A multiplexer circuit includes first and second fins each extending in an X-axis direction. First, second, third and fourth gates extend in a Y-axis direction perpendicular to the X-axis direction and contact the first and second fins. The first, second, third and fourth gates are configured to receive first, second, third and fourth data signals, respectively. Fifth, sixth, seventh and eighth gates extend in the Y-axis direction and contact the first and second fins, the fifth, sixth, seventh and eighth gates, and are configured to receive the first, second, third and fourth select signals, respectively. An input logic circuit is configured to provide an output at an intermediate node. A ninth gate extends in the Y-axis direction and contacts the first and second fins. An output logic circuit is configured to provide a selected one of the first, second, third and fourth data signals at an output terminal.

A multiplexer circuit includes first and second fins each extending in an X-axis direction. First, second, third and fourth gates extend in a Y-axis direction perpendicular to the X-axis direction and contact the first and second fins. The first, second, third and fourth gates are configured to receive first, second, third and fourth data signals, respectively. Fifth, sixth, seventh and eighth gates extend in the Y-axis direction and contact the first and second fins, the fifth, sixth, seventh and eighth gates, and are configured to receive the first, second, third and fourth select signals, respectively. An input logic circuit is configured to provide an output at an intermediate node. A ninth gate extends in the Y-axis direction and contacts the first and second fins. An output logic circuit is configured to provide a selected one of the first, second, third and fourth data signals at an output terminal.

A memory block circuit can include a plurality of data interfaces, a switch connected to each data interface of the plurality of data interfaces, and a plurality of memory banks each coupled to the switch. Each memory bank can include a memory controller and a random access memory connected to the memory controller. The memory block circuit also includes a control interface and a management controller connected to the control interface and each memory bank of the plurality of memory banks. Each memory bank can be independently controlled by the management controller.

Implementing a circuit design can include determining a chain of a plurality of loop elements of a circuit design, wherein each loop element includes a bit select node configured to perform a bit assignment operation and a corresponding address calculation node, wherein the address calculation nodes use a common variable to calculate a starting bit location provided to the corresponding bit select node. In response to the determining, the chain is replicated resulting in one chain for each value of the common variable and transforming each chain into a plurality of wires. A multiplexer is inserted into the circuit design. The plurality of wires for each chain is coupled to inputs of the multiplexer and the common variable is provided to the multiplexer as a select signal.

An integrated circuit includes first and second circuit blocks. The first circuit block includes a first storage circuit. A first data path passes through the first storage circuit and a first multiplexer circuit to a first input of a first logic circuit. The first multiplexer circuit is coupled to the first storage circuit. A second storage circuit is coupled between the first storage circuit and the first multiplexer circuit. A second data path passes through the second circuit block to a second input of the first logic circuit. The first multiplexer circuit is configurable to bypass or to couple the second storage circuit in the first data path based on an indication of whether a redundant third circuit block is coupled between the first and second circuit blocks in at least one of the first data path or the second data path.

A multiplexer circuit includes first and second fins each extending in an X-axis direction. First, second, third and fourth gates extend in a Y-axis direction perpendicular to the X-axis direction and contact the first and second fins. The first, second, third and fourth gates are configured to receive first, second, third and fourth data signals, respectively. Fifth, sixth, seventh and eighth gates extend in the Y-axis direction and contact the first and second fins, the fifth, sixth, seventh and eighth gates, and are configured to receive the first, second, third and fourth select signals, respectively. An input logic circuit is configured to provide an output at an intermediate node. A ninth gate extends in the Y-axis direction and contacts the first and second fins. An output logic circuit is configured to provide a selected one of the first, second, third and fourth data signals at an output terminal.

A multiplexer circuit includes first and second fins each extending in an X-axis direction. First, second, third and fourth gates extend in a Y-axis direction perpendicular to the X-axis direction and contact the first and second fins. The first, second, third and fourth gates are configured to receive first, second, third and fourth data signals, respectively. Fifth, sixth, seventh and eighth gates extend in the Y-axis direction and contact the first and second fins, the fifth, sixth, seventh and eighth gates, and are configured to receive the first, second, third and fourth select signals, respectively. An input logic circuit is configured to provide an output at an intermediate node. A ninth gate extends in the Y-axis direction and contacts the first and second fins. An output logic circuit is configured to provide a selected one of the first, second, third and fourth data signals at an output terminal.