Patent Document

CROSS REFERENCE TO RELATED APPLICATION 
     This application claims the benefit of provisional application Ser. No. 60/315,655, filed Aug. 29, 2001, which is hereby incorporated by reference in its entirety. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates to digital processing systems and, more particularly, to methods and apparatus for improving processor performance by switching tasks in response to a cache miss. 
     BACKGROUND OF THE INVENTION 
     Embedded processors, such as those used in wireless applications, may include a digital signal processor, a microcontroller and memory on a single chip. In wireless applications, processing speed is critical because of the need to maintain synchronization with the timing of the wireless system. Low cost, embedded processor systems face unique performance challenges, one of which is the constraint to use low-cost, slow memory, while maintaining high throughput. 
     In the example of wireless applications, a digital signal processor (DSP) is often employed for computation intensive tasks. In this system, low-cost, off-chip flash memory forms the bulk storage capacity of the system. However, the flash memory access time is much longer than the minimum cycle time of the digital signal processor. To achieve high performance on the DSP, it should execute from local memory which is much faster than the off-chip flash memory. 
     Embedded processor systems may implement the local memory with some form of fill-on-demand cache memory control instead of or in addition to simple RAM, which requires another processor or a direct memory access (DMA) controller to load code and/or data into the local memory prior to or after the processor requires the code and/or data. 
     When the DSP encounters a cache miss, the cache hardware must fill a cache line from the slower memory in the memory hierarchy. This fill-on-demand aspect of the cache often means that the DSP is stalled while all or part of the cache line is filled. 
     Accordingly, there is a need for methods and apparatus for improving the throughput of cache-based embedded processors. 
     SUMMARY OF THE INVENTION 
     According to a first aspect of the invention, a method is provided for operating an embedded processor system that includes a processor and a cache memory. The method comprises filling one or more lines of the cache memory with data associated with a first task, executing the first task, and, in response to a cache miss during execution of the first task, performing a cache line fill operation and, during the cache line fill operation, executing a second task. 
     According to another aspect of the invention, an embedded processor system comprises a cache memory for storing data associated with a first task, and a processor for executing the first task. The cache memory includes a cache controller for detecting a cache miss, for performing a cache fill operation in response to the cache miss and for generating a cache miss notification. The processor, in response to a cache miss notification during execution of the first task, executes a second task during the cache fill operation. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       For a better understanding of the present invention, reference is made to the accompanying drawings, which are incorporated herein by reference and in which: 
         FIG. 1  is a simplified block diagram of a prior art embedded processor system; 
         FIG. 2  is a simplified block diagram of an embedded processor system in accordance with an embodiment of the invention; 
         FIG. 3  is a block diagram of an embodiment of the cache memory shown in  FIG. 2 ; and 
         FIG. 4  is a flow diagram of a routine implemented by the cache controller in accordance with an embodiment of the invention. 
     
    
    
     DETAILED DESCRIPTION 
     A block diagram of a prior art digital processing system is shown in  FIG. 1 . A processor such as a digital signal processor (DSP)  10  and a cache memory  12  are located on a single processing chip  14 . Cache memory  12  may be an instruction cache or a data cache. Some systems may include a data cache and an instruction cache. An off-chip flash memory  20  is coupled to cache memory  12 . Processing chip  14  may include other components, such as an on-chip memory, a microcontroller for executing microcontroller instructions, a direct memory access (DMA) controller and various interfaces to off-chip devices. 
     The cache memory  12  and the flash memory  20  form a memory hierarchy in which cache memory  12  has relatively low latency and relatively low capacity, and flash memory  20  has relatively high latency and relatively high capacity. In operation, DSP  10  executes instructions and accesses data and/or instructions in cache memory  12 . The low latency cache memory  12  provides high performance except when a cache miss occurs. In the case of a cache miss, a cache line fill operation is required to load the requested data from flash memory  20 . The time required to load a cache line from flash memory  20  may be several hundred clock cycles of DSP  10 . During the line fill operation, the DSP  10  is stalled, thereby degrading performance. 
     A simplified block diagram of a digital processing system in accordance with an embodiment of the invention is shown in  FIG. 2 . Like elements in  FIGS. 1 and 2  have the same reference numerals. An example of a suitable DSP is disclosed in PCT Publication No. WO 00/687 783, published Nov. 16, 2000. However, the invention is not limited to any particular digital signal processor. Further, the DSP  10  may be replaced by a microcontroller, a general purpose microcomputer or any other processor. 
     According to a feature of the invention, instead of stalling the DSP  10  for the duration of the cache line fill operation, the DSP  10  is redirected to execute an alternative software task, such as an interrupt service routine (ISR). Processing of the first software task can resume at a later time, when the cache line fill operation has completed. Referring to  FIG. 2 , a cache miss interrupt generator  30  detects a cache line fill operation, wherein cache memory  12  performs a cache line fill operation from flash memory  20 , and generates an interrupt to DSP  10 . In response, DSP  10  executes a second software task during the cache line fill operation. The disclosed method enhances performance by utilizing processor time in which the processor would otherwise be stalled waiting for completion of the cache line fill operation. 
     A software organization wherein the software is organized as multiple independent threads, which are managed by an operating system (OS) scheduler, can also take advantage of this approach. In this case, a new software thread may be started during the cache line fill operation. The multithreaded software organization can be viewed as a more general superset of the main routine/interrupt service routine model. The main/ISR model effectively includes two software threads, and the processor interrupt hardware functions as the task scheduler. 
     The elements of a system employing this approach are: (1) a processor with a much faster cycle time than the memory subsystems it accesses; (2) a processor sequencer organization which, upon recognizing an interrupt assertion of higher priority than the current task, aborts the instructions which have already entered the instruction pipeline and redirects instructions fetched to the new task. This functionality allows a load operation to start and to generate a memory access, but then be aborted, allowing another task to start; (3) code and/or data caches between the processor and the slower memory subsystems; and (4) software modularity such that independent tasks (e.g., interrupt processing or multiple threads) are available to run on the processor at any time. 
     The system may optionally include circuitry to signal the operating system that a cache miss has occurred, allowing the operating system to start the next pending software task/thread. Without this circuit, the processor stalls on a cache miss in the conventional way, unless an unrelated interrupt occurs while the processor is stalled. With the additional circuitry, the system can guarantee that the interrupt will always be taken on a cache miss. Another option is to include address range checking circuitry, such that the interrupt on a cache miss is generated only if the memory address associated with the cache miss is within a specified address range. The address range may be fixed or programmable. As an optional enhancement in embedded systems with multiple memory subsystems, with different access latencies (e.g., off-chip flash memory and on-chip SRAM memory), the cache can employ multiple line fill and copyback buffers to further enhance overall throughput. This enhancement also requires either separate buses between the cache controller and each of the memory systems, or a common bus employing out-of-order line fill protocols (e.g., bus data tagging). 
     Referring again to  FIG. 2 , when the DSP  10  generates a memory access which misses the cache memory  12 , but is cacheable, the cache controller generates a cache line fill operation to the off-chip flash memory  20 . The access time to fetch the entire cache line from flash memory can be hundreds of processor cycles. 
     The cache miss interrupt generator  30  determines that a cache line fill operation has been requested by the cache controller and generates an interrupt to DSP  10 . Since the DSP  10  aborts the instructions in the pipeline upon detection of an interrupt, it aborts the instruction which generated the cache line miss and begins execution of the interrupt service routine. 
     The interrupt service routine determines the next appropriate step. For example, the ISR may determine that a high priority task, which is resident in the local memory system, is available to run. As long as the ISR hits in the local cache (or, as is often the case, the ISR executes out of local RAM, which is accessed in parallel with the local cache), then the DSP  10  is not stalled for the lengthy time required to complete the cache line fill operation. When the ISR has run to completion, execution returns to the lower priority task which generated the cache miss. 
     In the more general multithreaded software model, the interrupt invokes the operating system scheduler, which then passes execution to the current highest priority software thread which can run in the available local memory resources. That software thread either (a) runs to completion, or (b) is preempted by the scheduler at some point, such that another thread can run, such as the thread that was preempted on the cache miss, assuming that the cache line fill operation has now been completed. 
     A block diagram of an embodiment of cache memory for implementing the present invention is shown in  FIG. 3 . The cache memory of  FIG. 3  corresponds to the cache memory  12  and the cache miss interrupt generator  30  of  FIG. 2 . As is conventional, the cache memory includes a tag array  100 , a data array  102 , hit/miss logic  104 , a store buffer  106  and a write buffer  108 . The cache memory further includes a cache controller  110  having circuitry for generating a cache miss signal, one or more line fill buffers  112 A and  112 B and one or more copyback buffers  114 A and  114 B. The cache memory may further include an address range compare circuit  120 . 
     When a read access is generated by DSP  10  during execution of a first task or thread, the read address is supplied to hit/miss logic  104 . The tag array  100  stores upper address bits to identify the specific address source in memory that the cached line represents. The tags are compared with the read address to determine whether the requested data is in the cache. In the case of a hit, the read data is supplied to the DSP  10 . In the case of a miss, a miss signal is supplied to cache controller  110  and a cache line fill operation is initiated. In the cache line fill operation, a cache line containing the requested data is read from flash memory  20 . The cache line is loaded into tag array  100  and data array  102  through line fill buffer  112  and is available for use by DSP  10 . 
     In the case of a cache miss, cache controller  110  supplies a cache miss signal to DSP  10  to initiate execution of a second task or thread by DSP  10 . In the case of a cache miss, the cache line that is replaced may be copied to flash memory  20  through copyback buffer  114 A,  114 B. Optionally, the cache memory may include two or more line fill buffers  112 A,  112 B and two or more copyback buffers  114 A,  114 B for enhanced performance in executing a second software task during the cache line fill operation. 
     Address range compare circuit  120  may optionally be provided to limit the address range over which a second task is executed during the cache line fill operation. In particular, the address range compare circuit  120  receives an upper address limit and a lower address limit, which may be fixed or programmable. Address range compare circuit  120  also receives the memory load address supplied to flash memory  20  in the case of a cache line fill operation. The address range compare circuit  120  may be configured to determine if the memory load address is between the upper address limit and the lower address limit, either inclusively or exclusively. In another approach, address range compare circuit  120  may determine if the memory load address is outside the range between the upper address limit and the lower address limit. In any case, if a specified comparison criteria is satisfied, a signal is supplied to cache controller  110  to enable the cache miss signal to be supplied to DSP  10 . 
     A flow chart of a routine for improving processor performance by switching tasks in response to a cache miss operation is shown in  FIG. 4 . In step  200 , the processor (DSP  10 ) executes task A by referencing operands and/or instructions in cache memory  12 . In step  202 , cache memory  12  determines if a cache miss has occurred. If a cache miss has not occurred, the processor continues to execute task A in step  200 . In the case of a cache miss, cache memory  12  begins a cache line fill operation in step  204 . The cache line fill operation loads a cache line containing the requested data from the flash memory  20  into cache memory  12 . In step  206 , the address range compare circuit  120  in cache memory  12  compares the cache miss address to a selected address range as described above. In step  208 , a determination is made as to whether the cache miss address meets a specified address range comparison criteria. If the cache miss address does not meet the address range comparison criteria, the processor waits for the cache line fill operation to complete in step  210  and returns to execution of task A in step  200 . If the cache miss address meets the address range comparison criteria, the processor is notified to change tasks in step  212 . With reference to  FIG. 3 , cache controller  110  sends a cache miss signal to DSP  10 . The processor then executes task B in step  214  during the cache line fill operation. It will be understood that steps  206 ,  208  and  210  associated with address range comparison are optional in the process of  FIG. 4 . 
     Having thus described several aspects of at least one embodiment of this invention, it is to be appreciated various alterations, modifications, and improvements will readily occur to those skilled in the art. Such alterations, modifications, and improvements are intended to be part of this disclosure, and are intended to be within the spirit and scope of the invention. Accordingly, the foregoing description and drawings are by way of example only.

Technology Category: 4