cpu_ref/rsCpuIntrinsicYuvToRGB.cpp - platform/frameworks/rs - Git at Google

 /*
  * Copyright (C) 2013 The Android Open Source Project
  *
  * 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.
  */


 #include "rsCpuIntrinsic.h"
 #include "rsCpuIntrinsicInlines.h"

 #ifdef RS_COMPATIBILITY_LIB
 #include "rsCompatibilityLib.h"
 #endif

 #ifndef RS_COMPATIBILITY_LIB
 #include "hardware/gralloc.h"
 #endif

 namespace android {
 namespace renderscript {


 class RsdCpuScriptIntrinsicYuvToRGB : public RsdCpuScriptIntrinsic {
 public:
     void populateScript(Script *) override;
     void invokeFreeChildren() override;

     void setGlobalObj(uint32_t slot, ObjectBase *data) override;

     ~RsdCpuScriptIntrinsicYuvToRGB() override;
     RsdCpuScriptIntrinsicYuvToRGB(RsdCpuReferenceImpl *ctx, const Script *s, const Element *e);

 protected:
     ObjectBaseRef<Allocation> alloc;

     static void kernel(const RsExpandKernelDriverInfo *info,
                        uint32_t xstart, uint32_t xend,
                        uint32_t outstep);
 };


 void RsdCpuScriptIntrinsicYuvToRGB::setGlobalObj(uint32_t slot, ObjectBase *data) {
     rsAssert(slot == 0);
     alloc.set(static_cast<Allocation *>(data));
 }


 static uchar4 rsYuvToRGBA_uchar4(uchar y, uchar u, uchar v) {
     int16_t Y = ((int16_t)y) - 16;
     int16_t U = ((int16_t)u) - 128;
     int16_t V = ((int16_t)v) - 128;

     short4 p;
     p.x = (Y * 298 + V * 409 + 128) >> 8;
     p.y = (Y * 298 - U * 100 - V * 208 + 128) >> 8;
     p.z = (Y * 298 + U * 516 + 128) >> 8;
     p.w = 255;
     if(p.x < 0) {
         p.x = 0;
     }
     if(p.x > 255) {
         p.x = 255;
     }
     if(p.y < 0) {
         p.y = 0;
     }
     if(p.y > 255) {
         p.y = 255;
     }
     if(p.z < 0) {
         p.z = 0;
     }
     if(p.z > 255) {
         p.z = 255;
     }

     return (uchar4){static_cast<uchar>(p.x), static_cast<uchar>(p.y),
                     static_cast<uchar>(p.z), static_cast<uchar>(p.w)};
 }


 extern "C" void rsdIntrinsicYuv_K(void *dst, const uchar *Y, const uchar *uv, uint32_t xstart, size_t xend);
 extern "C" void rsdIntrinsicYuvR_K(void *dst, const uchar *Y, const uchar *uv, uint32_t xstart, size_t xend);
 extern "C" void rsdIntrinsicYuv2_K(void *dst, const uchar *Y, const uchar *u, const uchar *v, size_t xstart, size_t xend);

 void RsdCpuScriptIntrinsicYuvToRGB::kernel(const RsExpandKernelDriverInfo *info,
                                            uint32_t xstart, uint32_t xend,
                                            uint32_t outstep) {
     RsdCpuScriptIntrinsicYuvToRGB *cp = (RsdCpuScriptIntrinsicYuvToRGB *)info->usr;
     if (!cp->alloc.get()) {
         ALOGE("YuvToRGB executed without input, skipping");
         return;
     }
     const uchar *pinY = (const uchar *)cp->alloc->mHal.drvState.lod[0].mallocPtr;
     if (pinY == nullptr) {
         ALOGE("YuvToRGB executed without data, skipping");
         return;
     }

     size_t strideY = cp->alloc->mHal.drvState.lod[0].stride;

     // calculate correct stride in legacy case
     if (cp->alloc->mHal.drvState.lod[0].dimY == 0) {
         strideY = info->dim.x;
     }
     const uchar *Y = pinY + (info->current.y * strideY);

     uchar4 *out = (uchar4 *)info->outPtr[0] + xstart;
     uint32_t x1 = xstart;
     uint32_t x2 = xend;

     size_t cstep = cp->alloc->mHal.drvState.yuv.step;

     const uchar *pinU = (const uchar *)cp->alloc->mHal.drvState.lod[1].mallocPtr;
     const size_t strideU = cp->alloc->mHal.drvState.lod[1].stride;
     const uchar *u = pinU + ((info->current.y >> 1) * strideU);

     const uchar *pinV = (const uchar *)cp->alloc->mHal.drvState.lod[2].mallocPtr;
     const size_t strideV = cp->alloc->mHal.drvState.lod[2].stride;
     const uchar *v = pinV + ((info->current.y >> 1) * strideV);

     //ALOGE("pinY, %p, Y, %p, info->current.y, %d, strideY, %d", pinY, Y, info->current.y, strideY);
     //ALOGE("pinU, %p, U, %p, info->current.y, %d, strideU, %d", pinU, u, info->current.y, strideU);
     //ALOGE("pinV, %p, V, %p, info->current.y, %d, strideV, %d", pinV, v, info->current.y, strideV);
     //ALOGE("dimX, %d, dimY, %d", cp->alloc->mHal.drvState.lod[0].dimX, cp->alloc->mHal.drvState.lod[0].dimY);
     //ALOGE("info->dim.x, %d, info->dim.y, %d", info->dim.x, info->dim.y);

     if (pinU == nullptr) {
         // Legacy yuv support didn't fill in uv
         v = ((uint8_t *)cp->alloc->mHal.drvState.lod[0].mallocPtr) +
             (strideY * info->dim.y) +
             ((info->current.y >> 1) * strideY);
         u = v + 1;
         cstep = 2;
     }

     /* If we start on an odd pixel then deal with it here and bump things along
      * so that subsequent code can carry on with even-odd pairing assumptions.
      */
     if((x1 & 1) && (x2 > x1)) {
         int cx = (x1 >> 1) * cstep;
         *out = rsYuvToRGBA_uchar4(Y[x1], u[cx], v[cx]);
         out++;
         x1++;
     }

 #if defined(ARCH_ARM_USE_INTRINSICS)
     if((x2 > x1) && gArchUseSIMD) {
         int32_t len = x2 - x1;
         if (cstep == 1) {
             rsdIntrinsicYuv2_K(info->outPtr[0], Y, u, v, x1, x2);
             x1 += len;
             out += len;
         } else if (cstep == 2) {
             // Check for proper interleave
             intptr_t ipu = (intptr_t)u;
             intptr_t ipv = (intptr_t)v;

             if (ipu == (ipv + 1)) {
                 rsdIntrinsicYuv_K(info->outPtr[0], Y, v, x1, x2);
                 x1 += len;
                 out += len;
             } else if (ipu == (ipv - 1)) {
                 rsdIntrinsicYuvR_K(info->outPtr[0], Y, u, x1, x2);
                 x1 += len;
                 out += len;
             }
         }
     }
 #endif

     if(x2 > x1) {
        // ALOGE("y %i  %i  %i", info->current.y, x1, x2);
         while(x1 < x2) {
             int cx = (x1 >> 1) * cstep;
             *out = rsYuvToRGBA_uchar4(Y[x1], u[cx], v[cx]);
             out++;
             x1++;
             *out = rsYuvToRGBA_uchar4(Y[x1], u[cx], v[cx]);
             out++;
             x1++;
         }
     }

 }

 RsdCpuScriptIntrinsicYuvToRGB::RsdCpuScriptIntrinsicYuvToRGB(
             RsdCpuReferenceImpl *ctx, const Script *s, const Element *e)
             : RsdCpuScriptIntrinsic(ctx, s, e, RS_SCRIPT_INTRINSIC_ID_YUV_TO_RGB) {

     mRootPtr = &kernel;
 }

 RsdCpuScriptIntrinsicYuvToRGB::~RsdCpuScriptIntrinsicYuvToRGB() {
 }

 void RsdCpuScriptIntrinsicYuvToRGB::populateScript(Script *s) {
     s->mHal.info.exportedVariableCount = 1;
 }

 void RsdCpuScriptIntrinsicYuvToRGB::invokeFreeChildren() {
     alloc.clear();
 }

 RsdCpuScriptImpl * rsdIntrinsic_YuvToRGB(RsdCpuReferenceImpl *ctx,
                                          const Script *s, const Element *e) {
     return new RsdCpuScriptIntrinsicYuvToRGB(ctx, s, e);
 }

 } // namespace renderscript
 } // namespace android
	/*
	* Copyright (C) 2013 The Android Open Source Project
	*
	* 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.
	*/


	#include "rsCpuIntrinsic.h"
	#include "rsCpuIntrinsicInlines.h"

	#ifdef RS_COMPATIBILITY_LIB
	#include "rsCompatibilityLib.h"
	#endif

	#ifndef RS_COMPATIBILITY_LIB
	#include "hardware/gralloc.h"
	#endif

	namespace android {
	namespace renderscript {


	class RsdCpuScriptIntrinsicYuvToRGB : public RsdCpuScriptIntrinsic {
	public:
	void populateScript(Script *) override;
	void invokeFreeChildren() override;

	void setGlobalObj(uint32_t slot, ObjectBase *data) override;

	~RsdCpuScriptIntrinsicYuvToRGB() override;
	RsdCpuScriptIntrinsicYuvToRGB(RsdCpuReferenceImpl ctx, const Script s, const Element *e);

	protected:
	ObjectBaseRef<Allocation> alloc;

	static void kernel(const RsExpandKernelDriverInfo *info,
	uint32_t xstart, uint32_t xend,
	uint32_t outstep);
	};


	void RsdCpuScriptIntrinsicYuvToRGB::setGlobalObj(uint32_t slot, ObjectBase *data) {
	rsAssert(slot == 0);
	alloc.set(static_cast<Allocation *>(data));
	}




	static uchar4 rsYuvToRGBA_uchar4(uchar y, uchar u, uchar v) {
	int16_t Y = ((int16_t)y) - 16;
	int16_t U = ((int16_t)u) - 128;
	int16_t V = ((int16_t)v) - 128;

	short4 p;
	p.x = (Y * 298 + V * 409 + 128) >> 8;
	p.y = (Y * 298 - U * 100 - V * 208 + 128) >> 8;
	p.z = (Y * 298 + U * 516 + 128) >> 8;
	p.w = 255;
	if(p.x < 0) {
	p.x = 0;
	}
	if(p.x > 255) {
	p.x = 255;
	}
	if(p.y < 0) {
	p.y = 0;
	}
	if(p.y > 255) {
	p.y = 255;
	}
	if(p.z < 0) {
	p.z = 0;
	}
	if(p.z > 255) {
	p.z = 255;
	}

	return (uchar4){static_cast<uchar>(p.x), static_cast<uchar>(p.y),
	static_cast<uchar>(p.z), static_cast<uchar>(p.w)};
	}


	extern "C" void rsdIntrinsicYuv_K(void dst, const uchar Y, const uchar *uv, uint32_t xstart, size_t xend);
	extern "C" void rsdIntrinsicYuvR_K(void dst, const uchar Y, const uchar *uv, uint32_t xstart, size_t xend);
	extern "C" void rsdIntrinsicYuv2_K(void dst, const uchar Y, const uchar u, const uchar v, size_t xstart, size_t xend);

	void RsdCpuScriptIntrinsicYuvToRGB::kernel(const RsExpandKernelDriverInfo *info,
	uint32_t xstart, uint32_t xend,
	uint32_t outstep) {
	RsdCpuScriptIntrinsicYuvToRGB cp = (RsdCpuScriptIntrinsicYuvToRGB )info->usr;
	if (!cp->alloc.get()) {
	ALOGE("YuvToRGB executed without input, skipping");
	return;
	}
	const uchar pinY = (const uchar )cp->alloc->mHal.drvState.lod[0].mallocPtr;
	if (pinY == nullptr) {
	ALOGE("YuvToRGB executed without data, skipping");
	return;
	}

	size_t strideY = cp->alloc->mHal.drvState.lod[0].stride;

	// calculate correct stride in legacy case
	if (cp->alloc->mHal.drvState.lod[0].dimY == 0) {
	strideY = info->dim.x;
	}
	const uchar Y = pinY + (info->current.y strideY);

	uchar4 out = (uchar4 )info->outPtr[0] + xstart;
	uint32_t x1 = xstart;
	uint32_t x2 = xend;

	size_t cstep = cp->alloc->mHal.drvState.yuv.step;

	const uchar pinU = (const uchar )cp->alloc->mHal.drvState.lod[1].mallocPtr;
	const size_t strideU = cp->alloc->mHal.drvState.lod[1].stride;
	const uchar u = pinU + ((info->current.y >> 1) strideU);

	const uchar pinV = (const uchar )cp->alloc->mHal.drvState.lod[2].mallocPtr;
	const size_t strideV = cp->alloc->mHal.drvState.lod[2].stride;
	const uchar v = pinV + ((info->current.y >> 1) strideV);

	//ALOGE("pinY, %p, Y, %p, info->current.y, %d, strideY, %d", pinY, Y, info->current.y, strideY);
	//ALOGE("pinU, %p, U, %p, info->current.y, %d, strideU, %d", pinU, u, info->current.y, strideU);
	//ALOGE("pinV, %p, V, %p, info->current.y, %d, strideV, %d", pinV, v, info->current.y, strideV);
	//ALOGE("dimX, %d, dimY, %d", cp->alloc->mHal.drvState.lod[0].dimX, cp->alloc->mHal.drvState.lod[0].dimY);
	//ALOGE("info->dim.x, %d, info->dim.y, %d", info->dim.x, info->dim.y);

	if (pinU == nullptr) {
	// Legacy yuv support didn't fill in uv
	v = ((uint8_t *)cp->alloc->mHal.drvState.lod[0].mallocPtr) +
	(strideY * info->dim.y) +
	((info->current.y >> 1) * strideY);
	u = v + 1;
	cstep = 2;
	}

	/* If we start on an odd pixel then deal with it here and bump things along
	* so that subsequent code can carry on with even-odd pairing assumptions.
	*/
	if((x1 & 1) && (x2 > x1)) {
	int cx = (x1 >> 1) * cstep;
	*out = rsYuvToRGBA_uchar4(Y[x1], u[cx], v[cx]);
	out++;
	x1++;
	}

	#if defined(ARCH_ARM_USE_INTRINSICS)
	if((x2 > x1) && gArchUseSIMD) {
	int32_t len = x2 - x1;
	if (cstep == 1) {
	rsdIntrinsicYuv2_K(info->outPtr[0], Y, u, v, x1, x2);
	x1 += len;
	out += len;
	} else if (cstep == 2) {
	// Check for proper interleave
	intptr_t ipu = (intptr_t)u;
	intptr_t ipv = (intptr_t)v;

	if (ipu == (ipv + 1)) {
	rsdIntrinsicYuv_K(info->outPtr[0], Y, v, x1, x2);
	x1 += len;
	out += len;
	} else if (ipu == (ipv - 1)) {
	rsdIntrinsicYuvR_K(info->outPtr[0], Y, u, x1, x2);
	x1 += len;
	out += len;
	}
	}
	}
	#endif

	if(x2 > x1) {
	// ALOGE("y %i %i %i", info->current.y, x1, x2);
	while(x1 < x2) {
	int cx = (x1 >> 1) * cstep;
	*out = rsYuvToRGBA_uchar4(Y[x1], u[cx], v[cx]);
	out++;
	x1++;
	*out = rsYuvToRGBA_uchar4(Y[x1], u[cx], v[cx]);
	out++;
	x1++;
	}
	}

	}

	RsdCpuScriptIntrinsicYuvToRGB::RsdCpuScriptIntrinsicYuvToRGB(
	RsdCpuReferenceImpl ctx, const Script s, const Element *e)
	: RsdCpuScriptIntrinsic(ctx, s, e, RS_SCRIPT_INTRINSIC_ID_YUV_TO_RGB) {

	mRootPtr = &kernel;
	}

	RsdCpuScriptIntrinsicYuvToRGB::~RsdCpuScriptIntrinsicYuvToRGB() {
	}

	void RsdCpuScriptIntrinsicYuvToRGB::populateScript(Script *s) {
	s->mHal.info.exportedVariableCount = 1;
	}

	void RsdCpuScriptIntrinsicYuvToRGB::invokeFreeChildren() {
	alloc.clear();
	}

	RsdCpuScriptImpl * rsdIntrinsic_YuvToRGB(RsdCpuReferenceImpl *ctx,
	const Script s, const Element e) {
	return new RsdCpuScriptIntrinsicYuvToRGB(ctx, s, e);
	}

	} // namespace renderscript
	} // namespace android