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

 /*
  * Copyright (C) 2011-2012 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.
  */

 #if !defined(RS_SERVER) && !defined(RS_COMPATIBILITY_LIB)
 #include <cutils/compiler.h>
 #endif

 #include "rsContext.h"
 #include "rsScriptC.h"
 #include "rsMatrix4x4.h"
 #include "rsMatrix3x3.h"
 #include "rsMatrix2x2.h"

 #include "rsCpuCore.h"
 #include "rsCpuScript.h"

 using namespace android;
 using namespace android::renderscript;

 #define EXPORT_F32_FN_F32(func)                                 \
     float __attribute__((overloadable)) SC_##func(float v) {    \
         return func(v);                                         \
     }

 #define EXPORT_F32_FN_F32_F32(func)                                     \
     float __attribute__((overloadable)) SC_##func(float t, float v) {   \
         return func(t, v);                                              \
     }

 //////////////////////////////////////////////////////////////////////////////
 // Float util
 //////////////////////////////////////////////////////////////////////////////

 // Handle missing Gingerbread functions like tgammaf.
 float SC_tgammaf(float x) {
 #ifdef RS_COMPATIBILITY_LIB
     return tgamma(x);
 #else
     return tgammaf(x);
 #endif
 }

 uint32_t SC_abs_i32(int32_t v) {return abs(v);}

 static void SC_MatrixLoadRotate(Matrix4x4 *m, float rot, float x, float y, float z) {
     m->loadRotate(rot, x, y, z);
 }
 static void SC_MatrixLoadScale(Matrix4x4 *m, float x, float y, float z) {
     m->loadScale(x, y, z);
 }
 static void SC_MatrixLoadTranslate(Matrix4x4 *m, float x, float y, float z) {
     m->loadTranslate(x, y, z);
 }
 static void SC_MatrixRotate(Matrix4x4 *m, float rot, float x, float y, float z) {
     m->rotate(rot, x, y, z);
 }
 static void SC_MatrixScale(Matrix4x4 *m, float x, float y, float z) {
     m->scale(x, y, z);
 }
 static void SC_MatrixTranslate(Matrix4x4 *m, float x, float y, float z) {
     m->translate(x, y, z);
 }

 static void SC_MatrixLoadOrtho(Matrix4x4 *m, float l, float r, float b, float t, float n, float f) {
     m->loadOrtho(l, r, b, t, n, f);
 }
 static void SC_MatrixLoadFrustum(Matrix4x4 *m, float l, float r, float b, float t, float n, float f) {
     m->loadFrustum(l, r, b, t, n, f);
 }
 static void SC_MatrixLoadPerspective(Matrix4x4 *m, float fovy, float aspect, float near, float far) {
     m->loadPerspective(fovy, aspect, near, far);
 }

 static bool SC_MatrixInverse_4x4(Matrix4x4 *m) {
     return m->inverse();
 }
 static bool SC_MatrixInverseTranspose_4x4(Matrix4x4 *m) {
     return m->inverseTranspose();
 }
 static void SC_MatrixTranspose_4x4(Matrix4x4 *m) {
     m->transpose();
 }
 static void SC_MatrixTranspose_3x3(Matrix3x3 *m) {
     m->transpose();
 }
 static void SC_MatrixTranspose_2x2(Matrix2x2 *m) {
     m->transpose();
 }

 float SC_randf2(float min, float max) {
     float r = (float)rand();
     r /= RAND_MAX;
     r = r * (max - min) + min;
     return r;
 }

 EXPORT_F32_FN_F32(acosf)
 EXPORT_F32_FN_F32(acoshf)
 EXPORT_F32_FN_F32(asinf)
 EXPORT_F32_FN_F32(asinhf)
 EXPORT_F32_FN_F32(atanf)
 EXPORT_F32_FN_F32_F32(atan2f)
 EXPORT_F32_FN_F32(atanhf)
 EXPORT_F32_FN_F32(cbrtf)
 EXPORT_F32_FN_F32(ceilf)
 EXPORT_F32_FN_F32_F32(copysignf)
 EXPORT_F32_FN_F32(cosf)
 EXPORT_F32_FN_F32(coshf)
 EXPORT_F32_FN_F32(erfcf)
 EXPORT_F32_FN_F32(erff)
 EXPORT_F32_FN_F32(expf)
 EXPORT_F32_FN_F32(exp2f)
 EXPORT_F32_FN_F32(expm1f)
 EXPORT_F32_FN_F32_F32(fdimf)
 EXPORT_F32_FN_F32(floorf)
 float SC_fmaf(float u, float t, float v) {return fmaf(u, t, v);}
 EXPORT_F32_FN_F32_F32(fmaxf)
 EXPORT_F32_FN_F32_F32(fminf)
 EXPORT_F32_FN_F32_F32(fmodf)
 float SC_frexpf(float v, int* ptr) {return frexpf(v, ptr);}
 EXPORT_F32_FN_F32_F32(hypotf)
 int SC_ilogbf(float v) {return ilogbf(v); }
 float SC_ldexpf(float v, int i) {return ldexpf(v, i);}
 EXPORT_F32_FN_F32(lgammaf)
 float SC_lgammaf_r(float v, int* ptr) {return lgammaf_r(v, ptr);}
 EXPORT_F32_FN_F32(logf)
 EXPORT_F32_FN_F32(log10f)
 EXPORT_F32_FN_F32(log1pf)
 EXPORT_F32_FN_F32(logbf)
 float SC_modff(float v, float* ptr) {return modff(v, ptr);}
 EXPORT_F32_FN_F32_F32(nextafterf)
 EXPORT_F32_FN_F32_F32(powf)
 EXPORT_F32_FN_F32_F32(remainderf)
 float SC_remquof(float t, float v, int* ptr) {return remquof(t, v, ptr);}
 EXPORT_F32_FN_F32(rintf)
 EXPORT_F32_FN_F32(roundf)
 EXPORT_F32_FN_F32(sinf)
 EXPORT_F32_FN_F32(sinhf)
 EXPORT_F32_FN_F32(sqrtf)
 EXPORT_F32_FN_F32(tanf)
 EXPORT_F32_FN_F32(tanhf)
 EXPORT_F32_FN_F32(truncf)
 void __attribute__((overloadable)) rsMatrixLoadRotate(rs_matrix4x4 *m,
         float rot, float x, float y, float z) {
     SC_MatrixLoadRotate((Matrix4x4 *) m, rot, x, y, z);
 }
 void __attribute__((overloadable)) rsMatrixLoadScale(rs_matrix4x4 *m,
         float x, float y, float z) {
     SC_MatrixLoadScale((Matrix4x4 *) m, x, y, z);
 }
 void __attribute__((overloadable)) rsMatrixLoadTranslate(rs_matrix4x4 *m,
         float x, float y, float z) {
     SC_MatrixLoadTranslate((Matrix4x4 *) m, x, y, z);
 }
 void __attribute__((overloadable)) rsMatrixRotate(rs_matrix4x4 *m, float rot,
         float x, float y, float z) {
     SC_MatrixRotate((Matrix4x4 *) m, rot, x, y, z);
 }
 void __attribute__((overloadable)) rsMatrixScale(rs_matrix4x4 *m, float x,
         float y, float z) {
     SC_MatrixScale((Matrix4x4 *) m, x, y, z);
 }
 void __attribute__((overloadable)) rsMatrixTranslate(rs_matrix4x4 *m, float x,
         float y, float z) {
     SC_MatrixTranslate((Matrix4x4 *) m, x, y, z);
 }
 void __attribute__((overloadable)) rsMatrixLoadOrtho(rs_matrix4x4 *m, float l,
         float r, float b, float t, float n, float f) {
     SC_MatrixLoadOrtho((Matrix4x4 *) m, l, r, b, t, n, f);
 }
 void __attribute__((overloadable)) rsMatrixLoadFrustum(rs_matrix4x4 *m,
         float l, float r, float b, float t, float n, float f) {
     SC_MatrixLoadFrustum((Matrix4x4 *) m, l, r, b, t, n, f);
 }
 void __attribute__((overloadable)) rsMatrixLoadPerspective(rs_matrix4x4 *m,
         float fovy, float aspect, float near, float far) {
     SC_MatrixLoadPerspective((Matrix4x4 *) m, fovy, aspect, near, far);
 }
 bool __attribute__((overloadable)) rsMatrixInverse(rs_matrix4x4 *m) {
     return SC_MatrixInverse_4x4((Matrix4x4 *) m);
 }
 bool __attribute__((overloadable)) rsMatrixInverseTranspose(rs_matrix4x4 *m) {
     return SC_MatrixInverseTranspose_4x4((Matrix4x4 *) m);
 }
 void __attribute__((overloadable)) rsMatrixTranspose(rs_matrix4x4 *m) {
     SC_MatrixTranspose_4x4((Matrix4x4 *) m);
 }
 void __attribute__((overloadable)) rsMatrixTranspose(rs_matrix3x3 *m) {
     SC_MatrixTranspose_3x3((Matrix3x3 *) m);
 }
 void __attribute__((overloadable)) rsMatrixTranspose(rs_matrix2x2 *m) {
     SC_MatrixTranspose_2x2((Matrix2x2 *) m);
 }
	/*
	* Copyright (C) 2011-2012 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.
	*/

	#if !defined(RS_SERVER) && !defined(RS_COMPATIBILITY_LIB)
	#include <cutils/compiler.h>
	#endif

	#include "rsContext.h"
	#include "rsScriptC.h"
	#include "rsMatrix4x4.h"
	#include "rsMatrix3x3.h"
	#include "rsMatrix2x2.h"

	#include "rsCpuCore.h"
	#include "rsCpuScript.h"

	using namespace android;
	using namespace android::renderscript;

	#define EXPORT_F32_FN_F32(func) \
	float __attribute__((overloadable)) SC_##func(float v) { \
	return func(v); \
	}

	#define EXPORT_F32_FN_F32_F32(func) \
	float __attribute__((overloadable)) SC_##func(float t, float v) { \
	return func(t, v); \
	}

	//////////////////////////////////////////////////////////////////////////////
	// Float util
	//////////////////////////////////////////////////////////////////////////////

	// Handle missing Gingerbread functions like tgammaf.
	float SC_tgammaf(float x) {
	#ifdef RS_COMPATIBILITY_LIB
	return tgamma(x);
	#else
	return tgammaf(x);
	#endif
	}

	uint32_t SC_abs_i32(int32_t v) {return abs(v);}

	static void SC_MatrixLoadRotate(Matrix4x4 *m, float rot, float x, float y, float z) {
	m->loadRotate(rot, x, y, z);
	}
	static void SC_MatrixLoadScale(Matrix4x4 *m, float x, float y, float z) {
	m->loadScale(x, y, z);
	}
	static void SC_MatrixLoadTranslate(Matrix4x4 *m, float x, float y, float z) {
	m->loadTranslate(x, y, z);
	}
	static void SC_MatrixRotate(Matrix4x4 *m, float rot, float x, float y, float z) {
	m->rotate(rot, x, y, z);
	}
	static void SC_MatrixScale(Matrix4x4 *m, float x, float y, float z) {
	m->scale(x, y, z);
	}
	static void SC_MatrixTranslate(Matrix4x4 *m, float x, float y, float z) {
	m->translate(x, y, z);
	}

	static void SC_MatrixLoadOrtho(Matrix4x4 *m, float l, float r, float b, float t, float n, float f) {
	m->loadOrtho(l, r, b, t, n, f);
	}
	static void SC_MatrixLoadFrustum(Matrix4x4 *m, float l, float r, float b, float t, float n, float f) {
	m->loadFrustum(l, r, b, t, n, f);
	}
	static void SC_MatrixLoadPerspective(Matrix4x4 *m, float fovy, float aspect, float near, float far) {
	m->loadPerspective(fovy, aspect, near, far);
	}

	static bool SC_MatrixInverse_4x4(Matrix4x4 *m) {
	return m->inverse();
	}
	static bool SC_MatrixInverseTranspose_4x4(Matrix4x4 *m) {
	return m->inverseTranspose();
	}
	static void SC_MatrixTranspose_4x4(Matrix4x4 *m) {
	m->transpose();
	}
	static void SC_MatrixTranspose_3x3(Matrix3x3 *m) {
	m->transpose();
	}
	static void SC_MatrixTranspose_2x2(Matrix2x2 *m) {
	m->transpose();
	}

	float SC_randf2(float min, float max) {
	float r = (float)rand();
	r /= RAND_MAX;
	r = r * (max - min) + min;
	return r;
	}

	EXPORT_F32_FN_F32(acosf)
	EXPORT_F32_FN_F32(acoshf)
	EXPORT_F32_FN_F32(asinf)
	EXPORT_F32_FN_F32(asinhf)
	EXPORT_F32_FN_F32(atanf)
	EXPORT_F32_FN_F32_F32(atan2f)
	EXPORT_F32_FN_F32(atanhf)
	EXPORT_F32_FN_F32(cbrtf)
	EXPORT_F32_FN_F32(ceilf)
	EXPORT_F32_FN_F32_F32(copysignf)
	EXPORT_F32_FN_F32(cosf)
	EXPORT_F32_FN_F32(coshf)
	EXPORT_F32_FN_F32(erfcf)
	EXPORT_F32_FN_F32(erff)
	EXPORT_F32_FN_F32(expf)
	EXPORT_F32_FN_F32(exp2f)
	EXPORT_F32_FN_F32(expm1f)
	EXPORT_F32_FN_F32_F32(fdimf)
	EXPORT_F32_FN_F32(floorf)
	float SC_fmaf(float u, float t, float v) {return fmaf(u, t, v);}
	EXPORT_F32_FN_F32_F32(fmaxf)
	EXPORT_F32_FN_F32_F32(fminf)
	EXPORT_F32_FN_F32_F32(fmodf)
	float SC_frexpf(float v, int* ptr) {return frexpf(v, ptr);}
	EXPORT_F32_FN_F32_F32(hypotf)
	int SC_ilogbf(float v) {return ilogbf(v); }
	float SC_ldexpf(float v, int i) {return ldexpf(v, i);}
	EXPORT_F32_FN_F32(lgammaf)
	float SC_lgammaf_r(float v, int* ptr) {return lgammaf_r(v, ptr);}
	EXPORT_F32_FN_F32(logf)
	EXPORT_F32_FN_F32(log10f)
	EXPORT_F32_FN_F32(log1pf)
	EXPORT_F32_FN_F32(logbf)
	float SC_modff(float v, float* ptr) {return modff(v, ptr);}
	EXPORT_F32_FN_F32_F32(nextafterf)
	EXPORT_F32_FN_F32_F32(powf)
	EXPORT_F32_FN_F32_F32(remainderf)
	float SC_remquof(float t, float v, int* ptr) {return remquof(t, v, ptr);}
	EXPORT_F32_FN_F32(rintf)
	EXPORT_F32_FN_F32(roundf)
	EXPORT_F32_FN_F32(sinf)
	EXPORT_F32_FN_F32(sinhf)
	EXPORT_F32_FN_F32(sqrtf)
	EXPORT_F32_FN_F32(tanf)
	EXPORT_F32_FN_F32(tanhf)
	EXPORT_F32_FN_F32(truncf)
	void __attribute__((overloadable)) rsMatrixLoadRotate(rs_matrix4x4 *m,
	float rot, float x, float y, float z) {
	SC_MatrixLoadRotate((Matrix4x4 *) m, rot, x, y, z);
	}
	void __attribute__((overloadable)) rsMatrixLoadScale(rs_matrix4x4 *m,
	float x, float y, float z) {
	SC_MatrixLoadScale((Matrix4x4 *) m, x, y, z);
	}
	void __attribute__((overloadable)) rsMatrixLoadTranslate(rs_matrix4x4 *m,
	float x, float y, float z) {
	SC_MatrixLoadTranslate((Matrix4x4 *) m, x, y, z);
	}
	void __attribute__((overloadable)) rsMatrixRotate(rs_matrix4x4 *m, float rot,
	float x, float y, float z) {
	SC_MatrixRotate((Matrix4x4 *) m, rot, x, y, z);
	}
	void __attribute__((overloadable)) rsMatrixScale(rs_matrix4x4 *m, float x,
	float y, float z) {
	SC_MatrixScale((Matrix4x4 *) m, x, y, z);
	}
	void __attribute__((overloadable)) rsMatrixTranslate(rs_matrix4x4 *m, float x,
	float y, float z) {
	SC_MatrixTranslate((Matrix4x4 *) m, x, y, z);
	}
	void __attribute__((overloadable)) rsMatrixLoadOrtho(rs_matrix4x4 *m, float l,
	float r, float b, float t, float n, float f) {
	SC_MatrixLoadOrtho((Matrix4x4 *) m, l, r, b, t, n, f);
	}
	void __attribute__((overloadable)) rsMatrixLoadFrustum(rs_matrix4x4 *m,
	float l, float r, float b, float t, float n, float f) {
	SC_MatrixLoadFrustum((Matrix4x4 *) m, l, r, b, t, n, f);
	}
	void __attribute__((overloadable)) rsMatrixLoadPerspective(rs_matrix4x4 *m,
	float fovy, float aspect, float near, float far) {
	SC_MatrixLoadPerspective((Matrix4x4 *) m, fovy, aspect, near, far);
	}
	bool __attribute__((overloadable)) rsMatrixInverse(rs_matrix4x4 *m) {
	return SC_MatrixInverse_4x4((Matrix4x4 *) m);
	}
	bool __attribute__((overloadable)) rsMatrixInverseTranspose(rs_matrix4x4 *m) {
	return SC_MatrixInverseTranspose_4x4((Matrix4x4 *) m);
	}
	void __attribute__((overloadable)) rsMatrixTranspose(rs_matrix4x4 *m) {
	SC_MatrixTranspose_4x4((Matrix4x4 *) m);
	}
	void __attribute__((overloadable)) rsMatrixTranspose(rs_matrix3x3 *m) {
	SC_MatrixTranspose_3x3((Matrix3x3 *) m);
	}
	void __attribute__((overloadable)) rsMatrixTranspose(rs_matrix2x2 *m) {
	SC_MatrixTranspose_2x2((Matrix2x2 *) m);
	}