A method includes identifying state holding pipeline stages in a pipeline path of a design for test (DFT) of an integrated circuit design, splitting each pattern of a plurality of patterns into a first part and a second part, reformatting the plurality of patterns to generate another plurality of patterns such that the first part and the second part of each pattern of the plurality patterns are included in different patterns of the another plurality of patterns. The length of the first part is a function of a number of the identified pipeline stages.

Testability of memory on integrated circuits is improved by connecting storage elements like latches in memory to scan chains and configuring memory for scan dump. The use of latches and similar compact storage elements to form scannable memory can extend the testability of high-density memory circuits on complex integrated circuits operable at high clock speeds. A scannable memory architecture includes an input buffer with active low buffer latches, and an array of active high storage latches, operated in coordination to enable incorporation of the memory into scan chains for ATPG/TT and scan dump testing modes.

In an embodiment, a method for performing scan includes: entering scan mode; receiving a test pattern; applying the test pattern through a first scan chain by asserting and deasserting a scan enable signal to respectively perform shift and capture operations to the first scan chain; while applying the test pattern through the first scan chain, controlling a further scan flip-flop with the first scan chain without transitioning a further scan enable input of the further scan flip-flop; and evaluating an output of the first scan chain to detect faults.

A system-on-chip (SoC) is disclosed. The SoC includes a set of input channels, a first partition including a set of output wrapper chains, a set of output channels, a second partition including a set of input wrapper chains, and an inter-partition circuit coupled between the first and second partitions. During an external test mode, the set of input channels receives input test data. The set of output wrapper chains receives and stores intermediate data that is generated based on the input test data. The inter-partition circuit receives the intermediate data from the set of output wrapper chains and generates test response data based on the intermediate data. The set of input wrapper chains receives the test response data, and provides the test response data to be captured as output test data at the set of output channels to test the inter-partition circuit.

A memory tester of the present embodiment includes a first memory, a second memory, an arithmetic circuit, and a determination circuit. The first memory is configured to store scan input data and expected value data, the scan input data including a don't care bit, the expected value data being obtained by converting the don't care bit into a first predetermined value. The second memory is configured to store scan output data and mask data obtained by converting a value of the scan input data other than the don't care bit into a second predetermined value. The arithmetic circuit is configured to perform an exclusive or operation between the expected value data and the scan output data. The determination circuit is configured to determine whether the don't care bit of an arithmetic result from the arithmetic circuit is passed or failed by using the mask data.

Electronic scan circuitry includes a decompressor (510), a plurality of scan chains (520.i) fed by the decompressor (510), a scan circuit (502, 504) coupled to the plurality of scan chains (520.i) to scan them in and out, a masking circuit (590) fed by the scan chains (520.i), and a scannable masking qualification circuit (550, 560, 580) coupled to the masking circuit (590), the masking qualification circuit (550, 560, 580) scannable by scan-in of bits by the decompressor (510) along with scan-in of the scan chains (520.i), and the scannable masking qualification circuit (550, 560, 580) operable to hold such scanned-in bits upon scan-out of the scan chains through the masking circuit (590). Other scan circuitry, processes, circuits, devices and systems are also disclosed.

The disclosure describes novel methods and apparatuses for accessing test compression architectures (TCA) in a device using either a parallel or serial access technique. The serial access technique may be controlled by a device tester or by a JTAG controller. Further the disclosure provides an approach to access the TCA of a device when the device exists in a daisy-chain arrangement with other devices, such as in a customer's system. Additional embodiments are also provided and described in the disclosure.

A circuit comprises: a register configured to be a linear finite state machine and comprising storage elements, injection devices, one or more input channels for injecting variables using the injection devices, and one or more feedback devices; a plurality of phase shifters, each of the plurality of phase shifters configured to receive signals from a unique segment of the register; scan chains, serial inputs of the scan chains configured to receive signals from outputs of the plurality of phase shifters, wherein the one or more input channels are coupled to the injection devices at injection points in the register, each of the injection points being assigned to one of the one or more input channels based on lifespan values for the injection points, the injection points being determined based on one or more predetermined requirements.

The disclosure describes novel methods and apparatuses for controlling a device's TCA circuit when the device exists in a JTAG daisy-chain arrangement with other devices. The methods and apparatuses allow the TCA test pattern set used during device manufacturing to be reused when the device is placed in a JTAG daisy-chain arrangement with other devices, such as in a customers system using the device. Additional embodiments are also provided and described in the disclosure.

A method for testing a many-core processor comprises grouping a plurality of cores in the processor into a plurality of super cores, wherein each super core comprises one or more scan chains that propagate through a respective super core. Further, the method comprises grouping the plurality of super cores into a plurality of clusters. The method also comprises comparing one or more scan chain outputs of respective super cores in each cluster using a network of XOR and OR gates to generate a single bit fault signature for each scan chain in a respective cluster and compacting the single bit fault signatures for each scan chain using a hybrid of spatial and temporal compactors to generate a single bit fault signature for each cluster. The method also comprises method of using a cost function to obtain hierarchical parameters to achieve optimized ATPG effort, area overhead and test time.