Negative path testing in a bootloader environment can include backing up a global state of a component under test, injecting a fault to trigger an error in the component under test in a bootloader environment, executing error handling instructions until a checkpoint of the component under test in the bootloader environment is reached, restoring the global state to the component under test from the backup, and restarting the component under test.

An information handling system includes a first memory, a second memory, and a central processor. The first memory includes a buffer to store uncorrected no action (UCNA) errors for the second memory. The central processor detects a memory data corruption in the second memory, stores a first UCNA error associated with the memory data corruption in the buffer implemented within the first memory, determines whether the buffer is full, and erases an oldest in time UCNA error from the buffer in response to the buffer being full.

A register array includes a plurality of groups of latches. Each of the groups of latches includes a first latch, a second latch, and a test latch connected to the first latch and the second latch. During functional operation the first latch and the second latch process data, in response to the same read/write clock signal supplied simultaneously to the first read/write clock input and the second read/write clock input. During test operation a skewed test clock signal of an original test clock signal is supplied at different timings to the first latch, the second latch, and the test latch, and a single scan signal is input to the first latch. The single scan signal cascades from the first latch through the test latch to the second latch, and is output by the second latch, within a single cycle of the original test clock signal.

A circuit and method provide efficient stress testing of address translations in an integrated circuit such as a link processing unit. A random DMA mode (RDM) circuit provides a random input to index into a translation validation table (TVT) that is used to generate the real memory address. The RDM circuit allows testing all entries of the TVT, and thus all DMA modes, regardless of what bus agents are connected to the link processing unit. The RDM circuit may use a multiplexer to select between a runtime input and a random test input provided by the random bit generator. When the link processing unit is in a test mode a mode selection bit is asserted to select the random test input.

A circuit and method provide efficient stress testing of address translations in an integrated circuit such as a link processing unit. A random DMA mode (RDM) circuit provides a random input to index into a translation validation table (TVT) that is used to generate the real memory address. The RDM circuit allows testing all entries of the TVT, and thus all DMA modes, regardless of what bus agents are connected to the link processing unit. The RDM circuit may use a multiplexer to select between a runtime input and a random test input provided by the random bit generator. When the link processing unit is in a test mode a mode selection bit is asserted to select the random test input.

This document describes aspects of communicating information about repair elements of a memory device. A memory device can include multiple repair elements that can each replace a defective or damaged memory element, such as a memory row, using a repair operation. By knowing a quantity of remaining available repair elements, a user of a memory device can make informed decisions about whether to make a replacement. In operation, a host device can send a command to the memory device requesting repair element information. Logic of the memory device can determine a quantity of repair elements that are available for a repair operation. In some cases, the logic may store this quantity in a register of the memory device. The memory device can signal the quantity of repair elements to the host device in response to the command.

A semiconductor system may include a first semiconductor device and a second semiconductor device. The first semiconductor device may be configured to output a reset signal, command/address signals and data. The second semiconductor device may be configured to generate internal commands, internal addresses and internal data for performing an initialization operation. The second semiconductor device may be configured to store the internal data in a plurality of memory cells selected by the internal commands and the internal addresses.

Disclosed are methods and electronic devices that communicate with a reader. The methods and devices may receive a command emitted by the reader, and then select an application to be executed by the device based on the command that is received. The methods and devices may also determine whether to perform one or more self test according to which application was selected.

A method for a compliance test on a communication node, performed in a gateway constituting a vehicle network of a vehicle, may include: receiving a test mode request signal for the compliance test on the communication node; transmitting the test mode request signal to the communication node on which the compliance test is performed; receiving an output signal according to the test mode request signal from the communication node; and transmitting the received output signal to a fixture connected to a test apparatus which performs the compliance test on the communication node.

A method of monitoring operations of a set of ICs. The method loads a first set of configuration data into a first IC for configuring a group of configurable circuits of the first IC to perform operations of a user design. The method receives a definition of an event based on values of a set of signals in the user design and a set of corresponding actions to take when the event occurs. The set of signals includes at least one signal received from a second IC. The method generates an incremental second set of configuration data based on the definition of the event and the set of corresponding actions. While the first IC is performing the operations of the user design, the method loads the incremental second set of configuration data into the first IC and monitors the signals received from the second IC at the first IC.