Abstract: The performance of a neural network (NN) and/or deep neural network (DNN) can be limited by the number of operations being performed as well as management of data among the various memory components of the NN/DNN. By inserting a selected padding in the input data to align the input data in memory, data read/writes can be optimized for processing by the NN/DNN thereby enhancing the overall performance of a NN/DNN. Operatively, an operations controller/iterator can generate one or more instructions that inserts the selected padding into the data. The data padding can be calculated using various characteristics of the input data as well as the NN/DNN as well as characteristics of the cooperating memory components. Padding on the output data can be utilized to support the data alignment at the memory components and the cooperating processing units of the NN/DNN.

Abstract: The performance of a neural network (NN) and/or deep neural network (DNN) can limited by the number of operations being performed as well as management of data among the various memory components of the NN/DNN. Using virtualized hardware iterators, data for processing by the NN/DNN can be traversed and configured to optimize the number of operations as well as memory utilization to enhance the overall performance of a NN/DNN. Operatively, an iterator controller can generate instructions for execution by the NN/DNN representative of one more desired iterator operation types and to perform one or more iterator operations. Data can be iterated according to a selected iterator operation and communicated to one or more neuron processors of the NN/DD for processing and output to a destination memory. The iterator operations can be applied to various volumes of data (e.g., blobs) in parallel or multiple slices of the same volume.

Abstract: A deep neural network (DNN) module utilizes parallel kernel and parallel input processing to decrease bandwidth utilization, reduce power consumption, improve neuron multiplier stability, and provide other technical benefits. Parallel kernel processing enables the DNN module to load input data only once for processing by multiple kernels. Parallel input processing enables the DNN module to load kernel data only once for processing with multiple input data. The DNN module can implement other power-saving techniques like clock-gating (i.e. removing the clock from) and power-gating (i.e. removing the power from) banks of accumulators based upon usage of the accumulators. For example, individual banks of accumulators can be power-gated when all accumulators in a bank are not in use, and do not store data for a future calculation. Banks of accumulators can also be clock-gated when all accumulators in a bank are not in use, but store data for a future calculation.

Abstract: A direct memory access (DMA) engine may be responsible to enable and control DMA data flow within a computing system. The DMA engine moves blocks of data, associated with descriptors in a plurality of queues, from a source to a destination memory location or address, autonomously from control by a computer system's processor. Based on analysis of the data blocks linked to the descriptors in the queues, the DMA engine and its associated DMA fragmenter ensure that data blocks stored linked to descriptors in the queues do not remain idle for an exorbitant period of time. The DMA fragmenter may divide large data blocks into smaller data blocks to ensure that the processing of large data blocks does not preclude the timely processing of smaller data blocks associated with one or more descriptors in the queues. The data blocks stored may be two-dimensional data blocks.

Abstract: A deep neural network (“DNN”) module can compress and decompress neuron-generated activation data to reduce the utilization of memory bus bandwidth. The compression unit can receive an uncompressed chunk of data generated by a neuron in the DNN module. The compression unit generates a mask portion and a data portion of a compressed output chunk. The mask portion encodes the presence and location of the zero and non-zero bytes in the uncompressed chunk of data. The data portion stores truncated non-zero bytes from the uncompressed chunk of data. A decompression unit can receive a compressed chunk of data from memory in the DNN processor or memory of an application host. The decompression unit decompresses the compressed chunk of data using the mask portion and the data portion. This can reduce memory bus utilization, allow a DNN module to complete processing operations more quickly, and reduce power consumption.

Abstract: A deep neural network (DNN) processor is configured to execute descriptors in layer descriptor lists. The descriptors define instructions for performing a pass of a DNN by the DNN processor. Several types of descriptors can be utilized: memory-to-memory move (M2M) descriptors; operation descriptors; host communication descriptors; configuration descriptors; branch descriptors; and synchronization descriptors. A DMA engine uses M2M descriptors to perform multi-dimensional strided DMA operations. Operation descriptors define the type of operation to be performed by neurons in the DNN processor and the activation function to be used by the neurons. M2M descriptors are buffered separately from operation descriptors and can be executed at soon as possible, subject to explicitly set dependencies. As a result, latency can be reduced and, consequently, the neurons can complete their processing faster. The DNN module can then be powered down earlier than it otherwise would have, thereby saving power.

Abstract: A deep neural network (“DNN”) module can determine whether processing of certain values in an input buffer or a weight buffer by neurons can be skipped. For example, the DNN module might determine whether neurons can skip the processing of values in entire columns of a neuron buffer. Processing of these values might be skipped if an entire column of an input buffer or a weight buffer are zeros, for example. The DNN module can also determine whether processing of single values in rows of the input buffer or the weight buffer can be skipped (e.g. if the values are zero). Neurons that complete their processing early as a result of skipping operations can assist other neurons with their processing. A combination operation can be performed following the completion of processing that transfers the results of the processing operations performed by a neuron to their correct owner.

Abstract: The performance of a neural network (NN) and/or deep neural network (DNN) can limited by the number of operations being performed as well as management of data among the various memory components of the NN/DNN. Using a directed line buffer that operatively inserts one or more shifting bits in data blocks to be processed, data read/writes to the line buffer can be optimized for processing by the NN/DNN thereby enhancing the overall performance of a NN/DNN. Operatively, an operations controller and/or iterator can generate one or more instructions having a calculated shifting bit(s) for communication to the line buffer. Illustratively, the shifting bit(s) can be calculated using various characteristics of the input data as well as the NN/DNN inclusive of the data dimensions. The line buffer can read data for processing, insert the shifting bits and write the data in the line buffer for subsequent processing by cooperating processing unit(s).

Abstract: The performance of a neural network (NN) and/or deep neural network (DNN) can limited by the number of operations being performed as well as memory data management of a NN/DNN. Using vector quantization of neuron weight values, the processing of data by neurons can be optimize the number of operations as well as memory utilization to enhance the overall performance of a NN/DNN. Operatively, one or more contiguous segments of weight values can be converted into one or more vectors of arbitrary length and each of the one or more vectors can be assigned an index. The generated indexes can be stored in an exemplary vector quantization lookup table and retrieved by exemplary fast weight lookup hardware at run time on the flyas part of an exemplary data processing function of the NN as part of an inline de-quantization operation to obtain needed one or more neuron weight values.

Abstract: An exemplary artificial intelligence/machine learning hardware computing environment having an exemplary DNN module cooperating with one or more memory components can perform data sharing and distribution as well reuse of a buffer data to reduce the number of memory component read/writes thereby enhancing overall hardware performance and reducing power consumption. Illustratively, data from a cooperating memory component is read according to a selected operation of the exemplary hardware and written to corresponding other memory component for use by one or more processing elements (e.g., neurons). The data is read in such a manner to optimize the engagement of the one or more processing elements for each processing cycle as well as to reuse data previously stored in the one or more cooperating memory components. Operatively, the written data is copied to a shadow memory buffer prior to being consumed by the processing elements.

Abstract: An exemplary computing environment having a DNN module can maintain one or more bandwidth throttling mechanisms. Illustratively, a first throttling mechanism can specify the number of cycles to wait between transactions on a cooperating fabric component (e.g., data bus). Illustratively, a second throttling mechanism can be a transaction count limiter that operatively sets a threshold of a number of transactions to be processed during a given transaction sequence and limits the number of transactions such as multiple transactions in flight to not exceed the set threshold. In an illustrative operation, in executing these two exemplary calculated throttling parameters, the average bandwidth usage and the peak bandwidth usage can be limited. Operatively, with this fabric bandwidth control, the processing units of the DNN are optimized to process data across each transaction cycle resulting in enhanced processing and lower power consumption.

Abstract: A deep neural network (DNN) processor is configured to execute layer descriptors in layer descriptor lists. The descriptors define instructions for performing a forward pass of a DNN by the DNN processor. The layer descriptors can also be utilized to manage the flow of descriptors through the DNN module. For example, layer descriptors can define dependencies upon other descriptors. Descriptors defining a dependency will not execute until the descriptors upon which they are dependent have completed. Layer descriptors can also define a “fence,” or barrier, function that can be used to prevent the processing of upstream layer descriptors until the processing of all downstream layer descriptors is complete. The fence bit guarantees that there are no other layer descriptors in the DNN processing pipeline before the layer descriptor that has the fence to be asserted is processed.

Abstract: Optimized memory usage and management is crucial to the overall performance of a neural network (NN) or deep neural network (DNN) computing environment. Using various characteristics of the input data dimension, an apportionment sequence is calculated for the input data to be processed by the NN or DNN that optimizes the efficient use of the local and external memory components. The apportionment sequence can describe how to parcel the input data (and its associated processing parameters—e.g., processing weights) into one or more portions as well as how such portions of input data (and its associated processing parameters) are passed between the local memory, external memory, and processing unit components of the NN or DNN. Additionally, the apportionment sequence can include instructions to store generated output data in the local and/or external memory components so as to optimize the efficient use of the local and/or external memory components.

Abstract: A computing device having adaptable image search and methods for operating an image recognition program on the computing device are disclosed herein. An image recognition program may receive a query from a user and a target image within which a search based on the query is to be performed using one or more of a plurality of locally stored image recognition models, which are determined to be able to perform the search with sufficiently high confidence. The query may comprise text that is typed or converted from speech. The image recognition program performs the search within the target image for a target region of the target image using at least one selected image recognition model stored locally, and returns a search result to the user.

Abstract: A computing device having adaptable image search and methods for operating an image recognition program on the computing device are disclosed herein. An image recognition program may receive a query from a user and a target image within which a search based on the query is to be performed using one or more of a plurality of locally stored image recognition models, which are determined to be able to perform the search with sufficiently high confidence. The query may comprise text that is typed or converted from speech. The image recognition program performs the search within the target image for a target region of the target image using at least one selected image recognition model stored locally, and returns a search result to the user.