Abstract:
Load and store operations in computer systems are extended to provide for Stream Load and Store and Masked Load and Store. In Stream operations a CPU executes a Stream instruction that indicates by appropriate arguments a first address in memory or a first register in a register file from whence to begin reading data entities, and a first address or register from whence to begin storing the entities, and a number of entities to be read and written. In Masked Load and Masked Store operations stored masks are used to indicate patterns relative to first addresses and registers for loading and storing. Bit-string vector methods are taught for masks.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a divisional of U.S. patent application Ser. No. 09/629,805 entitled METHOD AND APPARATUS FOR IMPROVED COMPUTER LOAD AND STORE OPERATIONS, having a common assignee and common inventors, and filed on Jul. 31, 2000. That application claimed priority from provisional application Ser. No. 60/176,937. In addition, that application is a continuation-in-part of the following U.S. Pat. Nos. 6,477,562, 6,292,888, and 6,389,449, and 7,020,879. 
    
    
     FIELD OF THE INVENTION 
     The present invention is in the field of digital processing and pertains more particularly to apparatus and methods for loading and storing data entities in computer operations. 
     BACKGROUND OF THE INVENTION 
     The present invention is in the area of CPU operations in executing instructions from software. As is known in the art there are many kinds of instruction set architectures (ISA), and certain architectures have become favored in many computer operations. One of those architectures is the well-known MIPS ISA, and the MIPS ISA is used in the present specification in several examples. The invention, however, is not limited to MIPS ISA. 
     One of the necessary operations in computer processes when executing instructions is moving data entities between general-purpose or cache memory and register files in a CPU where the data is readily accessible. When more than one data entity must be loaded or stored before execution can commence or continue, several instructions are needed in a conventional instruction set architecture. In applications that need to access data the present inventors have discovered that it would be desirable to have a single instruction that could load or store data entities that are related in a known pattern, and that a single instruction capable of such operation would significantly improve the speed and efficiency of many computer operations. 
     What is therefore clearly needed is a method and apparatus comprising a single instruction for indicating data entities having a known positional relationship in memory, and for loading or storing a series of such data entities as a result of executing the single instruction. 
     SUMMARY OF THE INVENTION 
     In a preferred embodiment of the present invention, in computer operation, a method for selecting data entities from a memory and writing the data entities to a register file is provided, comprising steps of (a) selecting and reading N entities beginning at a first address; and (b) writing the entities to the register file from a first register in the order of the entities in the memory. In preferred embodiments the steps follow from a Stream Load instruction implemented according to an instruction set architecture (ISA), and the ISA may be MIPS. Also in a preferred embodiment arguments of the Stream Load instruction indicate a beginning memory address from which to read data entities, a first register in the register file at which to begin writing the data entities, and a number indicating the number of data entities to read and write. 
     In another aspect of the invention, in computer operation, a method for selecting data entities from a register file and writing the data entities to a memory is provided, comprising steps of (a) selecting and reading N entities beginning at a first register; and (b) writing the entities to the memory from a first address in the order of the entities in the register file. In preferred embodiments the steps follow from a Stream Store instruction implemented according to an instruction set architecture (ISA), and the ISA is MIPS. Also in preferred embodiments arguments of the Stream Store instruction indicate a beginning register from which to read data entities, an address in memory from which to write the data entities, and a number indicating the number of data entities to read and write. 
     In another aspect of the invention, in computer operations, a method for selecting data entities from a memory and writing the data entities to a register file is provided, comprising steps of (a) consulting a first map of entities to copy relative to a first address; (b) selecting and reading those entities indicated by the map; (c) consulting a second map of positions to write the entities copied from the memory, relative to a first register; and (d) writing the entities to the register file according to the second map. In preferred embodiments the steps follow from a Masked Load instruction implemented according to an instruction set architecture (ISA). Also in preferred embodiments the ISA is MIPS. Also in preferred embodiments arguments of the Masked Load instruction indicate a beginning memory address for positioning a mask, a mask number to be used, and a first register where to begin writing data entities in the register file. In some embodiments the first and second maps are implemented as bit strings, wherein the position of bits in the string indicate the positions for data entities to be selected from memory, and the registers to which data entities are to be written. 
     In yet another aspect of the invention a method for selecting data entities from a register file and writing the data entities to a memory is provided, comprising steps of (a) consulting a first map of entities to read relative to the first register; (b) selecting and reading those entities indicated by the map; (c) consulting a second map of positions to write the entities read from the register file, relative to the first address; and (d) writing the entities to the memory file according to the second map. In preferred embodiments the steps follow from a Masked Store instruction implemented according to an instruction set architecture (ISA), and the ISA may be MIPS. Also in preferred embodiments arguments of the Masked Store instruction indicate a beginning register for positioning a mask, a mask a number to be used, and a first register where to begin writing data entities in the memory. In some embodiments the first and second maps are implemented as bit strings, wherein the position of bits in the string indicate the positions for data entities to be read, and the registers to which data entities are to be written. 
     In yet another embodiment of the invention, for use in computer operations, a Stream Load instruction is provided comprising an indication of the instruction; a first argument indicating a first address in a memory from which to begin reading data entities; a second argument indicating a first register in a register file from which to write the data entities read from the memory; and a third argument indicating a number of data entities to be read and written. 
     In another aspect a Stream Store instruction is provided comprising an indication of the instruction; a first argument indicating a first address in a register file from which to begin reading data entities; a second argument indicating a first address in a memory beginning from which to write the data entities read from the register file; and a third argument indicating a number of data entities to be read and written. 
     In still another aspect a Masked Load instruction is provided comprising an indication of the instruction; a first argument indicating a first address in a memory at which to position a mask to indicate data entities to be read; a second argument indicating a first register in a register file beginning at which to write the data entities read from the memory; and a third argument indicating a mask number to be used to select the data entities to be read and written. 
     In still another aspect a Masked Store instruction is provided comprising an indication of the instruction; a first argument indicating a first register in a register file at which to position a mask to indicate data entities to be read; a second argument indicating a first address in a memory beginning at which to write the data entities read from the register file; and a third argument indicating a mask number to be used to select the data entities to be copied and written. 
     In another aspect a computing system is provided comprising a CPU; a memory; and a register file. The system is characterized in that the CPU, in loading data entities from the memory into the register file, reads a predetermined number of data entities, and writes the data entities into registers of the register file in the same order as in the memory, beginning at a predetermined first register. In preferred embodiments of the system the transferring of data entities from memory into the register file follow from a Stream Load instruction implemented according to an instruction set architecture (ISA) and executed by the CPU, and the ISA may be MIPS. In some embodiments arguments of the Stream Load instruction indicate a beginning memory address from which to read data entities, a first register in the register file from which to write the data entities, and a number indicating the number of data entities to read and write. 
     In yet another aspect a computing system is provided comprising a CPU; a memory; and a register file. The system is characterized in that the CPU, in storing data entities into the memory from the register file, reads a predetermined number of data entities from the register file, and writes the data entities into addressed locations in memory in the same order as in the register file, beginning at a predetermined first address. In preferred embodiments the storing of data entities from the register file into memory follows from a Stream Store instruction implemented according to an instruction set architecture (ISA) and executed by the CPU, and the ISA may be MIPS. Also in preferred embodiments arguments of the Stream Store instruction indicate a first register file from which to read data entities, a first address in memory to which to write the data entities, and a number indicating the number of data entities to read and write. 
     In another aspect a computing system is provided comprising a CPU; a memory; and a register file. This system is characterized in that the CPU, in storing data entities into the memory from the register file, reads a predetermined number of data entities from the register file, and writes the data entities into addressed locations in memory in the same order as in the register file, beginning at a predetermined first address. In preferred embodiments the storing of data entities from the register file into memory follows from a Stream Store instruction implemented according to an instruction set architecture (ISA) and executed by the CPU, and the ISA may be MIPS. In some embodiments arguments of the Stream Store instruction indicate a first register file from which to read data entities, a first address in memory to which to write the data entities, and a number indicating the number of data entities to read and write. 
     In another aspect a computing system is provided comprising a CPU; a memory; and a register file. The CPU, in loading data entities from the memory into the register file reads data entities according to a pre-determined pattern relative to a first address, and writes the data entities into registers of the register file in a pre-determined pattern relative to a first register. In preferred embodiments the loading of data entities from memory into the register file follows from a Masked Load instruction implemented according to an instruction set architecture (ISA) and executed by the CPU, and the ISA may be MIPS. In some embodiments arguments of the Masked Load instruction indicate a beginning memory address from which to read data entities, a first register in the register file beginning at which to write the data entities, and a Mask Number indicating a stored mask to be employed to indicate the relative positions in the memory and register file for reading a writing data entities. Further, the stored masks may be implemented as two bit-string vectors, a first vector indicating which data entities relative to the first address to read, and the second indicating into which registers relative to the first register to write the data entities. 
     In still another aspect a computing system is provided comprising a CPU; a memory; and a register file. In the system the CPU, in storing data entities into the memory from the register file reads data entities from the register file according to a pre-determined pattern, and writes the data entities into addressed locations in memory also according to a pre-determined pattern, beginning at a first address. In preferred embodiments the storing of data entities from the register file into memory follows from a Masked Store instruction implemented according to an instruction set architecture (ISA) and executed by the CPU, and the ISA may be MIPS. In preferred embodiments arguments of the Masked Load instruction indicate a beginning memory address from which to read data entities, a first register in the register file beginning at which to write the data entities, and a Mask Number indicating a stored mask to be employed to indicate the relative positions in the memory and register file for reading and writing the data entities. In some embodiments the stored masks are implemented as two bit-string vectors, a first vector indicating which data entities relative to the first register to read, and the second indicating into which registers relative to the first address to write the data entities. 
     In still another aspect a dynamic multistreaming (DMS) processor is provided, comprising a first plurality k of individual streams, and a second plurality m of masks or mask sets. Individual masks or masks sets of the second plurality m are dedicated to exclusive use of individual ones of the first plurality of k streams for performing Masked Load and/or Masked Store operations. In preferred embodiments individual masks or mask sets are amendable only by the stream to which the individual mask or mask sets are dedicated. 
     In still another aspect a dynamic multistreaming (DMS) processor system is provided, comprising a plurality k of individual streams, a set of masks or mask sets for use in performing Masked Load and Masked Store operations, wherein multiple data entities are loaded or stored as a result of executing a single instruction, and according to the masks, a cache memory, and a system memory. The system is characterized in that the system, in performing a Masked Load or a Masked Store operation transfers data entities directly between the system memory and one or more register files. 
     In embodiments of the invention taught in enabling detail below, for the first time methods and apparatus are provided for load and store operations in computer systems wherein multiple data entities may be read and written according to a single instruction, saving many cycles in execution, and data entities may be selected for reading and writing consecutively, or according to pre-stored position masks. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1A  is a schematic diagram of a memory and a register file illustrating a Stream Load operation according to an embodiment of the present invention. 
         FIG. 1B  is a schematic diagram of a memory and a register file illustrating a Stream Store operation according to an embodiment of the present invention. 
         FIG. 2A  is a schematic diagram of a memory and a register file illustrating a Masked Load operation according to an embodiment of the present invention. 
         FIG. 2B  illustrates an exemplary mask according to an embodiment of the present invention. 
         FIG. 2C  illustrates a set of masks according to an embodiment of the present invention. 
         FIG. 3A  illustrates a mask comprising submasks implemented as vectors according to an embodiment of the invention. 
         FIG. 3B  illustrates a memory and a register file in masked operations according to an embodiment of the invention. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     As was described briefly above, there exist in the technical field of computer operations a number of different instruction set architectures (ISA). An instruction set architecture, generally speaking, is the arrangement of bits and sets of bits in a binary word that a CPU interprets as an instruction. The well-known MIPS ISA is the architecture used by the present Inventors in implementing the present invention in a preferred embodiment, but the invention is certainly not limited to the MIPS ISA. For this reason the specific use of portions of an instruction word as known in MIPS architecture will not be described in detail herein. It is well-known that the MIPS architecture provides unused op-codes that can be used to implement new instructions, and the present inventors, in the MIPS preferred embodiment, have taken advantage of this feature. 
     Because the invention will apply to conceivably any ISA, the inventors will specify and describe the instructions that initiate new and non-obvious functions in the following manner: 
     Instruction A, B, C 
     where A, B, and C are arguments defining parameters for functions to be performed in executing the instruction. 
       FIG. 1A  is a schematic diagram illustrating a memory  11 , which may be any memory, such as a cache memory or a system memory from which a CPU may fetch data, and a register file  15 . Memory  11  has a Word Width, which in a preferred embodiment is 32 bits, and register file  15  similarly has a register width. The word width and the register width are preferably the same, but may differ in different embodiments of the invention. 
     Below the schematic of memory and register file in  FIG. 1  there is a logical structure for a Stream Load instruction according to an embodiment of the present invention. In the instruction structure there is an instruction opcode (for Stream Load), and three arguments, being a first argument @, a second argument “first register, and a third argument “N”. Referring to the diagram, when the CPU executes this instruction, it knows from the instruction opcode what the order of operations is to be, taking words from memory  11  and writing these words into register file  15 . The arguments provide the parameters. 
     In the example shown the CPU will read N consecutive words, beginning at address @ in memory  11 , shown in  FIG. 1A  as words  13  in the shaded area, and will write those N words in the same order to register file  15 , beginning at register “first register” providing in the register file the block of words  17 . 
     In alternative embodiments of the invention, because the width of a word in memory may differ from the width of a register in the register file, words selected from memory may affect more than a single register, or may not fill a register. If the memory word, for example, is twice the register width, one memory word will fill two consecutive registers, and a selected number of memory words will fill twice that number of registers. On the other hand, if a memory word is one-half the register width it will take two memory words to fill a single register. 
       FIG. 1B  is a schematic diagram similar to  FIG. 1A , but depicting a companion Stream Store instruction, wherein the CPU, executing the instruction, will read N consecutive words (words  17 ) from register file  15 , beginning at register “first register”, and will write those N words in the same order to memory  11  beginning at address @ defined in the arguments, providing words  13 . 
     The new instructions defined herein have important application in several instances, one of which is in application of multi-streaming processors to processing packets in network packet routing. These instructions, however, will find many other uses in use of virtually any sort of processor in a wide range of applications. 
     In packet processing, many packets have identical structure, and it is necessary, once a packet is brought into a router and stored in a memory such as memory  11 , to load certain header fields into a register file to be processed according to certain rules. As the structure is known, bytes that comprise the header may be stored in memory consecutively, the arguments of the new Stream Load and Stream Store instructions may be structured to load all of the necessary data for a packet to a register file for processing, and to store registers after processing. It may, of course, be the same or different registers that are stored as the registers that are used in Load. There are similarly many other potential applications for Stream Load and Stream Store, which will improve computer operations in many instances. 
     In an alternative embodiment of the present invention the inventors have determined the functionality of the invention may be significantly enhanced by structuring new commands to load and store multiple words without a limitation that the words be consecutive in either the memory or in the register file. The new commands are named Masked Load and Masked Store respectively. 
       FIG. 2A  is a schematic diagram of memory  11  and register file  15  illustrating an example of Masked Load. Memory  11  in this example is 1 byte wide, and 8 memory words are shown in memory  11 , arbitrarily numbered 0 through 7. Each word has a memory address as is known in the art. Register file  15  in this example is 4 bytes wide, and is shown organized into registers arbitrarily numbered on the left from 0 to 7. Below the schematic is an example of the organization of a Masked Load instruction, having three arguments. A first argument is an address in memory  11 , the second argument is a first register in the register file, and the third argument is now a mask number. 
       FIG. 2B  illustrates a Mask example having two columns, the left-most column for memory byte number, as shown, and the right-most column for relative register number. This is the mask for the Masked Load example of  FIG. 2A . Note that memory byte numbers  0 ,  3 ,  5 , and  7  are listed in the left-most column, and relative register numbers  0 ,  0 ,  2 , and  3  are listed in the right-most column. The mask tells the Masked Load instruction which memory bytes to read, and where to write these bytes into the register file. 
     Referring again to  FIG. 2A , note that relative memory bytes  0 ,  3 ,  5 , and  7  are shaded (each differently). The address (@) argument of the Masked Load instruction tells the CPU where to position the mask in memory, and the mask selects the bytes to read relative to the starting address. Since the register file is four bytes wide, four bytes from memory can be written side-by-side in a single register of the register file. In this example the default is that selected bytes will be written into the register file beginning in the least significant byte of each register, which is, by default, the right-most byte in this example. 
     The mask says that relative memory byte number  0  is to go to relative register number  0 . This is the first register indicated by the second argument of the instruction. Memory byte  0  is thus shown as written to the least significant byte of relative register  0  in the register file. The mask indicates next that relative memory byte  3  is also to be written to relative register  0  of the register file. Since this is the second byte to go to relative register  0 , it is written to the second to the second least significant byte in the indicated register of the register file. Memory byte  5  is written to relative register  2 , and since it is the only byte to go to register  2 , it goes in the 1.s. position. Relative memory byte  7  goes to relative register  3  according to the mask, and this is shown in  FIG. 2A  as well. The cross-hatching has been made common to illustrate the movement of data from the memory to the register file. 
     By default in this example data entities selected from memory are written to registers beginning at the least significant byte until a next entity is to be written to a different register. This is just one example of placement of selected bytes in registers. Any other placement may also be indicated by a mask, and the simple mask shown could have more columns indicating byte placement in registers. Many mask implementations and defaults are possible within the spirit and scope of the invention. 
     Just as illustrated above in the case of the Stream Load and Stream Store operations, the Masked Load operation has a matching Masked Store instruction as well. In the Store case, in the instruction architecture selected bits indicate the Store as opposed to Load operation, and the arguments have the same structure as for the Masked Load. 
     It will be apparent to the skilled artisan that the masks can be of arbitrary number in different embodiments of the invention, and the length of each mask, defining the number and position of bytes to be loaded, can vary in different embodiments as well. In one embodiment of the present invention the masks are useful in the situation discussed briefly above, that of processing data packets in routing machines. In this particular case the masks can be implemented to capture certain patterns of data entities from a memory, such as certain headers of packets for example, in processing data packets for routing. 
     Also in some embodiments of the present invention Masked Load and Masked Store instructions are used in threads (software) used for packet processing using dynamic multi-streaming processors. These processors have plural physical streams, each capable of supporting a separate thread, and each stream typically has a dedicated register file. In this case mask sets can be stored and dedicated to individual streams, or shared by two or more, or all streams. Such dynamic multi-streaming (DMS) processors are described in detail in the priority documents listed in the Cross-Reference to related documents above. 
     In a preferred embodiment masks are programmable, such that mask sets can be exchanged and amended as needed. Masks may be stored in a variety of ways. They may be stored and accessible from system memory for example, or in hidden registers on or off a processor, or in programmable ROM devices. In some embodiments facility is provided wherein masks may be linked, making larger masks, and providing an ability to amend masks without reprogramming. In one embodiment of the invention  32  masks are provided and up to 8 masks may be linked. In some cases masks may be stored in the instruction itself, if the instruction is of sufficient width to afford the bits needed for masking. If the instruction width is, for example, 64 bits, and only 32 bits are needed for the instruction itself, the other 32 bits may be a mask vector. 
     In the matter of programmability, masks may be programmed and/or amended in a variety of ways. Programming can be manual, in the sense of requiring human intervention, or amendable by dynamic action of the processing system using the masks. In the latter case, in application to DMS processors, there may be certain software burden, because, if one stream is using a mask or a set of masks in a load or store operation, it must be guaranteed that no other stream will update that mask or mask set. So in the case of DMS processors it is preferred that masks be dedicated to streams. In such a processor system, having k streams, there might be a mask or a set of masks dedicated to each of the k streams, such that a particular stream can only use and update its own mask or set of masks. 
     In the descriptions above, no particular distinction has been made to the memory source and destination of data entities for a Masked Load or a Masked Store operation. It is well known in the art, however, that state-of-the-art processors operate typically with cache memory rather than directly with system memory only. Cache memory and cache operations are notoriously well-known in the art, and need not be described in detail here. 
     In one embodiment of Masked Load and Store operations used with DMS processors according to the present invention, the masked load/stored could chose to bypass the cache (i.e. the access goes directly to the memory without consulting whether the required data resides in the cache), even if the memory access belongs to a cacheable space. Then, it is up to software to guarantee the coherency of the data. If the data cache is bypassed, the read/write ports to the data cache are freed for other accesses performed by the regular load/stores by other streams. Ports to caches are expensive. 
     In a preferred embodiment of the invention masks (or in some cases parts of masks) are implemented as two vectors, each written and stored as a 32-bit word.  FIG. 3A  is an illustration of vector-masks, and  FIG. 3B  illustrates a memory  17  and a register file (context register)  19  wherein bytes from memory  17  are transferred into file  19  according to the vector-mask of  FIG. 3A . 
     Referring now to  FIG. 3A , in each submask there are two vectors, being a select vector and a register vector. A submask as illustrated in  FIG. 3A  may be a complete mask, and a complete mask may consist of up to eight (in this embodiment) submasks. This is described in more detail below. 
     Referring now to submask  0  in  FIG. 3A , there are ones in bits  0 ,  1 ,  7 ,  12  and  13  in the Select vector. A one in any position in the select vector is to select a relative bit to be transferred from a memory to a register file. Other bits are zero. Of course the opposite could be true. 
     Referring now to  FIG. 3B , memory  17  is organized as 32 bytes wide. In this example the application is packet processing, and the data entities manipulated are bytes from header fields for packets. As described before, the beginning position for selecting data entities is given in the Masked Load instruction as the first argument @ (for address, see  FIG. 2A ). The third argument provides the Mask number, which is, in this case the two-vector submask of  FIG. 3A . The relevant bytes of the packet header stored in memory  17  and indicated as to-be-transferred by submask  0  of  FIG. 3A  are shown in memory  17  of  FIG. 3B  as shaded, each a different shading. This any combination or all of the bytes from the packet header of 32 bytes may be selected for transfer to a register file. 
     The Register vector of submask  0  indicates the relative position within the register file to write the selected bytes. Note there is a one in only one position in the Register vector in this particular example, that at position  12 . The significance of the one in the register vector is to index the register wherein bytes are to be stored in the register file. There may in other examples be more than a single one in the register vector. 
     Referring now to  FIG. 3B , bytes are stored in the register file beginning at a first register (FR). The first register for storage (start loading register) is the second argument of the Masked Load instruction. In other applications and embodiments there may be different defaults for different reasons. The Masked Load instruction in this example begins loading selected bytes from memory  17  into register file  19  at the first register and the default is to load in order from the least significant position, and adjacent, until the register is indexed by the register vector. Another order could well be used in another embodiment. Accordingly bytes  0 ,  1 , and  7  are loaded into the first register from the right (1.s.). The one at position  12  in the Register vector of  FIG. 3A  indexes the register, so bytes  12  and  13  are loaded into the first two positions of register FR+1. As there are no more bytes from memory  17  selected, this is the end of the operation. 
     As described above and illustrated herein, submask  0  is a complete mask. In a preferred embodiment, however, up to eight submasks may be combined to make a mask. Each submask in this embodiment has an end-of-mask bit as indicated in  FIG. 3B . A one in the end-of-mask bit indicates that submask is the last submask to be combined to form the mask for a particular instruction. 
     It is emphasized that the example of vector masks described just above is a single example. Many other masking schemes are possible within the spirit and scope of the invention. For example, selection and placement could be indicated by a single vector wherein a first data entity indicated to be selected beginning at a first address would be copied to a first register, and one or more zeros between data entities to be selected would indicate an index in the register in which following entities are to be placed in the register file. Many such schemes are possible, and a relatively few are indicated by example herein. 
     It will be apparent to the skilled artisan that, just as described above in the case of Stream Load and Store instructions, Masked Store may be accomplished in much the same fashion as the Masked Load instruction described in detail. 
     In the store operations of the example, note that there are bytes of the register file to which data entities are not written. There is a choice of whether to leave these bytes or to clear them. In a preferred embodiment the unused bytes are cleared. 
     It will be apparent to the skilled artisan that there are many variations that may be made in the embodiments of the present invention described above without departing from the spirit and scope of the invention. For example, there are a wide variety of ways that masks may be structured and implemented, and a wide variety of ways that masks may be stored, programmed, exchanged, and amended. There are similarly a variety of ways Masked Load and Store instructions may be defined and implemented, depending on the Instruction Set Architecture used. There are similarly many applications for such unique instructions beyond the packet-processing applications used as examples herein, and the new instructions may be useful with many kinds of processors, including Dynamic Multi-Streaming (DMS) Processors, which are a particular interest of the present inventors. 
     In the matter of DMS processors, the present application is related to four cases teaching aspects of DMS processors and their functioning, all four of which are listed in the Cross-Reference section above, and all four of which are incorporated into the present case by reference. the use of the stream and masked load/store instructions as taught above are especially interesting in DMS processors, since the stream that executes the new instructions in a thread can remain inactive while the masked load/store instruction is being executed in a functional unit. Therefore, other streams can make use of the rest of the resources of the processor. The stream executing the new instructions does not need to sit idle until the masked load/store completes, however. That stream can go on and execute more instructions, as long as the instructions do not depend on the values in the registers affected by the masked load/store instruction in execution. In other words, the stream could execute instructions out-of-order. 
     In addition to the above, there is a wide choice of granularity in different embodiments of the invention. In the example used, bytes are selected, but in other embodiments the granularity may be bits, words, or even blocks of memory. If words are used, there need not be a register vector, if the register is of the same word width. It should further be noted that the Stream Load and Store operations are simply a particular case of the Masked Load and Store operations. 
     Given the broad application of the invention and the broad scope, the invention should be limited only by the claims which follow.