/* * Copyright (C) 2017 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. */ package android.hardware.renderscript@1.0; import android.hardware.renderscript@1.0::types; // TODO: is there any way to keep this documentation in sync with the // corresponding Java doc? // // TODO: Some of the documentation was taken from Java docs, whereas others were // undocumented. Because of this, there's somewhat two different styles of // comments. Look into having a consistent convention. // // TODO: There was some confusion as to why some paramters use vec<> and others // use Ptr/Size. The convention is that vec<> is used whenever the paramter is // only an input parameter. HIDL is not supposed to include any output // parameters, so a more explicit Ptr/Size is used. interface IContext { /** * TODO: Do we need to define "selectors"? It may be a property of the * "adapted allocation" that's returned. * * Creates an arbitrary window into the base allocation. The type describes * the shape of the window. Any dimensions present in the type must be * equal to or smaller than the dimensions in the source allocation. A * dimension present in the allocation that is not present in the type must * be constrained away with the selectors. If a dimension is present in * both the type and allocation, one of two things must happen. If the type * is smaller than the allocation, a window must be created, the selected * value in the adapter for that dimension must act as the base address, * and the type must describe the size of the view starting at that point. * If the type and allocation dimension are of the same size, then setting * the selector for the dimension must be an error. * * @param type Type describing data layout * @param baseAlloc Allocation * @return subAlloc AllocationAdapter */ @callflow(next={"*"}) allocationAdapterCreate(Type type, Allocation baseAlloc) generates (AllocationAdapter subAlloc); /** * TODO: Need to relate "offset" back to the terminology in * allocationAdapterCreate() -- the latter uses the terms "selector" and * "selected value". Can we use consistent terminology? Are "offset" and * "selector" actually two different things? * * TODO: Explain the flattened layout in the offsets vec * * Sets the offsets for an Allocation Adapter. * * @param alloc AllocationAdapter * @param offsets Collection of offsets */ @callflow(next={"*"}) allocationAdapterOffset(AllocationAdapter alloc, vec offsets); /** * TODO: add more explanation here. * * Returns the Type of the Allocation. * * @param allocation Allocation * @return type Allocation's Type */ @callflow(next={"*"}) allocationGetType(Allocation allocation) generates (Type type); /** * TODO: more clarification needed describing if the pointer can be aliased * or if the data can outlive the allocation. * * Creates an Allocation for use by scripts with a given Type and a backing * pointer. For use with ALLOCATION_USAGE_SHARED. * * @param type Type describing data layout * @param mips AllocationMipmapControl specifies desired mipmap behavior for * the allocation * @param usage Bit field specifying how the Allocation is utilized * @param ptr Pointer to client-side data * @return allocation Created Allocation */ @callflow(next={"*"}) allocationCreateTyped(Type type, AllocationMipmapControl mips, bitfield usage, Ptr ptr) generates (Allocation allocation); /** * Creates an Allocation from a Bitmap. * * @param type Type describing data layout * @param mips AllocationMipmapControl specifies desired mipmap behavior for * the allocation * @param bitmap Bitmap source for the allocation data * @param usage Bit field specifying how the Allocation is utilized * @return allocation Created Allocation containing bitmap data */ @callflow(next={"*"}) allocationCreateFromBitmap(Type type, AllocationMipmapControl mips, vec bitmap, bitfield usage) generates (Allocation allocation); /** * Creates a Cubemapped Allocation from a Bitmap. * * @param type Type describing data layout * @param mips AllocationMipmapControl specifies desired mipmap behavior * for the allocation * @param bitmap Bitmap with cubemap faces layed out in the following * format: right, left, top, bottom, front, back * @param usage Bit field specifying how the Allocation is used * @return allocation Created Allocation containing cubemap data */ @callflow(next={"*"}) allocationCubeCreateFromBitmap(Type type, AllocationMipmapControl mips, vec bitmap, bitfield usage) generates (Allocation allocation); /** * Returns the handle to a raw buffer that is being managed by the screen * compositor. This operation is only valid for Allocations with * USAGE_IO_INPUT. * * @param allocation Allocation * @return nativeWindow NativeWindow object associated with allocation */ @callflow(next={"*"}) allocationGetNativeWindow(Allocation allocation) generates (NativeWindow nativeWindow); /** * TODO: more clarification needed * * Sets the NativeWindow of an Allocation. This operation is only valid * for Allocations with USAGE_IO_INPUT. * * @param allocation Allocation to be modified * @pram nativeWindow NativeWindow to associate with allocation */ @callflow(next={"*"}) allocationSetNativeWindow(Allocation allocation, NativeWindow nativewindow); /** * Initialize BufferQueue with specified max number of buffers. * * @param alloc Allocation * @param numBuffer Maximum number of buffers */ @callflow(next={"*"}) allocationSetupBufferQueue(Allocation alloc, uint32_t numBuffer); /** * TODO: clearly define baseAlloc vs subAlloc * * Shares the BufferQueue with another Allocation. Both must be * USAGE_IO_INPUT Allocations. * * @param baseAlloc Base Allocation * @param subAlloc Allocation to use the same buffer queue as the Base * Allocation */ @callflow(next={"*"}) allocationShareBufferQueue(Allocation baseAlloc, Allocation subAlloc); /** * Copies from the Allocation into a Bitmap. The bitmap must match the * dimensions of the Allocation. * * HIDL is always running in Passthrough mode for RenderScript, so the * buffer is modified directly by the driver. * * @param allocation Allocation * @param data Buffer to be copied into * @param sizeBytes Size of the buffer pointed to by "data" */ @callflow(next={"*"}) allocationCopyToBitmap(Allocation allocation, Ptr data, Size sizeBytes); /** * TODO: should we consolidate all [123]DWrite functions or [123]DRead * functions into the same API call? Our current plan is to be very similar * to the dispatch table API. How much should we deviate from the original * API? * TODO: better description on Vec3/Vec4 and padding. * * Copies data into a 1D region of this Allocation. * * When this HAL entry is executed, all Vec3 elements have been explicitly * padded as Vec4 elements. * * The size of the region is: count * Element's size. * * @param allocation Allocation to be modified * @param offset The offset of the first element to be copied * @param lod Selected mipmap level of detail * @param count Number of elements to be copied * @param data Source data to be copied to Allocation */ @callflow(next={"*"}) allocation1DWrite(Allocation allocation, uint32_t offset, uint32_t lod, uint32_t count, vec data); /** * Copies a value into a single sub-Element of this Allocation. * * @param allocation Allocation to be updated * @param x X position of the first element in the Allocation to be updated * @param y Y position of the first element in the Allocation to be * updated; for a 1D Allocation, this value must be 0 * @param z Z position of the first element in the Allocation to be * updated; for a 1D or 2D Allocation, this value must be 0 * @param lod Selected mipmap level of detail * @param data Data to be copied from * @param compIdx Component number to identify which sub-Element is updated */ @callflow(next={"*"}) allocationElementWrite(Allocation allocation, uint32_t x, uint32_t y, uint32_t z, uint32_t lod, vec data, Size compIdx); /** * Copies from an array into a rectangular region in this Allocation. * * When this HAL entry is executed, all Vec3 elements have been explicitly * padded as Vec4 elements. * * The size of the region is: w * h * Element's size. * * @param allocation Allocation to be modified * @param xoff X offset of the region to update in this Allocation * @param yoff Y offset of the region to update in this Allocation * @param lod Selected mipmap level of detail * @param face AllocationCubemapFace * @param w Width of the region to update * @param h Height of the region to update * @param data Data to be placed into the Allocation * @param stride For 1D Allocation, the stride must be the number of bytes * of this Allocation. For 2D and 3D Allocations, the stride * must be the stride in X dimension measuring in bytes. */ @callflow(next={"*"}) allocation2DWrite(Allocation allocation, uint32_t xoff, uint32_t yoff, uint32_t lod, AllocationCubemapFace face, uint32_t w, uint32_t h, vec data, Size stride); /** * Copies from an array into a 3D region in this Allocation. * * When this HAL entry is executed, all Vec3 elements have been explicitly * padded as Vec4 elements. * * The size of the region is: w * h * d * Element's size. * * @param allocation Allocation to be modified * @param xoff X offset of the region to update in this Allocation * @param yoff Y offset of the region to update in this Allocation * @param zoff Z offset of the region to update in this Allocation * @param lod Selected mipmap level of detail * @param w Width of the region to update * @param h Height of the region to update * @param d Depth of the region to update * @param data Data to be placed in the Allocation * @param stride For 1D Allocation, the stride must be the number of bytes * of this Allocation. For 2D and 3D Allocations, the stride * must be the stride in X dimension measuring in bytes. */ @callflow(next={"*"}) allocation3DWrite(Allocation allocation, uint32_t xoff, uint32_t yoff, uint32_t zoff, uint32_t lod, uint32_t w, uint32_t h, uint32_t d, vec data, Size stride); /** * Generates a mipmap chain. This is only valid if the Type of the * Allocation includes mipmaps. * * This function generates a complete set of mipmaps from the top level * LOD. * * If the Allocation is also using other memory spaces, a call to * allocationSyncAll(context, allocation, usage) is required. * * @param allocation Allocation which has its top LOD read and lower LOD * written to */ @callflow(next={"*"}) allocationGenerateMipmaps(Allocation allocation); /** * Copies all of an Allocation's data into an array. * * All Vec3 elements of an Allocation are padded to be Vec4, so the data * returned by this function automatically includes padding. * * HIDL is always running in Passthrough mode for RenderScript, so the * buffer is modified directly by the driver. * * @param allocation Allocation to be read * @param data Buffer to be copied into * @param sizeBytes Size of the buffer pointed to by "data" */ @callflow(next={"*"}) allocationRead(Allocation allocation, Ptr data, Size sizeBytes); /** * Copies a 1D region of this Allocation into an array. * * All Vec3 elements of an Allocation are padded to be Vec4, so the data * returned by this function automatically includes padding. * * The size of the region is: count * Element's size. * * HIDL is always running in Passthrough mode for RenderScript, so the * buffer is modified directly by the driver. * * @param allocation Allocation to be read * @param xoff X offset of the first element to be copied * @param lod Mipmap level of detail * @param count The number of elements to be copied * @param data Buffer to be copied into * @param sizeBytes Size of the buffer pointed to by "data" */ @callflow(next={"*"}) allocation1DRead(Allocation allocation, uint32_t xoff, uint32_t lod, uint32_t count, Ptr data, Size sizeBytes); /** * Returns the value of a single sub-Element of this Allocation. * * HIDL is always running in Passthrough mode for RenderScript, so the * buffer is modified directly by the driver. * * @param allocation Allocation to be read * @param x X position of the first element in the Allocation to be read * @param y Y position of the first element in the Allocation to be read * @param z Z position of the first element in the Allocation to be read * @param lod Mipmap level of detail * @param data Buffer to be copied into * @param sizeBytes Size of the buffer pointed to by "data" * @param compIdx Component number to identify which sub-Element is updated */ @callflow(next={"*"}) allocationElementRead(Allocation allocation, uint32_t x, uint32_t y, uint32_t z, uint32_t lod, Ptr data, Size sizeBytes, Size compIdx); /** * Copies from a rectangular region in this Allocation to an array. * * All Vec3 elements of an Allocation are padded to be Vec4, so the data * returned by this function automatically includes padding. * * The size of the region is: w * h * Element's size. * * HIDL is always running in Passthrough mode for RenderScript, so the * buffer is modified directly by the driver. * * @param allocation Allocation to be read * @param xoff X offset of the region to copy in this array * @param yoff Y offset of the region to copy in this array * @param lod Mipmap level of detail * @param face AllocationCubemapFace * @param w Width of the region to copy * @param h Height of the region to copy * @param data Buffer to be copied into * @param sizeBytes Size of the buffer pointed to by "data" * @param stride For 1D Allocation, the stride must be the number of bytes * of this Allocation. For 2D and 3D Allocations, the stride * must be the stride in X dimension measuring in bytes. */ @callflow(next={"*"}) allocation2DRead(Allocation allocation, uint32_t xoff, uint32_t yoff, uint32_t lod, AllocationCubemapFace face, uint32_t w, uint32_t h, Ptr data, Size sizeBytes, Size stride); /** * Copies from a rectangular cuboid region in this Allocation to an array. * * All Vec3 elements of an Allocation are padded to be Vec4, so the data * returned by this function automatically includes padding. * * The size of the region is: w * h * d * Element's size. * * HIDL is always running in Passthrough mode for RenderScript, so the * buffer is modified directly by the driver. * * @param allocation Allocation to be read * @param xoff X offset of the region to copy in this array * @param yoff Y offset of the region to copy in this array * @param zoff Z offset of the region to copy in this array * @param lod Mipmap level of detail * @param w Width of the region to copy * @param h Height of the region to copy * @param d Depth of the region to copy * @param data Buffer to be copied into * @param sizeBytes Size of the buffer pointed to by "data" * @param stride For 1D Allocation, the stride must be the number of bytes * of this Allocation. For 2D and 3D Allocations, the stride * must be the stride in X dimension measuring in bytes. */ @callflow(next={"*"}) allocation3DRead(Allocation allocation, uint32_t xoff, uint32_t yoff, uint32_t zoff, uint32_t lod, uint32_t w, uint32_t h, uint32_t d, Ptr data, Size sizeBytes, Size stride); /** * Propagates changes from one usage of the Allocation to the other usages * of the Allocation. * * @param allocation First usage of the Allocation * @param usageType Allocation usage type */ @callflow(next={"*"}) allocationSyncAll(Allocation allocation, AllocationUsageType usageType); /** * TODO: describe the functionality of resize1D better * TODO: original Java Doc description seems to contradict itself ("with * null contents and the region is otherwise undefined") * TODO: should "new elements" be "new cells"? * TODO: what does "objects are created" mean? * TODO: what does "new dimension" mean? IS the type of the resized * allocation different than the type before resizing? * * Resizes a 1D allocation. The contents of the allocation are preserved. * If new elements are allocated, objects are created with null contents * and the new region is otherwise undefined. * * If the new region is smaller, the references of any object outside the * new region must be released. * * A new type must be created with the new dimension. * * @param allocation Allocation to be resized * @param dimX New size along the x dimension of the Allocation */ @callflow(next={"*"}) allocationResize1D(Allocation allocation, uint32_t dimX); /** * TODO: There are allocationCopy2DRange and 3DRange, but no 1DRange. Should * the interface be cleaned up more? * * Copies a rectangular region from an Allocation into a rectangular region * in this Allocation. * * @param dstAlloc Allocation to be updated * @param dstXoff X offset of the region to update * @param dstYoff Y offset of the region to update * @param dstMip Selected mipmap level of the Allocation to update * @param dstFace Destination AllocationCubemapFace * @param width Width of the region to update * @param height Height of the region to update * @param srcAlloc Source Allocation, to be read * @param srcXoff X offset of the region in the source Allocation * @param srcYoff Y offset of the region in the source Allocation * @param srcMip Selected mipmap level of the source Allocation * @param srcFace Source AllocationCubemapFace */ @callflow(next={"*"}) allocationCopy2DRange(Allocation dstAlloc, uint32_t dstXoff, uint32_t dstYoff, uint32_t dstMip, AllocationCubemapFace dstFace, uint32_t width, uint32_t height, Allocation srcAlloc, uint32_t srcXoff, uint32_t srcYoff, uint32_t srcMip, AllocationCubemapFace srcFace); /** * Copies a rectangular cuboid region into the allocation from another * Allocation. * * @param dstAlloc Allocation to be updated * @param dstXoff X offset of the region to update * @param dstYoff Y offset of the region to update * @param dstZoff Z offset of the region to update * @param dstMip Selected mipmap level of the Allocation to update * @param width Width of the region to update * @param height Height of the region to update * @param depth Depth of the region to update * @param srcAlloc Source Allocation, to be read * @param srcXoff Source X offset of the region in the source Allocation * @param srcYoff Source Y offset of the region in the source Allocation * @param srcZoff Source Z offset of the region in the souce Allocation * @param srcMip Selected mipmap level of the Allocation to read */ @callflow(next={"*"}) allocationCopy3DRange(Allocation dstAlloc, uint32_t dstXoff, uint32_t dstYoff, uint32_t dstZoff, uint32_t dstMip, uint32_t width, uint32_t height, uint32_t depth, Allocation srcAlloc, uint32_t srcXoff, uint32_t srcYoff, uint32_t srcZoff, uint32_t srcMip); /** * TODO: define buffer and output stream * * Sends a buffer to the output stream. The contents of the Allocation may * be undefined after this operation. This operation is only valid if * USAGE_IO_OUTPUT is set on the Allocation. * * @param allocation Allocation to be sent */ @callflow(next={"*"}) allocationIoSend(Allocation allocation); /** * Receives the latest input into the Allocation. This operation is only * valid if USAGE_IO_INPUT is set on the Allocation, otherwise an error * must be reported and no operations may be executed. * * @param allocation Allocation to be updated */ @callflow(next={"*"}) allocationIoReceive(Allocation allocation); /** * TODO: describe default values for lod, face, and z better. * TODO: what cases can invalidate the pointer? Resize? It should be * clarified that this method should always return a valid pointer, but the * returned pointer might become invalid later. * * Retrieves the pointer to the actual data an Allocation contains as well * as the data's stride. * * If Allocation lacks the corresponding dimension for lod, face, or z, an * error message must be sent to the message queue and nullptr must be * returned for dataPtr and 0 for stride. All missing values must be 0 or * NONE in the corresponding enum. * * @param allocation Allocation * @param lod Mipmap level of detail * @param face AllocationCubemapFace * @param z Z position * @return pointer Pointer to the server-side data; if this points to an * invalid location in memory (because the buffer was * freed), this may result in undefined behavior * @return stride For 1D Allocation, the stride must be the number of bytes * of this Allocation. For 2D and 3D Allocations, the stride * must be the stride in X dimension measuring in bytes. */ @callflow(next={"*"}) allocationGetPointer(Allocation allocation, uint32_t lod, AllocationCubemapFace face, uint32_t z) generates (Ptr dataPtr, Size stride); /** * Retrieves an Element's metadata from native code. * * @param element Element to be read * @return elemData Element data */ @callflow(next={"*"}) elementGetNativeMetadata(Element element) generates (vec elemData); /** * TODO: define Sub-Element handles better. * * Retrieves an Element's sub Elements, specifically their identifiers, * names, and sizes. * * @param element Element to be read * @param numSubElem Number of sub-Elements * @return ids Sub-Element handles * @return names Sub-Element Names * @return arraySizes Sizes of sub-Element arrays */ @callflow(next={"*"}) elementGetSubElements(Element element, Size numSubElem) generates (vec ids, vec names, vec arraySizes); /** * TODO: can normalization flag be removed? * * Creates an Element. * * @param dt Data type * @param dk Data kind * @param norm Flag for normalization * @param size Vector length, with scalar = 1 * @return element Created Element */ @callflow(next={"*"}) elementCreate(DataType dt, DataKind dk, bool norm, uint32_t size) generates (Element element); /** * Creates a complex Element. * * @param einsPtr Container of input Elements * @param namesPtr Container of input names * @param arraySizesPtr Container of array sizes * @return element Created Element */ @callflow(next={"*"}) elementComplexCreate(vec einsPtr, vec names, vec arraySizesPtr) generates (Element element); /** * Retrives a Type's metadata from native code. * * @param type Type describing data layout * @return metadata Type's native metadata */ @callflow(next={"*"}) typeGetNativeMetadata(Type type) generates (vec metadata); /** * Creates a new Type. * * If Type is 1D, Y and Z must be 0. If Type is 2D, Z must be 0. * * @param element Element of the Type * @param dimX X dimension * @param dimY Y dimension * @param dimZ Z dimension * @param mipmaps Flag indicating whether Type has mipmaps * @param faces Flag indicating whether Type has faces * @param yuv Enumeration specifying which type of YUV format, if any, Type * uses * @return type Created Type */ @callflow(next={"*"}) typeCreate(Element element, uint32_t dimX, uint32_t dimY, uint32_t dimZ, bool mipmaps, bool faces, YuvFormat yuv) generates (Type type); /** * Destroys provided RenderScript context, including all objects created in * this context. */ @exit contextDestroy(); /** * TODO: provide overview of messaging model and figure out if this should * be part of HAL or not. * TODO: what is the "client" for purposes of this interface? * TODO: consider using send/receive to be more similar to other calls * TODO: define the purpose of size more * * Fills the provided buffer with message data. "size" should be at least * as large as the message size. Returns the MessageType and size of the * message are returned. * * @param data A pointer to a buffer to be filled with a message * @param size Size in bytes of the buffer pointed to by "data" * @return messageType Type of message sent to the client * @return receiveLen Length of the message in bytes */ @callflow(next={"*"}) contextGetMessage(Ptr data, Size size) generates (MessageToClientType messageType, Size receiveLen); /** * TODO: define subID better. * * Gets the metadata of a message to ensure entire message can be properly * received. Can be used to determine size of data to allocate when calling * contextGetMessage. * * @return messageType Type of message sent to the client * @return receiveLen Length of message * @return subID Message sub identifier */ @callflow(next={"*"}) contextPeekMessage() generates (MessageToClientType messageType, Size receiveLen, uint32_t subID); /** * TODO: Define "previous commands" better * TODO: Is the message identifier the same as subID? * * Places a message into the message queue to be sent back to the message * handler once all previous commands have been executed. The message data * is copied into the queue and can be discarded by the client after this * call. * * @param id Message identifier * @param data Message data */ @callflow(next={"*"}) contextSendMessage(uint32_t id, vec data); /** * TODO: Can this be done automatically as part of context creation? What * happens if we perform message operations before doing this? * * Initializes the messaging thread, so that the front-end API can receive * messages from the driver. This call also waits for the messaging FIFO to * start up. */ @callflow(next={"*"}) contextInitToClient(); /** * TODO: Why doesn't this happen automatically as part of context * destruction? What happens if the FIFO is not empty? * * Deinitializes a the messaging thread. Shuts down the FIFO. */ @callflow(next={"*"}) contextDeinitToClient(); /** * TODO: do we need to mark asynchronous operations in this interface * definition? * * Waits for any pending asynchronous operations (such as copies to a RS * allocation or RS script executions) to complete. */ @callflow(next={"*"}) contextFinish(); /** * Prints the currently available debugging information about the state of * the RS context to the logcat. */ @callflow(next={"*"}) contextLog(); /** * TODO: full path? relative path? Investigate further. * * Sets the cache directory of the context. * * @param cacheDir Name of the application's cache directory */ @callflow(next={"*"}) contextSetCacheDir(string cacheDir); /** * TODO: does this apply to the GPU as well? * * Changes the priority of the cpu worker threads for this context. * * @param priority Priority of the thread */ @callflow(next={"*"}) contextSetPriority(ThreadPriorities priority); /** * TODO: does this need to be part of the HAL? What if the object already * has a name? * * Assigns a name to a base object. * * @param obj Object to be named * @param name Assigned name */ @callflow(next={"*"}) assignName(ObjectBase obj, string name); /** * TODO: what if the object has no name? * * Returns the name of an object. * * @param obj Object to be read * @return name Name of the object */ @callflow(next={"*"}) getName(ObjectBase obj) generates (string name); /** * TODO: starting here we have a set of interfaces for use with * ScriptGroups. At the very least we should indicate for each one that's * what it's for. Should we include ScriptGroup in the interface names? * TODO: sweep whole file and remove prefix "v" from all parameter names * TODO: there are some places where we use Size for size, and others where * we use int32_t. Is there a reason it's int32_t? In some cases, it * requires a negative value. * * Creates a Closure which represents a function call to a ForEach Kernel * combined with arguments and values for global variables. * * @param kernelID Kernel identifier * @param returnValue Allocation used in output of Closure * @param fieldIDS Collection of Script's Field identifiers * @param values Collection of Script's data values * @param sizes Collection of Script's data sizes * @param depClosures Collection of Closures * @param depFieldIDS Collection of Script's dependent Field identifiers * @return closure Created Closure */ @callflow(next={"*"}) closureCreate(ScriptKernelID kernelID, Allocation returnValue, vec fieldIDS, vec values, vec sizes, vec depClosures, vec depFieldIDS) generates (Closure closure); /** * Creates a Closure which represents a function call to a invocable * function, combined with arguments and values for global variables. * * @param invokeID Invokable function identifier * @param params Collection of Invoke script parameters * @param fieldIDS Collection of Script Field identifiers * @param values Collection of values * @param sizes Collection of sizes * @return closure Created Closure */ @callflow(next={"*"}) invokeClosureCreate(ScriptInvokeID invokeID, vec params, vec fieldIDS, vec values, vec sizes) generates (Closure closure); /** * Sets the argument of a Closure at specified index and size to provided * value. * * @param closure Closure to be modified * @param index Index * @param value Value * @param size Size */ @callflow(next={"*"}) closureSetArg(Closure closure, uint32_t index, Ptr value, int32_t size); /** * Sets a global variable in a Closure. * * @param closure Closure * @param fieldID Global's Field identifier * @param value Value * @param size Size */ @callflow(next={"*"}) closureSetGlobal(Closure closure, ScriptFieldID fieldID, int64_t value, int32_t size); /** * TODO: should slot be unsigned? (applies to other two ID interfaces, too) * * Creates a Script Kernel ID. * * @param script Script * @param slot Slot * @param sig Bitfield describing Kernel signature and operation * @return scriptKernelID Script's Kernel identifier */ @callflow(next={"*"}) scriptKernelIDCreate(Script script, int32_t slot, bitfield sig) generates (ScriptKernelID scriptKernelID); /** * Creates a Script Invoke ID. * * @param script Script * @param slot Slot * @return scriptInvokeID Invoke Script's identifier */ @callflow(next={"*"}) scriptInvokeIDCreate(Script script, int32_t slot) generates (ScriptInvokeID scriptInvokeID); /** * TODO: describe the return value better. What is it? * * Creates a Script Field ID. * * @param script Script * @param slot Slot * @return scriptFieldID Script's Field identifier */ @callflow(next={"*"}) scriptFieldIDCreate(Script script, int32_t slot) generates (ScriptFieldID scriptFieldID); /** * TODO: add more description * * Creates a Script Group. * * @param kernels Collection of Scripts' Kernel identifiers * @param srcK Source Kernel identifiers * @param dstK Destination Kernel identifiers * @param dstF Destination Script Field identifiers * @param types Collection of Types describing data layout * @return scriptGroup Created Script Group */ @callflow(next={"*"}) scriptGroupCreate(vec kernels, vec srcK, vec dstK, vec dstF, vec types) generates (ScriptGroup scriptGroup); /** * Creates a Script Group. * * @param name Name * @param cacheDir Cache directory * @param closures Collection of Closures * @return scriptGroup2 Created Script Group */ @callflow(next={"*"}) scriptGroup2Create(string name, string cacheDir, vec closures) generates (ScriptGroup2 scriptGroup2); /** * TODO: if SetInput/Output corresponds to the Java API setInput() and * setOutput(), which are documented as deprecated in API 23, do we need to * support them? Or can we fallback to the CPU when they're used? Or can't * we tell whether they're used early enough to do fallback? * * Sets an output of the ScriptGroup. This specifies an Allocation to be * used for the kernels that require an output Allocation visible after the * ScriptGroup is executed. * * @param sg Script Group * @param kid Script's Kernel identifier to be changed * @param alloc Allocation to be filled by output */ @callflow(next={"*"}) scriptGroupSetOutput(ScriptGroup sg, ScriptKernelID kid, Allocation alloc); /** * Sets an input of the Script Group. This specifies an Allocation to be * used for kernels that require an input Allocation provided from outside * of the Script Group. * * @param sg Script Group * @param kid Script's Kernel identifier to be changed * @param alloc Allocation to be read as input */ @callflow(next={"*"}) scriptGroupSetInput(ScriptGroup sg, ScriptKernelID kid, Allocation alloc); /** * Executes a Script Group. * * @param sg Script Group to be executed. */ @callflow(next={"*"}) scriptGroupExecute( ScriptGroup sg); /** * Frees any native resources associated with this object. The primary use * is to force immediate cleanup of resources when it is believed the GC * may not respond quickly enough. * * @param handle Opaque handle to the server-side object to be destroyed */ @callflow(next={"*"}) objDestroy(ObjectBase obj); /** * Creates a Sampler. * * @param magFilter Magnification value for the filter * @param minFilter Minification value for the filter * @param wrapS S wrapping mode for the sampler * @param wrapT T wrapping mode for the sampler * @param wrapR R wrapping mode for the sampler * @param aniso Anisotropy setting for the sampler * @return sampler Created Sampler */ @callflow(next={"*"}) samplerCreate(SamplerValue magFilter, SamplerValue minFilter, SamplerValue wrapS, SamplerValue wrapT, SamplerValue wrapR, float aniso) generates (Sampler sampler); /** * Binds an Allocation to a global pointer in the Script. * * @param script Script to be bound to * @param allocation Allocation to be bound * @param slot Slot of a global variable */ @callflow(next={"*"}) scriptBindAllocation(Script script, Allocation allocation, uint32_t slot); /** * TODO: is this necessary? * * Sets the timezone of a Script. * * @param script Script to be altered * @param timeZone Time Zone value as text */ @callflow(next={"*"}) scriptSetTimeZone(Script script, string timeZone); /** * TODO: can scriptInvoke be combined with scriptInvokeV? * * Launches an invokable function. * * @param vs Script to be invoked * @param slot Slot of invokable function */ @callflow(next={"*"}) scriptInvoke(Script vs, uint32_t slot); /** * Invokes a Script with values. * * @param vs Script to be invoked * @param slot Slot * @param data Data buffer of packed arguments */ @callflow(next={"*"}) scriptInvokeV(Script vs, uint32_t slot, vec data); /** * TODO: add documentation for params * TODO: Should we rename "ScriptCall" to "LaunchOptions"? * * Launches a ForEach kernel. * * @param vs Script * @param slot Slot of ForEach Kernel * @param vains Collection of input Allocations or null * @param vaout Output Allocation or null * @param params Collection of parameters * @param sc Pointer to a ScriptCall, nullptr if unused */ @callflow(next={"*"}) scriptForEach(Script vs, uint32_t slot, vec vains, Allocation vaout, vec params, Ptr sc); /** * Launches a Reduction kernel. * * @param vs Script * @param slot Slot of Reduction Kernel * @param vains Collection of input Allocations * @param vaout Output Allocation * @param sc Pointer to a ScriptCall, nullptr if unused */ @callflow(next={"*"}) scriptReduce(Script vs, uint32_t slot, vec vains, Allocation vaout, Ptr sc); /** * Sets a Script's integer variable to a value. * * @param vs RenderScript Script * @param slot Slot number of variable to be updated * @param value Value to be pushed to variable */ @callflow(next={"*"}) scriptSetVarI(Script vs, uint32_t slot, int32_t value); /** * Sets a Script's Object variable to a value * * @param vs RenderScript Script * @param slot Slot number of variable to be updated * @param obj ObjectBase */ @callflow(next={"*"}) scriptSetVarObj( Script vs, uint32_t slot, ObjectBase obj); /** * Sets a Script's long variable to a value. * * @param vs RenderScript Script * @param slot Slot number of variable to be updated * @param value Value to be pushed to variable */ @callflow(next={"*"}) scriptSetVarJ(Script vs, uint32_t slot, int64_t value); /** * Sets a Script's float variable to a value. * * @param vs RenderScript Script * @param slot Slot number of variable to be updated * @param value Value to be pushed to variable */ @callflow(next={"*"}) scriptSetVarF(Script vs, uint32_t slot, float value); /** * Sets a Script's double variable to a value. * * @param vs RenderScript Script * @param slot Slot number of variable to be updated * @param value Value to be pushed to variable */ @callflow(next={"*"}) scriptSetVarD(Script vs, uint32_t slot, double value); /** * Sets a Script's struct variable to a value. * * @param vs RenderScript Script * @param slot Slot number of variable to be updated * @param data Data to be pushed to variable */ @callflow(next={"*"}) scriptSetVarV(Script vs, uint32_t slot, vec data); /** * TODO: Why do we have typed setters but only untyped getter? * * Retrieves the value from a global variable in a script. * * @param vs RenderScript Script * @param slot Slot number of variable to be read * @param len Size of data to be filled * @return data Data to be updated */ @callflow(next={"*"}) scriptGetVarV(Script vs, uint32_t slot, Size len) generates (vec data); /** * TODO: Is this a value to be replicated for each member of the array? Or * is there a representation for each separate member? * * Sets the value of a global array of structs, given the Element and * dimension. * * @param vs RenderScript Script * @param slot Slot number of variable to be updated * @param data Data * @param ve Element * @param dims Collection of dimensions */ @callflow(next={"*"}) scriptSetVarVE(Script vs, uint32_t slot, vec data, Element ve, vec dims); /** * TODO: is cacheDir redundant with createCache() function? Can we remove * it? * TODO: define resName more clearly * * Creates a RenderScript C99 kernel script. * * @param resName Resource name of the bitcode * @param cacheDir Cache directory name * @param text The kernel's bitcode as a uint8_t vector * @return script Created Script */ @callflow(next={"*"}) scriptCCreate(string resName, string cacheDir, vec text) generates (Script script); /** * Creates a RenderScript Intrinsic script. * * @param id Intrinsic Script identifier * @param elem Element * @return script Created Script */ @callflow(next={"*"}) scriptIntrinsicCreate(ScriptIntrinsicID id, Element elem) generates (Script script); };