#include "rs_core.rsh" #include "rs_structs.h" // Opaque Allocation type operations extern uint32_t __attribute__((overloadable)) rsAllocationGetDimX(rs_allocation a) { Allocation_t *alloc = (Allocation_t *)a.p; return alloc->mHal.drvState.lod[0].dimX; } extern uint32_t __attribute__((overloadable)) rsAllocationGetDimY(rs_allocation a) { Allocation_t *alloc = (Allocation_t *)a.p; return alloc->mHal.drvState.lod[0].dimY; } extern uint32_t __attribute__((overloadable)) rsAllocationGetDimZ(rs_allocation a) { Allocation_t *alloc = (Allocation_t *)a.p; return alloc->mHal.drvState.lod[0].dimZ; } extern uint32_t __attribute__((overloadable)) rsAllocationGetDimLOD(rs_allocation a) { Allocation_t *alloc = (Allocation_t *)a.p; return alloc->mHal.state.hasMipmaps; } extern uint32_t __attribute__((overloadable)) rsAllocationGetDimFaces(rs_allocation a) { Allocation_t *alloc = (Allocation_t *)a.p; return alloc->mHal.state.hasFaces; } extern rs_element __attribute__((overloadable)) rsAllocationGetElement(rs_allocation a) { Allocation_t *alloc = (Allocation_t *)a.p; if (alloc == NULL) { rs_element nullElem = {0}; return nullElem; } Type_t *type = (Type_t *)alloc->mHal.state.type; rs_element returnElem = {type->mHal.state.element}; rs_element rs_retval = {0}; rsSetObject(&rs_retval, returnElem); return rs_retval; } // TODO: this needs to be optimized, obviously static void memcpy(void* dst, const void* src, size_t size) { char* dst_c = (char*) dst; const char* src_c = (const char*) src; for (; size > 0; size--) { *dst_c++ = *src_c++; } } #ifdef RS_DEBUG_RUNTIME #define ELEMENT_AT(T) \ extern void __attribute__((overloadable)) \ rsSetElementAt_##T(rs_allocation a, const T *val, uint32_t x); \ extern void __attribute__((overloadable)) \ rsSetElementAt_##T(rs_allocation a, const T *val, uint32_t x, uint32_t y); \ extern void __attribute__((overloadable)) \ rsSetElementAt_##T(rs_allocation a, const T *val, uint32_t x, uint32_t y, uint32_t z); \ extern void __attribute__((overloadable)) \ rsGetElementAt_##T(rs_allocation a, T *val, uint32_t x); \ extern void __attribute__((overloadable)) \ rsGetElementAt_##T(rs_allocation a, T *val, uint32_t x, uint32_t y); \ extern void __attribute__((overloadable)) \ rsGetElementAt_##T(rs_allocation a, T *val, uint32_t x, uint32_t y, uint32_t z); \ \ extern void __attribute__((overloadable)) \ rsSetElementAt_##T(rs_allocation a, T val, uint32_t x) { \ rsSetElementAt_##T(a, &val, x); \ } \ extern void __attribute__((overloadable)) \ rsSetElementAt_##T(rs_allocation a, T val, uint32_t x, uint32_t y) { \ rsSetElementAt_##T(a, &val, x, y); \ } \ extern void __attribute__((overloadable)) \ rsSetElementAt_##T(rs_allocation a, T val, uint32_t x, uint32_t y, uint32_t z) { \ rsSetElementAt_##T(a, &val, x, y, z); \ } \ extern T __attribute__((overloadable)) \ rsGetElementAt_##T(rs_allocation a, uint32_t x) { \ T tmp; \ rsGetElementAt_##T(a, &tmp, x); \ return tmp; \ } \ extern T __attribute__((overloadable)) \ rsGetElementAt_##T(rs_allocation a, uint32_t x, uint32_t y) { \ T tmp; \ rsGetElementAt_##T(a, &tmp, x, y); \ return tmp; \ } \ extern T __attribute__((overloadable)) \ rsGetElementAt_##T(rs_allocation a, uint32_t x, uint32_t y, uint32_t z) { \ T tmp; \ rsGetElementAt_##T(a, &tmp, x, y, z); \ return tmp; \ } #else uint8_t* rsOffset(rs_allocation a, uint32_t sizeOf, uint32_t x, uint32_t y, uint32_t z) { Allocation_t *alloc = (Allocation_t *)a.p; //#ifdef __LP64__ // uint8_t *p = (uint8_t *)a.r; //#else uint8_t *p = (uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; //#endif const uint32_t stride = (uint32_t)alloc->mHal.drvState.lod[0].stride; const uint32_t dimY = alloc->mHal.drvState.lod[0].dimY; uint8_t *dp = &p[(sizeOf * x) + (y * stride) + (z * stride * dimY)]; return dp; } uint8_t* rsOffsetNs(rs_allocation a, uint32_t x, uint32_t y, uint32_t z) { Allocation_t *alloc = (Allocation_t *)a.p; //#ifdef __LP64__ // uint8_t *p = (uint8_t *)a.r; //#else uint8_t *p = (uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; //#endif const uint32_t stride = alloc->mHal.drvState.lod[0].stride; const uint32_t dimY = alloc->mHal.drvState.lod[0].dimY; const uint32_t sizeOf = alloc->mHal.state.elementSizeBytes;; uint8_t *dp = &p[(sizeOf * x) + (y * stride) + (z * stride * dimY)]; return dp; } // The functions rsSetElementAtImpl_T and rsGetElementAtImpl_T are implemented in bitcode // in ll32/allocation.ll and ll64/allocation.ll. To be able to provide debug info for // these functions define them here instead, if we are linking with the debug library. #ifdef RS_G_RUNTIME #define SET_ELEMENT_AT_IMPL_TYPE_SIZE(typename, size) \ void rsSetElementAtImpl_##typename \ (rs_allocation a, typename val, uint32_t x, uint32_t y, uint32_t z) { \ typename* val_ptr = (typename*)rsOffset(a, size, x, y, z); \ *val_ptr = val; \ } #define GET_ELEMENT_AT_IMPL_TYPE_SIZE(typename, size) \ typename rsGetElementAtImpl_##typename \ (rs_allocation a, uint32_t x, uint32_t y, uint32_t z) { \ typename *val_ptr = (typename*)rsOffset(a, size, x, y, z); \ return *val_ptr; \ } #define SET_ELEMENT_AT_IMPL_TYPE(typename) \ SET_ELEMENT_AT_IMPL_TYPE_SIZE(typename, sizeof(typename)) \ SET_ELEMENT_AT_IMPL_TYPE_SIZE(typename##2, sizeof(typename)*2) \ SET_ELEMENT_AT_IMPL_TYPE_SIZE(typename##3, sizeof(typename)*4) \ SET_ELEMENT_AT_IMPL_TYPE_SIZE(typename##4, sizeof(typename)*4) #define GET_ELEMENT_AT_IMPL_TYPE(typename) \ GET_ELEMENT_AT_IMPL_TYPE_SIZE(typename, sizeof(typename)) \ GET_ELEMENT_AT_IMPL_TYPE_SIZE(typename##2, sizeof(typename)*2) \ GET_ELEMENT_AT_IMPL_TYPE_SIZE(typename##3, sizeof(typename)*4) \ GET_ELEMENT_AT_IMPL_TYPE_SIZE(typename##4, sizeof(typename)*4) #define ELEMENT_AT_IMPL_TYPE(typename) \ SET_ELEMENT_AT_IMPL_TYPE(typename) \ GET_ELEMENT_AT_IMPL_TYPE(typename) ELEMENT_AT_IMPL_TYPE(char) ELEMENT_AT_IMPL_TYPE(uchar) ELEMENT_AT_IMPL_TYPE(short) ELEMENT_AT_IMPL_TYPE(ushort) ELEMENT_AT_IMPL_TYPE(int) ELEMENT_AT_IMPL_TYPE(uint) ELEMENT_AT_IMPL_TYPE(long) ELEMENT_AT_IMPL_TYPE(ulong) ELEMENT_AT_IMPL_TYPE(half) ELEMENT_AT_IMPL_TYPE(float) ELEMENT_AT_IMPL_TYPE(double) #undef ELEMENT_AT_IMPL_TYPE #undef GET_ELEMENT_AT_IMPL_TYPE #undef SET_ELEMENT_AT_IMPL_TYPE #undef GET_ELEMENT_AT_IMPL_TYPE_SIZE #undef SET_ELEMENT_AT_IMPL_TYPE_SIZE #define SET_ELEMENT_AT_TYPE_IMPL(T, typename) /* nothing */ #define GET_ELEMENT_AT_TYPE_IMPL(T, typename) /* nothing */ #else #define SET_ELEMENT_AT_TYPE_IMPL(T, typename) \ void \ rsSetElementAtImpl_##typename(rs_allocation a, typename val, uint32_t x, \ uint32_t y, uint32_t z); #define GET_ELEMENT_AT_TYPE_IMPL(T, typename) \ typename \ rsGetElementAtImpl_##typename(rs_allocation a, uint32_t x, uint32_t y, \ uint32_t z); #endif //RS_G_RUNTIME #define SET_ELEMENT_AT_TYPE_DEF(T, typename) \ extern void __attribute__((overloadable)) \ rsSetElementAt_##typename(rs_allocation a, T val, uint32_t x) { \ rsSetElementAtImpl_##typename(a, (typename)val, x, 0, 0); \ } \ \ extern void __attribute__((overloadable)) \ rsSetElementAt_##typename(rs_allocation a, T val, uint32_t x, \ uint32_t y) { \ rsSetElementAtImpl_##typename(a, (typename)val, x, y, 0); \ } \ \ extern void __attribute__((overloadable)) \ rsSetElementAt_##typename(rs_allocation a, T val, uint32_t x, uint32_t y, \ uint32_t z) { \ rsSetElementAtImpl_##typename(a, (typename)val, x, y, z); \ } #define GET_ELEMENT_AT_TYPE_DEF(T, typename) \ extern typename __attribute__((overloadable)) \ rsGetElementAt_##typename(rs_allocation a, uint32_t x) { \ return (typename)rsGetElementAtImpl_##typename(a, x, 0, 0); \ } \ \ extern typename __attribute__((overloadable)) \ rsGetElementAt_##typename(rs_allocation a, uint32_t x, uint32_t y) { \ return (typename)rsGetElementAtImpl_##typename(a, x, y, 0); \ } \ \ extern typename __attribute__((overloadable)) \ rsGetElementAt_##typename(rs_allocation a, uint32_t x, uint32_t y, \ uint32_t z) { \ return (typename)rsGetElementAtImpl_##typename(a, x, y, z); \ } #define SET_ELEMENT_AT(T) SET_ELEMENT_AT_TYPE_IMPL(T, T) \ SET_ELEMENT_AT_TYPE_DEF(T, T) #define GET_ELEMENT_AT(T) GET_ELEMENT_AT_TYPE_IMPL(T, T) \ GET_ELEMENT_AT_TYPE_DEF(T, T) #define ELEMENT_AT(T) \ SET_ELEMENT_AT(T) \ GET_ELEMENT_AT(T) extern const void * __attribute__((overloadable)) rsGetElementAt(rs_allocation a, uint32_t x) { Allocation_t *alloc = (Allocation_t *)a.p; const uint8_t *p = (const uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; const uint32_t eSize = alloc->mHal.state.elementSizeBytes; return &p[eSize * x]; } extern const void * __attribute__((overloadable)) rsGetElementAt(rs_allocation a, uint32_t x, uint32_t y) { Allocation_t *alloc = (Allocation_t *)a.p; const uint8_t *p = (const uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; const uint32_t eSize = alloc->mHal.state.elementSizeBytes; const uint32_t stride = alloc->mHal.drvState.lod[0].stride; return &p[(eSize * x) + (y * stride)]; } extern const void * __attribute__((overloadable)) rsGetElementAt(rs_allocation a, uint32_t x, uint32_t y, uint32_t z) { Allocation_t *alloc = (Allocation_t *)a.p; const uint8_t *p = (const uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; const uint32_t eSize = alloc->mHal.state.elementSizeBytes; const uint32_t stride = alloc->mHal.drvState.lod[0].stride; const uint32_t dimY = alloc->mHal.drvState.lod[0].dimY; return &p[(eSize * x) + (y * stride) + (z * stride * dimY)]; } extern void __attribute__((overloadable)) rsSetElementAt(rs_allocation a, void* ptr, uint32_t x) { Allocation_t *alloc = (Allocation_t *)a.p; const uint8_t *p = (const uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; const uint32_t eSize = alloc->mHal.state.elementSizeBytes; memcpy((void*)&p[eSize * x], ptr, eSize); } extern void __attribute__((overloadable)) rsSetElementAt(rs_allocation a, void* ptr, uint32_t x, uint32_t y) { Allocation_t *alloc = (Allocation_t *)a.p; const uint8_t *p = (const uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; const uint32_t eSize = alloc->mHal.state.elementSizeBytes; const uint32_t stride = alloc->mHal.drvState.lod[0].stride; memcpy((void*)&p[(eSize * x) + (y * stride)], ptr, eSize); } extern void __attribute__((overloadable)) rsSetElementAt(rs_allocation a, void* ptr, uint32_t x, uint32_t y, uint32_t z) { Allocation_t *alloc = (Allocation_t *)a.p; const uint8_t *p = (const uint8_t *)alloc->mHal.drvState.lod[0].mallocPtr; const uint32_t eSize = alloc->mHal.state.elementSizeBytes; const uint32_t stride = alloc->mHal.drvState.lod[0].stride; const uint32_t dimY = alloc->mHal.drvState.lod[0].dimY; memcpy((void*)&p[(eSize * x) + (y * stride) + (z * stride * dimY)], ptr, eSize); } #endif // RS_DEBUG_RUNTIME ELEMENT_AT(char) ELEMENT_AT(char2) ELEMENT_AT(char3) ELEMENT_AT(char4) ELEMENT_AT(uchar) ELEMENT_AT(uchar2) ELEMENT_AT(uchar3) ELEMENT_AT(uchar4) ELEMENT_AT(short) ELEMENT_AT(short2) ELEMENT_AT(short3) ELEMENT_AT(short4) ELEMENT_AT(ushort) ELEMENT_AT(ushort2) ELEMENT_AT(ushort3) ELEMENT_AT(ushort4) ELEMENT_AT(int) ELEMENT_AT(int2) ELEMENT_AT(int3) ELEMENT_AT(int4) ELEMENT_AT(uint) ELEMENT_AT(uint2) ELEMENT_AT(uint3) ELEMENT_AT(uint4) ELEMENT_AT(long) ELEMENT_AT(long2) ELEMENT_AT(long3) ELEMENT_AT(long4) ELEMENT_AT(ulong) ELEMENT_AT(ulong2) ELEMENT_AT(ulong3) ELEMENT_AT(ulong4) ELEMENT_AT(half) ELEMENT_AT(half2) ELEMENT_AT(half3) ELEMENT_AT(half4) ELEMENT_AT(float) ELEMENT_AT(float2) ELEMENT_AT(float3) ELEMENT_AT(float4) ELEMENT_AT(double) ELEMENT_AT(double2) ELEMENT_AT(double3) ELEMENT_AT(double4) typedef unsigned long long ull; typedef unsigned long long ull2 __attribute__((ext_vector_type(2))); typedef unsigned long long ull3 __attribute__((ext_vector_type(3))); typedef unsigned long long ull4 __attribute__((ext_vector_type(4))); #ifndef RS_DEBUG_RUNTIME SET_ELEMENT_AT_TYPE_IMPL(ull, ulong) SET_ELEMENT_AT_TYPE_IMPL(ull2, ulong2) SET_ELEMENT_AT_TYPE_IMPL(ull3, ulong3) SET_ELEMENT_AT_TYPE_IMPL(ull4, ulong4) #undef SET_ELEMENT_AT_TYPE_DEF #undef GET_ELEMENT_AT_TYPE_DEF #undef SET_ELEMENT_AT_TYPE_IMPL #undef GET_ELEMENT_AT_TYPE_IMPL #undef ELEMENT_AT_TYPE #endif #undef ELEMENT_AT extern uchar __attribute__((overloadable)) rsGetElementAtYuv_uchar_Y(rs_allocation a, uint32_t x, uint32_t y) { return rsGetElementAt_uchar(a, x, y); } extern uchar __attribute__((overloadable)) rsGetElementAtYuv_uchar_U(rs_allocation a, uint32_t x, uint32_t y) { Allocation_t *alloc = (Allocation_t *)a.p; const size_t cstep = alloc->mHal.drvState.yuv.step; const size_t shift = alloc->mHal.drvState.yuv.shift; const size_t stride = alloc->mHal.drvState.lod[1].stride; const uchar *pin = (const uchar *)alloc->mHal.drvState.lod[1].mallocPtr; return pin[((x >> shift) * cstep) + ((y >> shift) * stride)]; } extern uchar __attribute__((overloadable)) rsGetElementAtYuv_uchar_V(rs_allocation a, uint32_t x, uint32_t y) { Allocation_t *alloc = (Allocation_t *)a.p; const size_t cstep = alloc->mHal.drvState.yuv.step; const size_t shift = alloc->mHal.drvState.yuv.shift; const size_t stride = alloc->mHal.drvState.lod[2].stride; const uchar *pin = (const uchar *)alloc->mHal.drvState.lod[2].mallocPtr; return pin[((x >> shift) * cstep) + ((y >> shift) * stride)]; } // The functions rsAllocationVLoadXImpl_T and rsAllocationVStoreXImpl_T are implemented in // bitcode in ll32/allocation.ll and ll64/allocation.ll. To be able to provide debug info // for these functions define them here instead, if we are linking with the debug library. #ifdef RS_G_RUNTIME #define VOP_IMPL(T) \ void __rsAllocationVStoreXImpl_##T \ (rs_allocation a, const T val, uint32_t x, uint32_t y, uint32_t z) {\ T *val_ptr = (T*)rsOffsetNs(a, x, y, z); \ memcpy(val_ptr, &val, sizeof(T)); \ } \ T __rsAllocationVLoadXImpl_##T \ (rs_allocation a, uint32_t x, uint32_t y, uint32_t z) { \ T result = {}; \ T* val_ptr = (T*)rsOffsetNs(a, x, y, z); \ memcpy(&result, val_ptr, sizeof(T)); \ return result; \ } #else #define VOP_IMPL(T) \ extern void __rsAllocationVStoreXImpl_##T(rs_allocation a, const T val, uint32_t x, uint32_t y, uint32_t z); \ extern T __rsAllocationVLoadXImpl_##T(rs_allocation a, uint32_t x, uint32_t y, uint32_t z); #endif // RS_G_RUNTIME #define VOP_DEF(T) \ extern void __attribute__((overloadable)) \ rsAllocationVStoreX_##T(rs_allocation a, T val, uint32_t x) { \ __rsAllocationVStoreXImpl_##T(a, val, x, 0, 0); \ } \ extern void __attribute__((overloadable)) \ rsAllocationVStoreX_##T(rs_allocation a, T val, uint32_t x, uint32_t y) { \ __rsAllocationVStoreXImpl_##T(a, val, x, y, 0); \ } \ extern void __attribute__((overloadable)) \ rsAllocationVStoreX_##T(rs_allocation a, T val, uint32_t x, uint32_t y, uint32_t z) { \ __rsAllocationVStoreXImpl_##T(a, val, x, y, z); \ } \ extern T __attribute__((overloadable)) \ rsAllocationVLoadX_##T(rs_allocation a, uint32_t x) { \ return __rsAllocationVLoadXImpl_##T(a, x, 0, 0); \ } \ extern T __attribute__((overloadable)) \ rsAllocationVLoadX_##T(rs_allocation a, uint32_t x, uint32_t y) { \ return __rsAllocationVLoadXImpl_##T(a, x, y, 0); \ } \ extern T __attribute__((overloadable)) \ rsAllocationVLoadX_##T(rs_allocation a, uint32_t x, uint32_t y, uint32_t z) { \ return __rsAllocationVLoadXImpl_##T(a, x, y, z); \ } #define VOP(T) VOP_IMPL(T) \ VOP_DEF(T) VOP(char2) VOP(char3) VOP(char4) VOP(uchar2) VOP(uchar3) VOP(uchar4) VOP(short2) VOP(short3) VOP(short4) VOP(ushort2) VOP(ushort3) VOP(ushort4) VOP(int2) VOP(int3) VOP(int4) VOP(uint2) VOP(uint3) VOP(uint4) VOP(long2) VOP(long3) VOP(long4) VOP(ulong2) VOP(ulong3) VOP(ulong4) VOP(float2) VOP(float3) VOP(float4) VOP(double2) VOP(double3) VOP(double4) #undef VOP_IMPL #undef VOP_DEF #undef VOP static const rs_element kInvalidElement = {0}; extern rs_element __attribute__((overloadable)) rsCreateElement( int32_t dt, int32_t dk, bool isNormalized, uint32_t vecSize); extern rs_type __attribute__((overloadable)) rsCreateType( rs_element element, uint32_t dimX, uint32_t dimY, uint32_t dimZ, bool mipmaps, bool faces, rs_yuv_format yuv_format); extern rs_allocation __attribute__((overloadable)) rsCreateAllocation( rs_type type, rs_allocation_mipmap_control mipmaps, uint32_t usages, void *ptr); rs_element __attribute__((overloadable)) rsCreateElement( rs_data_type data_type) { switch (data_type) { case RS_TYPE_BOOLEAN: case RS_TYPE_FLOAT_16: case RS_TYPE_FLOAT_32: case RS_TYPE_FLOAT_64: case RS_TYPE_SIGNED_8: case RS_TYPE_SIGNED_16: case RS_TYPE_SIGNED_32: case RS_TYPE_SIGNED_64: case RS_TYPE_UNSIGNED_8: case RS_TYPE_UNSIGNED_16: case RS_TYPE_UNSIGNED_32: case RS_TYPE_UNSIGNED_64: case RS_TYPE_MATRIX_4X4: case RS_TYPE_MATRIX_3X3: case RS_TYPE_MATRIX_2X2: case RS_TYPE_ELEMENT: case RS_TYPE_TYPE: case RS_TYPE_ALLOCATION: case RS_TYPE_SCRIPT: return rsCreateElement(data_type, RS_KIND_USER, false, 1); default: rsDebug("Invalid data_type", data_type); return kInvalidElement; } } rs_element __attribute__((overloadable)) rsCreateVectorElement( rs_data_type data_type, uint32_t vector_width) { if (vector_width < 2 || vector_width > 4) { rsDebug("Invalid vector_width", vector_width); return kInvalidElement; } switch (data_type) { case RS_TYPE_BOOLEAN: case RS_TYPE_FLOAT_16: case RS_TYPE_FLOAT_32: case RS_TYPE_FLOAT_64: case RS_TYPE_SIGNED_8: case RS_TYPE_SIGNED_16: case RS_TYPE_SIGNED_32: case RS_TYPE_SIGNED_64: case RS_TYPE_UNSIGNED_8: case RS_TYPE_UNSIGNED_16: case RS_TYPE_UNSIGNED_32: case RS_TYPE_UNSIGNED_64: return rsCreateElement(data_type, RS_KIND_USER, false, vector_width); default: rsDebug("Invalid data_type for vector element", data_type); return kInvalidElement; } } rs_element __attribute__((overloadable)) rsCreatePixelElement( rs_data_type data_type, rs_data_kind data_kind) { if (data_type != RS_TYPE_UNSIGNED_8 && data_type != RS_TYPE_UNSIGNED_16 && data_type != RS_TYPE_UNSIGNED_5_6_5 && data_type != RS_TYPE_UNSIGNED_4_4_4_4 && data_type != RS_TYPE_UNSIGNED_5_5_5_1) { rsDebug("Invalid data_type for pixel element", data_type); return kInvalidElement; } if (data_kind != RS_KIND_PIXEL_L && data_kind != RS_KIND_PIXEL_A && data_kind != RS_KIND_PIXEL_LA && data_kind != RS_KIND_PIXEL_RGB && data_kind != RS_KIND_PIXEL_RGBA && data_kind != RS_KIND_PIXEL_DEPTH && data_kind != RS_KIND_PIXEL_YUV) { rsDebug("Invalid data_kind for pixel element", data_type); return kInvalidElement; } if (data_type == RS_TYPE_UNSIGNED_5_6_5 && data_kind != RS_KIND_PIXEL_RGB) { rsDebug("Bad data_type and data_kind combo", data_type, data_kind); return kInvalidElement; } if (data_type == RS_TYPE_UNSIGNED_5_5_5_1 && data_kind != RS_KIND_PIXEL_RGBA) { rsDebug("Bad data_type and data_kind combo", data_type, data_kind); return kInvalidElement; } if (data_type == RS_TYPE_UNSIGNED_4_4_4_4 && data_kind != RS_KIND_PIXEL_RGBA) { rsDebug("Bad data_type and data_kind combo", data_type, data_kind); return kInvalidElement; } if (data_type == RS_TYPE_UNSIGNED_16 && data_kind != RS_KIND_PIXEL_DEPTH) { rsDebug("Bad data_type and data_kind combo", data_type, data_kind); return kInvalidElement; } int vector_width = 1; switch (data_kind) { case RS_KIND_PIXEL_LA: vector_width = 2; break; case RS_KIND_PIXEL_RGB: vector_width = 3; break; case RS_KIND_PIXEL_RGBA: vector_width = 4; break; case RS_KIND_PIXEL_DEPTH: vector_width = 2; break; default: break; } return rsCreateElement(data_type, data_kind, true, vector_width); } rs_type __attribute__((overloadable)) rsCreateType(rs_element element, uint32_t dimX, uint32_t dimY, uint32_t dimZ) { return rsCreateType(element, dimX, dimY, dimZ, false, false, RS_YUV_NONE); } rs_type __attribute__((overloadable)) rsCreateType(rs_element element, uint32_t dimX, uint32_t dimY) { return rsCreateType(element, dimX, dimY, 0, false, false, RS_YUV_NONE); } rs_type __attribute__((overloadable)) rsCreateType(rs_element element, uint32_t dimX) { return rsCreateType(element, dimX, 0, 0, false, false, RS_YUV_NONE); } rs_allocation __attribute__((overloadable)) rsCreateAllocation(rs_type type, uint32_t usage) { return rsCreateAllocation(type, RS_ALLOCATION_MIPMAP_NONE, usage, NULL); } rs_allocation __attribute__((overloadable)) rsCreateAllocation(rs_type type) { return rsCreateAllocation(type, RS_ALLOCATION_MIPMAP_NONE, RS_ALLOCATION_USAGE_SCRIPT, NULL); }