Abstract: A microcontroller using an optimized buffer replacement strategy comprises a memory configured to store instructions, a processor configured to execute said program instructions, and a memory accelerator operatively coupled between the processor and the memory. The memory accelerator is configured to receive an information request and overwrite the buffer from which the prefetch was initiated with the requested information when the request is fulfilled by a previously initiated prefetch operation.

Abstract: A memory accelerator module buffers program instructions and/or data for high speed access using a deterministic access protocol. The program memory is logically partitioned into ‘stripes’, or ‘cyclically sequential’ partitions, and the memory accelerator module includes a latch that is associated with each partition. When a particular partition is accessed, it is loaded into its corresponding latch, and the instructions in the next sequential partition are automatically pre-fetched into their corresponding latch. In this manner, the performance of a sequential-access process will have a known response, because the pre-fetched instructions from the next partition will be in the latch when the program sequences to these instructions. Previously accessed blocks remain in their corresponding latches until the pre-fetch process ‘cycles around’ and overwrites the contents of each sequentially-accessed latch.

Abstract: A memory accelerator module buffers program instructions and/or data for high speed access using a deterministic access protocol. The program memory is logically partitioned into ‘stripes’, or ‘cyclically sequential’ partitions, and the memory accelerator module includes a latch that is associated with each partition. When a particular partition is accessed, it is loaded into its corresponding latch, and the instructions in the next sequential partition are automatically pre-fetched into their corresponding latch. In this manner, the performance of a sequential-access process will have a known response, because the pre-fetched instructions from the next partition will be in the latch when the program sequences to these instructions. Previously accessed blocks remain in their corresponding latches until the pre-fetch process ‘cycles around’ and overwrites the contents of each sequentially-accessed latch.

Abstract: A processing system supports memory access based on distinct memory space access instructions as well as universal access instructions that are independent of memory space partitions. Conventional memory-space dependent instructions, such as MOV, MOVX, and MOVC, provide an optimized addressing scheme, and an extended memory-space independent instruction EMOV provides an optimized code efficiency, processing speed, and ease of code generation. A mapping between the discrete memory space partitions and a “universal” memory space allocation is provided. The processing hardware interprets the universal address to determine the corresponding memory space, and provides the access to an address within that memory space.

Abstract: A memory access architecture and technique employs multiple independent buffers that are configured to store items from memory sequentially. The memory is logically partitioned, and each independent buffer is associated with a corresponding memory partition. The partitioning is cyclically sequential, based on the total number of buffers, K, and the size of the buffers, N. The first N memory locations are allocated to the first partition; the next N memory locations to the second partition; and so on until the Kth partition. The next N memory locations, after the Kth partition, are allocated to the first partition; the next N locations are allocated to the second partition; and so on. When an item is accessed from memory, the buffer corresponding to the item's memory location is loaded from memory, and a prefetch of the next sequential partition commences to load the next buffer.

Abstract: A processing system with extended addressing capabilities includes a control bit that controls the number of address bytes that are stored onto a program stack. If the control bit is set to a first state, the address is pushed onto the program stack in the same manner as that used for shorter-address legacy devices. If the control bit is set to a second state, the address is pushed onto the program stack using the number of bytes required to contain a longer extended address. This same control bit controls the number of bytes that are popped off the stack upon return from an interrupt subroutine. The state of the control bit is controlled by one or more program instructions, thereby allowing it to assume each state dynamically. This dynamic control of the number of bytes pushed and popped to and from the stack allows for an optimization of stack utilization, and thereby further compatibility with legacy devices and applications.

Abstract: A memory access architecture and technique employs multiple independent buffers that are configured to store items from memory sequentially. The memory is logically partitioned, and each independent buffer is associated with a corresponding memory partition. The partitioning is cyclically sequential, based on the total number of buffers, K, and the size of the buffers, N. The first N memory locations are allocated to the first partition; the next N memory locations to the second partition; and so on until the Kth partition. The next N memory locations, after the Kth partition, are allocated to the first partition; the next N locations are allocated to the second partition; and so on. When an item is accessed from memory, the buffer corresponding to the item's memory location is loaded from memory, and a prefetch of the next sequential partition commences to load the next buffer.

Abstract: A memory accelerator module buffers program instructions and/or data for high speed access using a deterministic access protocol. The program memory is logically partitioned into ‘stripes’, or ‘cyclically sequential’ partitions, and the memory accelerator module includes a latch that is associated with each partition. When a particular partition is accessed, it is loaded into its corresponding latch, and the instructions in the next sequential partition are automatically pre-fetched into their corresponding latch. In this manner, the performance of a sequential-access process will have a known response, because the pre-fetched instructions from the next partition will be in the latch when the program sequences to these instructions. Previously accessed blocks remain in their corresponding latches until the pre-fetch process ‘cycles around’ and overwrites the contents of each sequentially-accessed latch.

Abstract: A microcontroller with selectable function external pins. Program controllable configuration registers control pin function selection through multiplexers which select between data/address lines and special function unit output lines and which control line drivers which are disabled when the pins are used as input pins.

Abstract: In a computer system, especially a microcontroller, a circuit for protecting hardware-modifiable status bits during a read-modify-write operation, which circuit is relatively simple to implement yet operates well and does not require an undue amount of die real estate to implement. The circuit comprises means for storing information representing whether a hardware-modifiable status bit has been updated during a read-modify-write operation, and means to prevent over-writing of the status bit during the write portion of the read-modify-write cycle when the stored information is detected. The means for storing the information comprises a latch set into its first state whose output indicates whether the first state exists. That output is connected to logic circuitry which blocks the rewrite portion of the read-modify-write operation from changing a hardware-modified bit set during that cycle.

Abstract: An instruction prefetch system for a digital processor, and in particular a microcontroller which includes the prefetch system and instruction queue normally provided as part of the instruction fetch unit, to which is added a second instruction prefetch buffer in the system, preferably in the bus interface unit which serves as the memory interface unit. This added prefetch buffer has storage for only a small number of bytes or words, and operates to supply prefetched instructions to the queue in the instruction fetch unit. However, it operates under the following constraint: it only prefetches within the boundaries of each small block of code memory and stalls when a block boundary is reached until a new address appears. This approach combines some cache and prefetch principles for a limited cost design.

Abstract: A microcontroller which directly drives a memory with low order address bits during a fetch operation. Driving the low order address bits directly while the high order bits are latched during an address/data multiplex on the same pins allows the latch enable cycle to be skipped during sequential fetches. A sequential address detector indicates when the latch enable cycle can be skipped.

Abstract: Page-mode-organized ROMs and associated circuitry are connected only to data and control buses in an information processing system. Addressing and reading of the ROMs are controlled by a processor without connecting the ROMs to an address bus. Selection of a particular ROM and of a particular page in the selected ROM is accomplished by applying a first control signal to the control bus and a first data word to the data bus. This first data word thus serves as the address of the selected page in the selected ROM. Then a particular byte of the selected page is selected by applying a second control signal to the control bus and a second data word to the data bus. This second data word serves as the address of the selected byte. Subsequently, in response to a third control signal, the selected byte is read out of the selected ROM and applied to the data bus.