The present application discloses a signal channel switching method, a display terminal and a computer-readable storage medium. The signal channel switching method includes the following operations: establishing a data connection with a first external device connected with a first hot plug pin; obtaining a first voltage detected by a second hot plug pin, and judging whether the first voltage conforms to a preset rule; if the first voltage conforms to the preset rule, obtaining information of a second external device connected with the second hot plug pin; cutting off the data connection with the first external device and establishing a data connection with the second external device according to the information of the second external device.

The present disclosure relates to asymmetric read/write architectures for enhanced throughput and reduced latency. One example embodiment includes an integrated circuit. The integrated circuit includes a network interface. The integrated circuit also includes a communication bus interface. The integrated circuit is configured to establish a communication link with a processor of the host computing device over the communication bus interface, which includes mapping to memory addresses associated with the processor of the host computing device. The integrated circuit is also configured to receive payload data for transmission over the network interface in response to the processor of the host computing device writing payload data to the mapped memory addresses using one or more programmed input-outputs (PIOs). Further, the integrated circuit is configured to write payload data received over the network interface to the memory of the host computing device using direct memory access (DMA).

An electronic device comprises a bridge configured to transfer data bus transactions from a transaction source domain having a first bus width to a transaction target domain having a second bus width less than the first bus width. The bridge comprises a first interface configured to receive a transaction from the transaction source domain, where the transaction has a first transaction burst length. A converter logic is configured such that when a transaction is received via the first interface, the converter logic splits the transaction into a plurality of second transactions each having a respective second transaction burst length, wherein the plurality of second transactions have the second bus width. A second interface is configured to send the plurality of second transactions to the transaction target domain.

A method of mediating a read transaction from a transaction source domain having a first bus width to a transaction target domain having a second bus width less than the first bus width. The method includes receiving first and second read transactions associated with a first and second transaction ID, separating each read transaction into a plurality of sub-transactions, which have the second bus width. The method further includes sending a sub-transaction of each plurality of sub-transactions to the transaction target domain and receiving first data associated with the first transaction ID and second data associated with the second transaction ID, storing the first data in a first storage element assigned to a first list, storing the second data in a second storage element assigned to a second list; and reading out data to the transaction source domain from the first list and the second list independently of each other.

A computer-implemented method includes using a transmitter to send data from the transmitter through a plurality of lanes to a receiver using a synchronous operation mode that includes sending the data from the transmitter through the plurality of lanes to the receiver in a synchronous transmission manner that relies on an alignment between a transmitter clock frequency and a receiver clock frequency. A synchronous operation performance analysis (SOPA) is performed during the synchronous operation mode. A switch from the synchronous operation mode to an asynchronous operation mode is made based on a result of performing the SOPA. The asynchronous operation mode includes sending the data from the transmitter through the plurality of lanes to the receiver without requiring alignment between the transmitter clock frequency and the receiver clock frequency.

A method for data transmission and a data-processing circuit are provided. The data-processing circuit includes a memory that implements a buffer and a controller for controlling an operation of the data-processing circuit. When the data-processing circuit receives input data, data-hot-bits are used to address multiple data blocks of the input data. After analyzing the data-hot-bits, a starting address and a data length of each of the data blocks can be obtained. The input data is written to the buffer according to information analyzed from the data-hot-bits, and the data-hot-bits achieve an effect of masking the dummy data address. Further, data dependency among the data blocks can be confirmed by comparing the data-hot-bits with respect to each of the data blocks before the data blocks are written to the buffer.

Systems and devices can include an upstream port, a downstream port, and a multilane link connecting the upstream port to the downstream port, the multilane link comprising a first link width. The upstream port or the downstream port can be configured to determine that the downstream port is to operate using a second link width, the second link width less than the first link width; transmit to the upstream port an indication of a last data block for the first link width across one or more lanes of the multilane link; cause a first set lanes to enter an idle state; and transmit data on a second set of lanes, the second set of lanes defining the second link width.

Embodiments herein describe on-demand packetization where data that is too large to be converted directly into data words (DWs) for a chip-to-chip (C2C) interface are packetized instead. When identifying a protocol word that is larger than the DW of the C2C interface, a protocol layer can perform packetization where a plurality of protocol words are packetized and sent as a transfer. In one embodiment, the protocol layer removes some or all of the control data or signals in the protocol words so that the protocol words no longer exceed the size of the DW. These shortened protocol words can then be mapped to DWs and transmitted as separate packets on the C2C. The protocol layer can then collect the portion of the control data that was removed from the protocol words and transmit this data as a separate packet on the C2C interface.

The present invention provides a SerDes interface circuit and a control device which make it possible to use the same SerDes to perform data transfer of different communication rates. The present invention includes: a FIFO that inputs a first clock of a first frequency, first transmission data based on the first clock, and a second clock of a second frequency which is different from the first frequency, and that outputs the first transmission data on the basis of the second clock in the order of input; a flipflop that fetches and holds the FIFO output on the basis of the second clock; and an output state machine operating with the second clock that inputs the FIFO output and the flipflop output, and generates parallel data in which the same data corresponding to the first transmission data is consecutive.

Embodiments herein describe on-demand packetization where data that is too large to be converted directly into data words (DWs) for a chip-to-chip (C2C) interface are packetized instead. When identifying a protocol word that is larger than the DW of the C2C interface, a protocol layer can perform packetization where a plurality of protocol words are packetized and sent as a transfer. In one embodiment, the protocol layer removes some or all of the control data or signals in the protocol words so that the protocol words no longer exceed the size of the DW. These shortened protocol words can then be mapped to DWs and transmitted as separate packets on the C2C. The protocol layer can then collect the portion of the control data that was removed from the protocol words and transmit this data as a separate packet on the C2C interface.