/* * Copyright (C) 2015 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. */ // Don't edit this file! It is auto-generated by frameworks/rs/api/generate.sh. /* * rs_object_info.rsh: Object Characteristics Functions * * The functions below can be used to query the characteristics of an Allocation, Element, * or Sampler object. These objects are created from Java. You can't create them from a * script. * * Allocations: * * Allocations are the primary method used to pass data to and from RenderScript kernels. * * They are a structured collection of cells that can be used to store bitmaps, textures, * arbitrary data points, etc. * * This collection of cells may have many dimensions (X, Y, Z, Array0, Array1, Array2, Array3), * faces (for cubemaps), and level of details (for mipmapping). * * See the android.renderscript.Allocation for details on to create Allocations. * * Elements: * * The term "element" is used a bit ambiguously in RenderScript, as both type information * for the cells of an Allocation and the instantiation of that type. For example: * - rs_element is a handle to a type specification, and * - In functions like rsGetElementAt(), "element" means the instantiation of the type, * i.e. a cell of an Allocation. * * The functions below let you query the characteristics of the type specificiation. * * An Element can specify a simple data types as found in C, e.g. an integer, float, or * boolean. It can also specify a handle to a RenderScript object. See rs_data_type for * a list of basic types. * * Elements can specify fixed size vector (of size 2, 3, or 4) versions of the basic types. * Elements can be grouped together into complex Elements, creating the equivalent of * C structure definitions. * * Elements can also have a kind, which is semantic information used to interpret pixel * data. See rs_data_kind. * * When creating Allocations of common elements, you can simply use one of the many predefined * Elements like F32_2. * * To create complex Elements, use the Element.Builder Java class. * * Samplers: * * Samplers objects define how Allocations can be read as structure within a kernel. * See android.renderscript.S. */ #ifndef RENDERSCRIPT_RS_OBJECT_INFO_RSH #define RENDERSCRIPT_RS_OBJECT_INFO_RSH /* * rsAllocationGetDimFaces: Presence of more than one face * * If the Allocation is a cubemap, this function returns 1 if there's more than one face * present. In all other cases, it returns 0. * * Use rsGetDimHasFaces() to get the dimension of a currently running kernel. * * Returns: Returns 1 if more than one face is present, 0 otherwise. */ extern uint32_t __attribute__((overloadable)) rsAllocationGetDimFaces(rs_allocation a); /* * rsAllocationGetDimLOD: Presence of levels of detail * * Query an Allocation for the presence of more than one Level Of Detail. This is useful * for mipmaps. * * Use rsGetDimLod() to get the dimension of a currently running kernel. * * Returns: Returns 1 if more than one LOD is present, 0 otherwise. */ extern uint32_t __attribute__((overloadable)) rsAllocationGetDimLOD(rs_allocation a); /* * rsAllocationGetDimX: Size of the X dimension * * Returns the size of the X dimension of the Allocation. * * Use rsGetDimX() to get the dimension of a currently running kernel. * * Returns: X dimension of the Allocation. */ extern uint32_t __attribute__((overloadable)) rsAllocationGetDimX(rs_allocation a); /* * rsAllocationGetDimY: Size of the Y dimension * * Returns the size of the Y dimension of the Allocation. If the Allocation has less * than two dimensions, returns 0. * * Use rsGetDimY() to get the dimension of a currently running kernel. * * Returns: Y dimension of the Allocation. */ extern uint32_t __attribute__((overloadable)) rsAllocationGetDimY(rs_allocation a); /* * rsAllocationGetDimZ: Size of the Z dimension * * Returns the size of the Z dimension of the Allocation. If the Allocation has less * than three dimensions, returns 0. * * Use rsGetDimZ() to get the dimension of a currently running kernel. * * Returns: Z dimension of the Allocation. */ extern uint32_t __attribute__((overloadable)) rsAllocationGetDimZ(rs_allocation a); /* * rsAllocationGetElement: Get the object that describes the cell of an Allocation * * Get the Element object describing the type, kind, and other characteristics of a cell * of an Allocation. See the rsElement* functions below. * * Parameters: * a: Allocation to get data from. * * Returns: Element describing Allocation layout. */ extern rs_element __attribute__((overloadable)) rsAllocationGetElement(rs_allocation a); /* * rsClearObject: Release an object * * Tells the run time that this handle will no longer be used to access the the related * object. If this was the last handle to that object, resource recovery may happen. * * After calling this function, *dst will be set to an empty handle. See rsIsObject(). */ extern void __attribute__((overloadable)) rsClearObject(rs_element* dst); extern void __attribute__((overloadable)) rsClearObject(rs_type* dst); extern void __attribute__((overloadable)) rsClearObject(rs_allocation* dst); extern void __attribute__((overloadable)) rsClearObject(rs_sampler* dst); extern void __attribute__((overloadable)) rsClearObject(rs_script* dst); /* * rsIsObject: Check for an empty handle * * Returns true if the handle contains a non-null reference. * * This function does not validate that the internal pointer used in the handle * points to an actual valid object; it only checks for null. * * This function can be used to check the Element returned by rsElementGetSubElement() * or see if rsClearObject() has been called on a handle. */ extern bool __attribute__((overloadable)) rsIsObject(rs_element v); extern bool __attribute__((overloadable)) rsIsObject(rs_type v); extern bool __attribute__((overloadable)) rsIsObject(rs_allocation v); extern bool __attribute__((overloadable)) rsIsObject(rs_sampler v); extern bool __attribute__((overloadable)) rsIsObject(rs_script v); /* * rsElementGetBytesSize: Size of an Element * * Returns the size in bytes that an instantiation of this Element will occupy. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern uint32_t __attribute__((overloadable)) rsElementGetBytesSize(rs_element e); #endif /* * rsElementGetDataKind: Kind of an Element * * Returns the Element's data kind. This is used to interpret pixel data. * * See rs_data_kind. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern rs_data_kind __attribute__((overloadable)) rsElementGetDataKind(rs_element e); #endif /* * rsElementGetDataType: Data type of an Element * * Returns the Element's base data type. This can be a type similar to C/C++ (e.g. * RS_TYPE_UNSIGNED_8), a handle (e.g. RS_TYPE_ALLOCATION and RS_TYPE_ELEMENT), or a * more complex numerical type (e.g. RS_TYPE_UNSIGNED_5_6_5 and RS_TYPE_MATRIX_4X4). * See rs_data_type. * * If the Element describes a vector, this function returns the data type of one of its items. * Use rsElementGetVectorSize to get the size of the vector. * * If the Element describes a structure, RS_TYPE_NONE is returned. Use the rsElementGetSub* * functions to explore this complex Element. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern rs_data_type __attribute__((overloadable)) rsElementGetDataType(rs_element e); #endif /* * rsElementGetSubElement: Sub-element of a complex Element * * For Elements that represents a structure, this function returns the sub-element at the * specified index. * * If the Element is not a structure or the index is greater or equal to the number of * sub-elements, an invalid handle is returned. * * Parameters: * e: Element to query. * index: Index of the sub-element to return. * * Returns: Sub-element at the given index. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern rs_element __attribute__((overloadable)) rsElementGetSubElement(rs_element e, uint32_t index); #endif /* * rsElementGetSubElementArraySize: Array size of a sub-element of a complex Element * * For complex Elements, sub-elements can be statically sized arrays. This function * returns the array size of the sub-element at the index. This sub-element repetition * is different than fixed size vectors. * * Parameters: * e: Element to query. * index: Index of the sub-element. * * Returns: Array size of the sub-element. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern uint32_t __attribute__((overloadable)) rsElementGetSubElementArraySize(rs_element e, uint32_t index); #endif /* * rsElementGetSubElementCount: Number of sub-elements * * Elements can be simple, such as an int or a float, or a structure with multiple * sub-elements. This function returns zero for simple Elements and the number of * sub-elements for complex Elements. * * Parameters: * e: Element to get data from. * * Returns: Number of sub-elements. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern uint32_t __attribute__((overloadable)) rsElementGetSubElementCount(rs_element e); #endif /* * rsElementGetSubElementName: Name of a sub-element * * For complex Elements, this function returns the name of the sub-element at the * specified index. * * Parameters: * e: Element to get data from. * index: Index of the sub-element. * name: Address of the array to store the name into. * nameLength: Length of the provided name array. * * Returns: Number of characters copied, excluding the null terminator. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern uint32_t __attribute__((overloadable)) rsElementGetSubElementName(rs_element e, uint32_t index, char* name, uint32_t nameLength); #endif /* * rsElementGetSubElementNameLength: Length of the name of a sub-element * * For complex Elements, this function returns the length of the name of the sub-element * at the specified index. * * Parameters: * e: Element to get data from. * index: Index of the sub-element. * * Returns: Length of the sub-element name including the null terminator. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern uint32_t __attribute__((overloadable)) rsElementGetSubElementNameLength(rs_element e, uint32_t index); #endif /* * rsElementGetSubElementOffsetBytes: Offset of the instantiated sub-element * * This function returns the relative position of the instantiation of the specified * sub-element within the instantiation of the Element. * * For example, if the Element describes a 32 bit float followed by a 32 bit integer, * the offset return for the first will be 0 and the second 4. * * Parameters: * e: Element to get data from. * index: Index of the sub-element. * * Returns: Offset in bytes. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern uint32_t __attribute__((overloadable)) rsElementGetSubElementOffsetBytes(rs_element e, uint32_t index); #endif /* * rsElementGetVectorSize: Vector size of the Element * * Returns the Element's vector size. If the Element does not represent a vector, * 1 is returned. * * Parameters: * e: Element to get data from. * * Returns: Length of the element vector. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern uint32_t __attribute__((overloadable)) rsElementGetVectorSize(rs_element e); #endif /* * rsGetAllocation: Return the Allocation for a given pointer * * DEPRECATED. Do not use. * * Returns the Allocation for a given pointer. The pointer should point within a valid * allocation. The results are undefined if the pointer is not from a valid Allocation. */ extern rs_allocation __attribute__((overloadable #if (defined(RS_VERSION) && (RS_VERSION >= 22)) , deprecated("This function is deprecated and will be removed from the SDK in a future release.") #endif )) rsGetAllocation(const void* p); /* * rsSamplerGetAnisotropy: Anisotropy of the Sampler * * Get the Sampler's anisotropy. * * See android.renderscript.S. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern float __attribute__((overloadable)) rsSamplerGetAnisotropy(rs_sampler s); #endif /* * rsSamplerGetMagnification: Sampler magnification value * * Get the Sampler's magnification value. * * See android.renderscript.S. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern rs_sampler_value __attribute__((overloadable)) rsSamplerGetMagnification(rs_sampler s); #endif /* * rsSamplerGetMinification: Sampler minification value * * Get the Sampler's minification value. * * See android.renderscript.S. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern rs_sampler_value __attribute__((overloadable)) rsSamplerGetMinification(rs_sampler s); #endif /* * rsSamplerGetWrapS: Sampler wrap S value * * Get the Sampler's wrap S value. * * See android.renderscript.S. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern rs_sampler_value __attribute__((overloadable)) rsSamplerGetWrapS(rs_sampler s); #endif /* * rsSamplerGetWrapT: Sampler wrap T value * * Get the sampler's wrap T value. * * See android.renderscript.S. */ #if (defined(RS_VERSION) && (RS_VERSION >= 16)) extern rs_sampler_value __attribute__((overloadable)) rsSamplerGetWrapT(rs_sampler s); #endif /* * rsSetObject: For internal use. * */ extern void __attribute__((overloadable)) rsSetObject(rs_element* dst, rs_element src); extern void __attribute__((overloadable)) rsSetObject(rs_type* dst, rs_type src); extern void __attribute__((overloadable)) rsSetObject(rs_allocation* dst, rs_allocation src); extern void __attribute__((overloadable)) rsSetObject(rs_sampler* dst, rs_sampler src); extern void __attribute__((overloadable)) rsSetObject(rs_script* dst, rs_script src); #endif // RENDERSCRIPT_RS_OBJECT_INFO_RSH