Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) for processing transmissions in a communications (e.g., CDMA) system. The method and system improve software instruction debugging operations by capturing real-time information relating to software execution flow and include and instructions and circuitry for operating a core processor process within a core processor. A non-intrusive debugging process operates within a debugging mechanism of a digital signal processor. Non-intrusively monitoring in real time predetermined aspects of software execution occurs with the core processing process and occurs in real-time on the processor. An embedded trace macrocell records selectable aspects of the non-intrusively monitored software execution and generates at least one breakpoint in response to events arising within the selectable aspects of the non-intrusively monitored software execution.

Abstract: In a particular embodiment, a method of monitoring interrupts during a power down event at a processor includes activating an interrupt monitor to detect interrupts. The method also includes isolating an interrupt controller of the processor from the interrupt monitor, where the interrupt controller shares a power domain with the processor. The method also includes detecting interrupts at the interrupt monitor during a power down time period associated with the power down event.

Abstract: DSP architectures having improved performance are described. In an exemplary architecture, a DSP includes two MAC units and two ALUs, where one of the ALUs replaces an adder for one of the two MAC units. This DSP may be configured to operate in a dual-MAC/single-ALU configuration, a single-MAC/dual-ALU configuration, or a dual-MAC/dual-ALU configuration. This flexibility allows the DSP to handle various types of signal processing operations and improves utilization of the available hardware. The DSP architectures further includes pipeline registers that break up critical paths and allow operations at a higher clock speed for greater throughput.

Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) for processing transmissions in a communications (e.g., CDMA) system. A method and system control transferring data between debugging registers and digital signal processor processes in association with a power transition sequence of the digital signal processor. In a digital signal processor, debugging registers associate with the core processor process and the debugging process. Control bits control transferring data among the debugging registers, the core processor process and the debugging process. The control bit prevents transferring data among the debugging registers, the core processor process and the debugging process in the event of a power transition sequence. Control bits also prevent a power transition sequence of the digital signal processor in the event of transferring data among the debugging registers and the core processor process or the debugging process.

Abstract: Techniques for debugging a programmable integrated circuit are described. Embodiments include steps of initiating instruction-cache-misses in the integrated circuit using a remote computer executing a test program; substituting, during an instruction-cache-miss event, instructions in the application program with test instructions provided by the test program; and debugging the integrated circuit based on analysis of its responses to the test instructions. In exemplary applications, such techniques are used for debugging graphics processors of wireless communication system-on-chip devices, among other programmable integrated circuit devices.

Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) for processing transmissions in a communications (e.g., CDMA) system. Inter-thread trace alignment with execution trace processing includes recording timing data relating to a common predetermined event. Such an event may be the number of cycles since a last thread initiated execution tracing or the number of cycles since all threads terminated execution tracing. The number of cycles at which a thread initiates execution tracing is referenced to the common predetermined event for maintaining the timing of execution tracing. The data relating to the common predetermined event is then updated to associate with the time at which the thread initiated execution tracing. The result is to permit aligning the timing data associated with all threads.

Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) for processing transmissions in a communications (e.g., CDMA) system. Trusted and untrusted debugging operational control occurs in operating a core processor associated with the digital signal processor. A debugging process within a debugging mechanism associates with the core processor. The core processor process determines the origin of debugging control as trusted debugging control or untrusted debugging control. In the event of trusted debugging control, the core processor process provides to the trusted debugging control a first set of features and privileges. Alternatively, in the event that debugging control is untrusted debugging control, the core processor process provides the untrusted debugging control a second restricted set of features and privileges, all for maintaining security and proper operation of the core processor process.

Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) for processing transmissions in a communications (e.g., CDMA) system. The disclosed method and system provide for processing instructions in a multi-threaded process including the use of breakpoint instructions for generating debugging event(s). Generating a debugging event occurs in response to the execution of breakpoint instructions and executes debugging instructions in response to the debugging event. The debugging instructions debug processing instructions in the multi-threaded processor by transitioning at least one or more threads into a debugging mode. The disclosure generates a debugging return for reporting the executing debugging instructions in the subset of the threads of the multi-threaded processor.

Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) for processing transmissions in a communications (e.g., CDMA) system. Stuffing instructions in a processing pipeline of a multi-threaded digital signal processor provides for operating a core processor process and a debugging process within a debugging mechanism. Writing a stuff instruction into a debugging process registry and a stuff command in a debugging process command register provides for identifying a predetermined thread of the multi-threaded digital signal processor in which to execute the stuff instruction. The instruction stuffing process issues a debugging process control resume command during a predetermined stage of executing on the predetermined thread and directs the core processor to perform the stuff instruction during the debugging process. The core processor may then execute the stuffed instruction in association with the core processor process and the debugging process.

Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) fox processing transmissions in a communications (e.g., CDMA) system. A method and system control transferring data between debugging registers and digital signal processor processes in association with a power transition sequence of the digital signal processor. In a digital signal processor, debugging registers associate with the core processor process and the debugging process. Control bits control transferring data among the debugging registers, the core processor process and the debugging process. The control bit prevents transferring data among the debugging registers, the core processor process and the debugging process in the event of a power transition sequence. Control bits also prevent a power transition sequence of the digital signal processor in the event of transferring data among the debugging registers and the core processor process or the debugging process.

Abstract: Techniques for the design and use of a digital signal processor, including (but not limited to) for processing transmissions in a communications (e.g., CDMA) system. The method and system improve software instruction debugging operations by capturing real-time information relating to software execution flow and include and instructions and circuitry for operating a core processor process within a core processor. A non-intrusive debugging process operates within a debugging mechanism of a digital signal processor. Non-intrusively monitoring in real time predetermined aspects of software execution occurs with the core processing process and occurs in real-time on the processor. An embedded trace macrocell records selectable aspects of the non-intrusively monitored software execution and generates at least one breakpoint in response to events arising within the selectable aspects of the non-intrusively monitored software execution.

Abstract: DSP architectures having improved performance are described. In an exemplary architecture, a DSP includes two MAC units and two ALUs, where one of the ALUs replaces an adder for one of the two MAC units. This DSP may be configured to operate in a dual-MAC/single-ALU configuration, a single-MAC/dual-ALU configuration, or a dual-MAC/dual-ALU configuration. This flexibility allows the DSP to handle various types of signal processing operations and improves utilization of the available hardware. The DSP architectures further includes pipeline registers that break up critical paths and allow operations at a higher clock speed for greater throughput.

Abstract: Two multiply-accumulate units are coupled together so that the computation (B*C)+(D*E) can be completed in one cycle. An adder (216) adds together the products of the two multipliers (206), (208). The sum is applied to the first accumulator (220). Preferably, the second product is also applied to the second accumulator (222), and a multiplexer (218) applies either a zero or the second product to the adder (216). If two unrelated computations are to be executed simultaneously, then the zero is applied, and the output of the second accumulator is fed back to the register file (PI2). If a single (B*C)+(D*E) computation is to be executed, then the second product is applied to the adder, and the output of the second accumulator is disregarded.