Abstract: An apparatus having a plurality of first circuits, second circuits, third circuits and fourth circuits is disclosed. The first circuits may be configured to generate a plurality of first signals in response to (i) a priority signal and (ii) a request signal. The second circuits may be configured to generate a plurality of second signals in response to the first signals. The third circuits may be configured to generate a plurality of enable signals in response to the second signals. The fourth circuits may be configured to generate collectively an output signal in response to (i) the enable signals and (ii) the request signal. A combination of the first circuits, the second circuits, the third circuits and the fourth circuits generally establishes a programmable priority encoder. The second signals may be generated independent of the enable signals.

Abstract: An apparatus having a plurality of first circuits, second circuits, third circuits and fourth circuits is disclosed. The first circuits may be configured to generate a plurality of first signals in response to (i) a priority signal and (ii) a request signal. The second circuits may be configured to generate a plurality of second signals in response to the first signals. The third circuits may be configured to generate a plurality of enable signals in response to the second signals. The fourth circuits may be configured to generate collectively an output signal in response to (i) the enable signals and (ii) the request signal. A combination of the first circuits, the second circuits, the third circuits and the fourth circuits generally establishes a programmable priority encoder. The second signals may be generated independent of the enable signals.

Abstract: A system for layout of a module in an integrated circuit layout pattern has a cell library and a cell placement system. The cell library includes a plurality of cells. The cell placement system is adapted to select one or more cells from the cell library and to locally place each selected cell within the module layout so that each cell pin of the selected cells and each port of the module layout occupies a unique vertical routing track within the module layout.

Abstract: The present invention concerns an apparatus including a modular memory and an address locator circuit. The modular memory may be configured to generate a current address signal, a first data output signal and a second data output signal in response to a first port address signal, a second port address signal, an initial state parameter, a target state parameter, a first port enable signal, a second port enable signal, a write enable signal, a data input signal, a first location signal and a second location signal. The address locator circuit may be configured to generate the first location signal and the second location signal in response to the first port address signal, the second port address signal and the current address signal.

Abstract: An architecture includes a controller. The controller is configured to receive a microprogram. The microprogram is configured for performing at least one of hierarchical or a sequence of polynomial computations. The architecture also includes an arithmetic logic unit (ALU) communicably coupled to the controller. The ALU is controlled by the controller. Additionally, the microprogram is compiled prior to execution by the controller, the microprogram is compiled into a plurality of binary tables, and the microprogram is programmed in a command language in which each command includes a first portion for indicating at least one of a command or data transferred to the ALU, and a second portion for including a control command to the controller. The architecture and implementation of the programmable controller may be for cryptographic applications, including those related to public key cryptography.

Abstract: An apparatus including an initialization circuit and a hash computation circuit. The initialization circuit may be configured to present a number of initialization values. The hash computation circuit may be configured to generate hash values for the message in response to the padded message blocks and the initialization values. The hash computation circuit generally performs a diagonal cut technique that simultaneously uses values from a plurality of different cycle rounds in a single cycle round analog.

Abstract: An apparatus having a first circuit and a second circuit is disclosed. The first circuit may be configured to (i) generate second Galois Field elements by performing a first Galois Field inversion on first Galois Field elements, the first Galois Field inversion being different from a second Galois Field inversion defined by an Advanced Encryption Standard and (ii) generate third Galois Field elements by multiplying the second Galois Field elements by an inverse of a predetermined matrix. The second circuit may be configured to (i) generate fourth Galois Field elements by processing the third Galois Field elements in a current encryption round while in a non-skip mode, (ii) generate fifth Galois Field elements by multiplying the fourth Galois Field elements by the predetermined matrix and (iii) present the fifth Galois Field elements as updated versions of the first Galois Field elements in advance of a next encryption round.

Abstract: The present invention is a cryptoengine configured for providing countermeasures against attacks, including: an input/output (I/O) control unit, a memory, a controller, and an Arithmetic Logic Unit (ALU). The memory is communicatively coupled with the I/O control unit, receives inputs from the I/O control unit, and provides outputs to the I/O control unit based upon the received inputs. The controller is communicatively coupled with the I/O control unit for transmitting and receiving control signals. The ALU includes a plurality of storage components and computational components. The ALU is communicatively coupled with the controller and receives commands from/transmits status bits and flags to the controller. The ALU is further communicatively coupled with the memory and is configured for providing output signals to/receiving input signals from the memory. Further, the cryptoengine is configured for being communicatively coupled with a host computing device.

Abstract: The present invention concerns an apparatus including a modular memory and an address locator circuit. The modular memory may be configured to generate a current address signal, a first data output signal and a second data output signal in response to a first port address signal, a second port address signal, an initial state parameter, a target state parameter, a first port enable signal, a second port enable signal, a write enable signal, a data input signal, a first location signal and a second location signal. The address locator circuit may be configured to generate the first location signal and the second location signal in response to the first port address signal, the second port address signal and the current address signal.

Abstract: An apparatus comprising a controller, a plurality of transport circuits and a plurality of memory-controlling circuits. The controller may be configured to (i) present one or more commands and (ii) receive one or more responses. Each of the plurality of transport circuits may be configured to (i) receive one of the commands, (ii) present the responses, and (iii) generate one or more control signals. Each of the plurality of memory-controlling circuits may be (i) coupled to a respective one of the plurality of transport circuits and (ii) configured to (i) generate one or more memory access signals in response to the one or more control signals, (ii) receive one or more memory output signals from a respective memory in response to the one or more memory access signals and (iii) generate the responses in response to the one or more memory output signals. Each respective memory may be independently sized.

Abstract: A memory collar including a first circuit and a second circuit. The first circuit may be configured to generate one or more data sequences in response to one or more test commands. The one or more data sequences may be presented to a memory during a test mode. The second circuit may be configured to pre-process one or more outputs generated by the memory in response to the one or more data sequences.

Abstract: A memory collar includes a first circuit, a second circuit and a third circuit. The first circuit may be configured to generate a first control signal, a second control signal and a third control signal in response to one or more test commands. The second circuit may be configured to generate a fourth control signal in response to said third control signal and the fourth control signal. The third circuit may be configured to generate one or more address sequences. The one or more address sequences are presented to a memory during a test mode.

Abstract: An apparatus comprising a processor and an internal memory. The processor may be configured to test an external memory using (i) a netlist and (ii) a testing program. The internal memory may be configured to store the testing program. The testing program may be downloadable to the internal memory independently from the storing of the netlist.

Abstract: The present invention is directed to a sequential tester for longest prefix search engines. The tester may include a longest prefix search engine, an inputs generator for providing a nearly random flow of input commands to the longest prefix search engine and for outputting a floating rectangle which may represent a search table of the longest prefix search engine, a coding module for providing address and prefix information to the longest prefix search engine, a mapping module for providing data information to the longest prefix search engine, a super search engine for performing super search operations, and an analyzer for computing predicted outputs of the longest prefix search engine and for comparing the predicted outputs with actual outputs computed by the longest prefix search engine.

Abstract: A memory testing system for testing a plurality of memory locations in an electronic memory device is provided. The system includes a programmable memory device integrated into the electronic memory device capable of receiving and storing a compiled memory testing program. A processor is in communication with the programmable memory device to read and execute instructions from the compiled testing program stored in the programmable memory device and a command interpreter is configured to receive data from the processor related to commands to be executed during memory testing.

Abstract: A combination of an infrequently-called tiny multiplication unit and a “differential” unit that quickly computes T (n+1) basing on known T n. The schedule (how often the multiplication unit is called) can be considered as a parameter of the algorithm. The proposed architecture of the “differential” unit is efficient both in terms of speed (delay) and area (gate count).

Abstract: The present invention provides a memory BISR architecture for a slice. The architecture includes (1) a plurality of physical memory instances; (2) a Mem_BIST controller, communicatively coupled to the plurality of physical memory instances, for testing the plurality of physical memory instances; (3) a FLARE module, communicatively coupled to the Mem_BIST controller, including a scan chain of registers for storing test results of the plurality of physical memory instances, each of the plurality of physical memory instances M_i being assigned one FLARE bit f_i, i=1, 2, . . . , n, the FLARE module being used by the Mem_BIST controller to scan in an error vector F=(f—1, f—2, . . . , f_n); (4) a BISR controller, communicatively coupled to the FLARE module, a ROM module and a REPAIR_CONFIGURATION module, for scanning out the error vector F from the FLARE module to computer a repair configuration vector R=(r—1, r—2, . . .

Abstract: A memory timing model is provided, which includes an address input, a multiple-bit data input, a multiple-bit data output, a capacity C and a width N. N one-bit wide memory modules are instantiated in parallel with one another between respective bits of the data input and the data output. Each memory module has a capacity of C bits addressed by the address input.

Abstract: A circuit for implementing elliptic curve and hyperelliptic curve encryption and decryption operations, having a read only memory with no more than about two kilobytes of accessible memory, containing first programming instructions. An arithmetic logic unit has access to second programming instructions that are resident in a gate-level program disposed in the arithmetic logic unit, and is operable to receive data from no more than one input FIFO register. A microcontroller has no more than about two thousand gates, and is adapted to read the first programming instructions from the read only memory, send control signals to the arithmetic logic unit, and receive flags from the arithmetic logic unit. The arithmetic unit reads the third programming instructions, selectively performs elliptic curve and hyperelliptic curve encryption and decryption operations on the data according to the second programming instructions and the microcontroller, and sends output to no more than one output FIFO register.

Abstract: An architecture for a block cipher, where the architecture includes functional units that are logically reconfigurable so as to be able to both encrypt clear text into cipher text and decrypt cipher text into clear text using more than one block cipher mode based on at least one of advanced encryption standard and data encryption standard.