Abstract: An integrated circuit having a normal mode for operating under normal operating conditions and a debug mode for operating to test and debug the integrated circuit. The integrated circuit includes a plurality of output pins that carry a first plurality of signals in the normal mode and carry a second plurality of signals in the debug mode. In one embodiment, the integrated circuit embodies a microprocessor. The microprocessor may include logic circuitry for enabling the second plurality of signals to be output from a multiplexer to the output pins in response to a predetermined event, such as a hit in an associated memory unit.

Abstract: A pipeline control system for implementing a virtual architecture having a complex instruction set is distributed over RISC-like semi-autonomous functional units in a processor. Decoder logic fetches instructions of the target architecture and translates them into simpler RISC-like operations. These operations, each having an associated tag, are issued to the functional units. Address processing unit computes addresses of the instructions and operands, performs segment relocation, and manages the processor's memory. Operations are executed by the units in a manner that is generally independent of operation processing by the other units. The units report termination information back to the decoder logic, but do not irrevocably change the state of the machine. Based on the termination information, the decoder logic retires normally terminated operations in order.

Abstract: A pipeline control system is distributed over the functional units (15, 17, 20, 25) in a processor (10). Decoder logic (12) issues operations, each with an associated tag, to the functional units, with up to n operations allowed to be outstanding. The units execute the operations and report termination information back to the decoder logic, but do not irrevocably change the state of the machine. Based on the termination information, the decoder logic retires normally terminated operations in order. If an operation terminates abnormally, the decoder logic instructs the units to back out of those operations that include and are later than the operation that terminated abnormally.

Abstract: A pipeline control system for implementing a virtual architecture having a complex instruction set is distributed over RISC-like semi-autonomous functional units in a processor. Decoder logic fetches instructions of the target architecture and translates them into simpler RISC-like operations. These operations, each having an associated tag, are issued to the functional units. Address processing unit computes addresses of the instructions and operands, performs segment relocation, and manages the processor's memory. Operations are executed by the units in a manner that is generally independent of operation processing by the other units. The units report termination information back to the decoder logic, but do not irrevocably change the state of the machine. Based on the termination information, the decoder logic retires normally terminated operations in order.

Abstract: A pipeline control system for implementing a virtual architecture having complex instruction set is distributed over RISC-like semi-autonomous functional units in a processor. Decoder logic fetches instructions of the target architecture and translates them into simpler RISC-like operations. These operations, each having an associated tag, are issued to the functional units. Address processing unit computes addresses of the instructions and operands, performs segment relocation, and manages the processor's memory. Operations are executed by the units in a manner that is generally independent of operation processing by the other units. The units report termination information back to the decoder logic, but do not irrevocably change the state of the machine. Based on the termination information, the decoder logic retires normally terminated operations in order.

Abstract: A pipeline control system is distributed over the functional units (15, 17, 20, 25) in a processor (10). Decoder logic (12) issues operations, each with an associated tag, to the functional units, with up to n operations allowed to be outstanding. The units execute the operations and report termination information back to the decoder logic, but do not irrevocably change the state of the machine. Based on the termination information, the decoder logic retires normally terminated operations in order. If an operation terminates abnormally, the decoder logic instructs the units to back out of those operations that include and are later than the operation that terminated abnormally.

Abstract: A dual-bus architecture that includes a high-speed system bus, called the NexBus (20), and a slower peripheral bus, called the alternate bus or AB (25). The NexBus and AB are coupled by control logic (45) which includes an arbiter (50) and an alternate bus interface (ABI) (60). The ABI is treated as a master for both the NexBus and the AB. While it would be possible to have the adapter always request the AB (which also requires the NexBus), that would slow down NexBus operations to the bandwidth of the AB. This problem is avoided by providing two request lines for each adapter, -NREQ (NexBus only) and -AREQ (both buses), having the adapter normally assert -NREQ first. However, if the addressed device is on the AB, the ABI automatically detects this fact and attempts to do a crossing transfer to the AB, even though the request was for the NexBus only.

Abstract: A voltage-controlled delay element utilizes a current-starved inverter configuration with a feedback path that ensures a rapid discharge of the storage node to ground once the desired delay time has elapsed. The circuit comprises a circuit path for charging the storage node (preferably rapidly), a first pull-down path capable of discharging the storage node at a rate determined by the control voltage, a second pull-down path capable of rapidly discharging the storage node, an output inverter, and a feedback connection between the output terminal of the output inverter and the second pull-down path to rapidly discharge the storage node when the output voltage starts rising. The circuit further comprises a means for programmably adjusting the delay in response to logic signals.

Abstract: A pipeline control system is distributed over the functional units (15, 17, 20, 25) in a processor (10). Decoder logic (12) issues operations, each with an associated tag, to the functional units, with up to n operations allowed to be outstanding. The units execute the operations and report termination information back to the decoder logic, but do not irrevocably change the state of the machine. Based on the termination information, the decoder logic retires normally terminated operations in order. If an operation terminates abnormally, the decoder logic instructs the units to back out of those operations that include and are later than the operation that terminated abnormally.

Abstract: A dual-bus architecture that includes a high-speed system bus, called the NexBus (20), and a slower peripheral bus, called the alternate bus or AB (25). The NexBus and AB are coupled by control logic (45) which includes an arbiter (50) and an alternate bus interface (ABI) (60). The ABI is treated as a master for both the NexBus and the AB. While it would be possible to have the adapter always request the AB (which also requires the NexBus), that would slow down NexBus operations to the bandwidth of the AB. This problem is avoided by providing two request lines for each adapter, -NREQ (NexBus only) and -AREQ (both buses), having the adapter normally assert -NREQ first. However, if the addressed device is on the AB, the ABI automatically detects this fact and attempts to do a crossing transfer to the AB, even though the request was for the NexBus only.

Abstract: A bus system wherein N-bit devices (12b,12c) attached to the lower half (30L) of a 2N-bit bus (30) communciate with 2N-bit (12a, 12d) devices attached to the full bus. Bi-directional registered transceivers (60,62,65,67) are coupled between the upper and lower halves of the bus. The N-bit devices are capable of asserting a pair of signals called HOLDN and LATCHN. For a 2 N-bit source device transmitting data to an N-bit sink device, the 2 N-bit source puts 2 N bits of data on the upper and lower halves of the bus during a given cycle, during which the N-bit sink device samples the N bits on the lower half of the bus. The assertion of HOLDN causes the N bits on the upper half of the bus to be latched and subsequently driven onto the lower half of the bus. Where an N-bit source device is communicating to a 2 N-bit sink device, the N-bit device puts the high order N bits and low order N bits of data on the lower half of the bus on successive cycles.

Abstract: A dual-bus architecture that includes a high-seed system bus, called the NexBus (20), and a slower peripheral bus, called the alternate bus or AB (25). The NexBus and AB are coupled by control logic (45) which includes an arbiter (50) and an alternate bus interface (ABI) (60). The ABI is treated as a master for both the NexBus and the AB. While it would be possible to have the adapter always request the AB (which also requires the NexBus), that would slow down NexBus operations to the bandwidth of the AB. This problem is avoided by providing two request lines for each adapter, -NREQ (NexBus only) and -AREQ (both buses), having the adapter normally assert -NREQ first. However, if the addressed device is on the AB, the ABI automatically detects this fact and attempts to do a crossing transfer to the AB, even though the request was for the NexBus only.

Abstract: A pipeline control system is distributed over the functional units (15, 17, 20, 25) in a processor (10). Decoder logic (12) issues operations, each with an associated tag, to the functional units, with up to n operations allowed to be outstanding. The units execute the operations and report termination information back to the decoder logic, but do not irrevocably change the state of the machine. Based on the termination information, the decoder logic retires normally terminated operations in order. If an operation terminates abnormally, the decoder logic instructs the units to back out of those operations that include and are later than the operation that terminated abnormally.

Abstract: A technique that efficiently allocates the servicing of interrupts among a plurality of CPUs in a multiprocessor computer system requires no change in software that was written for a system with one CPU and one PIC. Symmetric and asymmetric configurations contemplate a primary CPU (15a) and one or more secondary CPU's (15b-d) responding to and servicing multiple sets of interrupts. Both configurations include interrupt supervisory logic to support such operation. The symmetric configuration provides a PIC (20a-d) for each CPU in the system. All the PICs are located at the same I/O address, and separate provision is made to specify which PIC is to respond to an interrupt acknowledge cycle initiated by a particular CPU. The asymmetric configuration of the present invention provides PIC (20a) for the primary CPU (15a) only. That PIC's interrupt line is communicated only to the primary CPU. Another mechanism, such as an ATTN facility (95), is provided to drive the secondary CPU's interrupt inputs.

Abstract: A data processing system in which interleaving among memory controllers may be controlled. The interleaving is carried out on a double-word basis, and the state of the double-word address bit is used to select the bus address of the memory controller in which double-words having that address bit are stored. The dynamically controllable interleaving allows greater flexibility in the design of the memory controllers in a data processing system.

Abstract: A very high speed data bus system for communication among the various functional units that may constitute a large computer system. The bus communication medium comprises a number of line pairs on the backplane, and the bus system comprises a bus control unit for arbitrating requests from a plurality of interface units or ports, there being one such port associated with each functional unit. The functional units are densely packed, that is, mounted in immediately adjacent connectors to define a populated section of the backplane in which all connectors have ports coupled thereto, and one or two unpopulated sections of the backplane in which the connectors are empty. In the populated section, the effective characteristic impedance, designated Z.sub.O ', is lower than the effective characteristic impedance, designated Z.sub.O, in the unpopulated region. A populated end of the transmission line is resistively terminated with a resistance corresponding to Z.sub.

Abstract: A very high speed data bus system for communication among the various functional units that may constitute a large computer system. The bus communication medium comprises a number of line pairs on the backplane, and the bus system comprises a bus control unit for arbitrating requests from a plurality of interface units or ports, there being one such port associated with each functional unit. The functional units are densely packed, that is, mounted in immediately adjacent connectors to define a populated section of the backplane in which all connectors have ports coupled thereto, and one or two unpopulated sections of the backplane in which the connectors are empty. In the populated section, the effective characteristic impedance, designated Z.sub.0 ', is lower than the effective characteristic impedance, designated Z.sub.0, in the unpopulated region. A populated end of the transmission line is resistively terminated with a resistance corresponding to Z.sub.

Abstract: In a high speed data bus system, each functional unit has an associated port which operates to accept all related information that makes up a communication, or if this cannot be done, to accept none of the information. More particularly, an information transfer, depending on its nature, may comprise one BIQ or more than one BIQ (a "BIQ" is a bus information quantum which is placed on the bus for one bus cycle). To implement the indivisibility of multiple-BIQ transfers, the control logic for each port includes screening circuitry responsive to the state of the port's input buffers, and further responsive to flags from the functional unit for selectively accepting or rejecting BIQ's, and further includes screening constraint circuitry to ensure that the port accepts all or none of the BIQ's that make up the transfer. Depending on the flag, the rejection may be total, or may apply only to a designated class of transfers (for example, operations).