/* * Copyright (C) 2018 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.neuralnetworks@1.2; import @1.0::ErrorStatus; import @1.1::ExecutionPreference; import @1.1::IDevice; import IPreparedModelCallback; /** * This interface represents a device driver. */ interface IDevice extends @1.1::IDevice { /** * Get the version string of the driver implementation. * * The version string must be a unique token among the set of version strings of * drivers of a specific device. The token identifies the device driver's * implementation. The token must not be confused with the feature level which is solely * defined by the interface version. This API is opaque to the Android framework, but the * Android framework may use the information for debugging or to pass on to NNAPI applications. * * Application developers sometimes have specific requirements to ensure good user experiences, * and they need more information to make intelligent decisions when the Android framework cannot. * For example, combined with the device name and other information, the token can help * NNAPI applications filter devices based on their needs: * - An application demands a certain level of performance, but a specific version of * the driver cannot meet that requirement because of a performance regression. * The application can disallow the driver based on the version provided. * - An application has a minimum precision requirement, but certain versions of * the driver cannot meet that requirement because of bugs or certain optimizations. * The application can filter out versions of these drivers. * * @return status Error status returned from querying the version string. Must be: * - NONE if the query was successful * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if the query resulted in an * unspecified error * @return version The version string of the device implementation. * Must have nonzero length */ getVersionString() generates (ErrorStatus status, string version); /** * Get the type of a given device. * * The device type can be used to help application developers to distribute * Machine Learning workloads and other workloads such as graphical rendering. * E.g., for an app which renders AR scenes based on real time object detection * results, the developer could choose an ACCELERATOR type device for ML * workloads, and reserve GPU for graphical rendering. * * @return status Error status returned from querying the device type. Must be: * - NONE if the query was successful * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if the query resulted in an * unspecified error * @return type The DeviceType of the device. Please note, this is not a * bitfield of DeviceTypes. Each device must only be of a * single DeviceType. */ getType() generates (ErrorStatus status, DeviceType type); /** * Gets the capabilities of a driver. * * @return status Error status of the call, must be: * - NONE if successful * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if there is an unspecified error * @return capabilities Capabilities of the driver. */ getCapabilities_1_2() generates (ErrorStatus status, Capabilities capabilities); /** * Gets information about extensions supported by the driver implementation. * * All extension operations and operands must be fully supported for the * extension to appear in the list of supported extensions. * * @return status Error status of the call, must be: * - NONE if successful * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if there is an unspecified error * @return extensions A list of supported extensions. */ getSupportedExtensions() generates (ErrorStatus status, vec extensions); /** * Gets the supported operations in a model. * * getSupportedOperations indicates which operations of a model are fully * supported by the vendor driver. If an operation may not be supported for * any reason, getSupportedOperations must return false for that operation. * * @param model A model whose operations--and their corresponding operands-- * are to be verified by the driver. * @return status Error status of the call, must be: * - NONE if successful * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if there is an unspecified error * - INVALID_ARGUMENT if provided model is invalid * @return supportedOperations A list of supported operations, where true * indicates the operation is supported and false indicates the * operation is not supported. The index of "supported" corresponds with * the index of the operation it is describing. */ getSupportedOperations_1_2(Model model) generates (ErrorStatus status, vec supportedOperations); /** * Gets the caching requirements of the driver implementation. * * There are two types of cache file descriptors provided to the driver: model cache * and data cache. * * The data cache is for caching constant data, possibly including preprocessed * and transformed tensor buffers. Any modification to the data cache should * have no worse effect than generating bad output values at execution time. * * The model cache is for caching security-sensitive data such as compiled * executable machine code in the device's native binary format. A modification * to the model cache may affect the driver's execution behavior, and a malicious * client could make use of this to execute beyond the granted permission. Thus, * the driver must always check whether the model cache is corrupted before * preparing the model from cache. * * getNumberOfCacheFilesNeeded returns how many of each type of cache files the driver * implementation needs to cache a single prepared model. Returning 0 for both types * indicates compilation caching is not supported by this driver. The driver may * still choose not to cache certain compiled models even if it reports that caching * is supported. * * If the device reports that caching is not supported, the user may avoid calling * IDevice::prepareModelFromCache or providing cache file descriptors to * IDevice::prepareModel_1_2. * * @return status Error status of the call, must be: * - NONE if successful * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if there is an unspecified error * @return numModelCache An unsigned integer indicating how many files for model cache * the driver needs to cache a single prepared model. It must * be less than or equal to Constant::MAX_NUMBER_OF_CACHE_FILES. * @return numDataCache An unsigned integer indicating how many files for data cache * the driver needs to cache a single prepared model. It must * be less than or equal to Constant::MAX_NUMBER_OF_CACHE_FILES. */ getNumberOfCacheFilesNeeded() generates (ErrorStatus status, uint32_t numModelCache, uint32_t numDataCache); /** * Asynchronously creates a prepared model for execution and optionally saves it * into cache files. * * prepareModel is used to make any necessary transformations to or alternative * representations to a model for execution, possibly including * transformations on the constant data, optimization on the model's graph, * or compilation into the device's native binary format. The model itself * is not changed. * * Optionally, caching information may be provided for the driver to save * the prepared model to cache files for faster model compilation time * when the same model preparation is requested in the future. There are * two types of cache file handles provided to the driver: model cache * and data cache. For more information on the two types of cache handles, * refer to getNumberOfCacheFilesNeeded. * * The file descriptors must be opened with read and write permission. A file may * have any size, and the corresponding file descriptor may have any offset. The * driver must truncate a file to zero size before writing to that file. The file * descriptors may be closed by the client once the asynchronous preparation has * finished. The driver must dup a file descriptor if it wants to get access to * the cache file later. * * The model is prepared asynchronously with respect to the caller. The * prepareModel function must verify the inputs to the preparedModel function * related to preparing the model (as opposed to saving the prepared model to * cache) are correct. If there is an error, prepareModel must immediately invoke * the callback with the appropriate ErrorStatus value and nullptr for the * IPreparedModel, then return with the same ErrorStatus. If the inputs to the * prepareModel function that are related to preparing the model are valid and * there is no error, prepareModel must launch an asynchronous task * to prepare the model in the background, and immediately return from * prepareModel with ErrorStatus::NONE. If the asynchronous task fails to launch, * prepareModel must immediately invoke the callback with * ErrorStatus::GENERAL_FAILURE and nullptr for the IPreparedModel, then return * with ErrorStatus::GENERAL_FAILURE. * * When the asynchronous task has finished preparing the model, it must * immediately invoke the callback function provided as an input to * prepareModel. If the model was prepared successfully, the callback object * must be invoked with an error status of ErrorStatus::NONE and the * produced IPreparedModel object. If an error occurred preparing the model, * the callback object must be invoked with the appropriate ErrorStatus * value and nullptr for the IPreparedModel. * * Optionally, the driver may save the prepared model to cache during the * asynchronous preparation. Any error that occurs when saving to cache must * not affect the status of preparing the model. Even if the input arguments * related to the cache may be invalid, or the driver may fail to save to cache, * the prepareModel function must finish preparing the model. The driver * may choose not to save to cache even if the caching information is * provided and valid. * * The only information that may be unknown to the model at this stage is * the shape of the tensors, which may only be known at execution time. As * such, some driver services may return partially prepared models, where * the prepared model may only be finished when it is paired with a set of * inputs to the model. Note that the same prepared model object may be * used with different shapes of inputs on different (possibly concurrent) * executions. * * Multiple threads may call prepareModel on the same model concurrently. * * @param model The model to be prepared for execution. * @param preference Indicates the intended execution behavior of a prepared * model. * @param modelCache A vector of handles with each entry holding exactly one * cache file descriptor for the security-sensitive cache. The length of * the vector must either be 0 indicating that caching information is not provided, * or match the numModelCache returned from getNumberOfCacheFilesNeeded. The cache * handles will be provided in the same order when retrieving the * preparedModel from cache files with prepareModelFromCache. * @param dataCache A vector of handles with each entry holding exactly one * cache file descriptor for the constants' cache. The length of * the vector must either be 0 indicating that caching information is not provided, * or match the numDataCache returned from getNumberOfCacheFilesNeeded. The cache * handles will be provided in the same order when retrieving the * preparedModel from cache files with prepareModelFromCache. * @param token A caching token of length Constant::BYTE_SIZE_OF_CACHE_TOKEN * identifying the prepared model. The same token will be provided when retrieving * the prepared model from the cache files with prepareModelFromCache. * Tokens should be chosen to have a low rate of collision for a particular * application. The driver cannot detect a collision; a collision will result * in a failed execution or in a successful execution that produces incorrect * output values. If both modelCache and dataCache are empty indicating that * caching information is not provided, this token must be ignored. * @param callback A callback object used to return the error status of * preparing the model for execution and the prepared model if * successful, nullptr otherwise. The callback object's notify function * must be called exactly once, even if the model could not be prepared. * @return status Error status of launching a task which prepares the model * in the background; must be: * - NONE if preparation task is successfully launched * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if there is an unspecified error * - INVALID_ARGUMENT if one of the input arguments related to preparing the * model is invalid */ prepareModel_1_2(Model model, ExecutionPreference preference, vec modelCache, vec dataCache, uint8_t[Constant:BYTE_SIZE_OF_CACHE_TOKEN] token, IPreparedModelCallback callback) generates (ErrorStatus status); /** * Creates a prepared model from cache files for execution. * * prepareModelFromCache is used to retrieve a prepared model directly from * cache files to avoid slow model compilation time. There are * two types of cache file handles provided to the driver: model cache * and data cache. For more information on the two types of cache handles, * refer to getNumberOfCacheFilesNeeded. * * The file descriptors must be opened with read and write permission. A file may * have any size, and the corresponding file descriptor may have any offset. The * driver must truncate a file to zero size before writing to that file. The file * descriptors may be closed by the client once the asynchronous preparation has * finished. The driver must dup a file descriptor if it wants to get access to * the cache file later. * * The model is prepared asynchronously with respect to the caller. The * prepareModelFromCache function must verify the inputs to the * prepareModelFromCache function are correct, and that the security-sensitive * cache has not been modified since it was last written by the driver. * If there is an error, or if compilation caching is not supported, or if the * security-sensitive cache has been modified, prepareModelFromCache must * immediately invoke the callback with the appropriate ErrorStatus value and * nullptr for the IPreparedModel, then return with the same ErrorStatus. If * the inputs to the prepareModelFromCache function are valid, the security-sensitive * cache is not modified, and there is no error, prepareModelFromCache must launch an * asynchronous task to prepare the model in the background, and immediately return * from prepareModelFromCache with ErrorStatus::NONE. If the asynchronous task * fails to launch, prepareModelFromCache must immediately invoke the callback * with ErrorStatus::GENERAL_FAILURE and nullptr for the IPreparedModel, then * return with ErrorStatus::GENERAL_FAILURE. * * When the asynchronous task has finished preparing the model, it must * immediately invoke the callback function provided as an input to * prepareModelFromCache. If the model was prepared successfully, the * callback object must be invoked with an error status of ErrorStatus::NONE * and the produced IPreparedModel object. If an error occurred preparing * the model, the callback object must be invoked with the appropriate * ErrorStatus value and nullptr for the IPreparedModel. * * The only information that may be unknown to the model at this stage is * the shape of the tensors, which may only be known at execution time. As * such, some driver services may return partially prepared models, where * the prepared model may only be finished when it is paired with a set of * inputs to the model. Note that the same prepared model object may be * used with different shapes of inputs on different (possibly concurrent) * executions. * * @param modelCache A vector of handles with each entry holding exactly one * cache file descriptor for the security-sensitive cache. The length of * the vector must match the numModelCache returned from getNumberOfCacheFilesNeeded. * The cache handles will be provided in the same order as with prepareModel_1_2. * @param dataCache A vector of handles with each entry holding exactly one * cache file descriptor for the constants' cache. The length of the vector * must match the numDataCache returned from getNumberOfCacheFilesNeeded. * The cache handles will be provided in the same order as with prepareModel_1_2. * @param token A caching token of length Constant::BYTE_SIZE_OF_CACHE_TOKEN * identifying the prepared model. It is the same token provided when saving * the cache files with prepareModel_1_2. Tokens should be chosen * to have a low rate of collision for a particular application. The driver * cannot detect a collision; a collision will result in a failed execution * or in a successful execution that produces incorrect output values. * @param callback A callback object used to return the error status of * preparing the model for execution and the prepared model if * successful, nullptr otherwise. The callback object's notify function * must be called exactly once, even if the model could not be prepared. * @return status Error status of launching a task which prepares the model * in the background; must be: * - NONE if preparation task is successfully launched * - DEVICE_UNAVAILABLE if driver is offline or busy * - GENERAL_FAILURE if caching is not supported or if there is an * unspecified error * - INVALID_ARGUMENT if one of the input arguments is invalid */ prepareModelFromCache(vec modelCache, vec dataCache, uint8_t[Constant:BYTE_SIZE_OF_CACHE_TOKEN] token, IPreparedModelCallback callback) generates (ErrorStatus status); };