @return true if the clip element's geometry can be drawn directly to the
	* stencil clip bit. Will only be true if canBeDirect is true.
	* numPasses will be 1 if return value is true.
	*/
	static bool GetClipPasses(GrSetOp op,
	bool canBeDirect,
	unsigned int stencilClipMask,
	bool invertedFill,
	int* numPasses,
	GrStencilSettings settings[kMaxStencilClipPasses]);
	};

	#endif