Optimized allocation of multi-pipeline executable and specific pipeline executable instructions to execution pipelines based on criteria

Abstract

A microprocessor with a floating point unit configured to efficiently allocate multi-pipeline executable instructions is disclosed. Multi-pipeline executable instructions are instructions that are not forced to execute in a particular type of execution pipe. For example, junk ops are multi-pipeline executable. A junk op is an instruction that is executed at an early stage of the floating point unit's pipeline (e.g., during register rename), but still passes through an execution pipeline for exception checking. Junk ops are not limited to a particular execution pipeline, but instead may pass through any of the microprocessor's execution pipelines in the floating point unit. Multi-pipeline executable instructions are allocated on a per-clock cycle basis using a number of different criteria. For example, the allocation may vary depending upon the number of multi-pipeline executable instructions received by the floating point unit in a single clock cycle.

Claims

What is claimed is:

1. A method for allocating a plurality of instructions to a plurality of execution pipelines, the method comprising:

receiving the plurality of instructions, wherein one or more of the plurality of instructions are multi-pipeline executable, wherein the remaining instructions are single-pipeline executable, wherein the multi-pipeline executable instructions are capable of being executed by more than one type of execution pipeline, and wherein the single-pipeline executable instructions are executable by only one type of execution pipeline;

allocating each single-pipeline executable instruction to one of the plurality of execution pipelines according to instruction type; and

allocating each multi-pipeline executable instruction to one of the plurality of execution pipelines according to a set of criteria, wherein the set of criteria includes determining whether at least one other multi-pipeline executable instruction is present in the plurality of instructions.

2. The method as recited in claim 1, wherein the set of criteria further includes determining whether at least one other single-pipeline executable instruction must be executed by a particular pipeline that executes instructions that on average occur less frequently than instructions that must be executed by the other execution pipelines.

3. The method as recited in claim 2, wherein the particular pipeline is a store pipeline.

4. The method as recited in claim 1, wherein the criteria further includes allocating the plurality of instructions so that any execution pipelines configured to perform store operations receive on average as many multi-pipeline executable instructions as the remaining execution pipelines combined.

5. The method as recited in claim 1, wherein the criteria further includes determining if there are two or more multi-pipeline executable instructions in the plurality of instructions, and, if so, refraining from allocating the multi-pipeline executable instructions to a particular one of the execution pipelines that executes single-pipeline executable instructions that on average occur more frequently than single-pipeline executable instructions that must be executed by the other execution pipelines.

6. The method as recited in claim 5, wherein the particular pipeline is a store pipe.

7. The method as recited in claim 1, wherein the criteria further includes determining if there are two or more multi-pipeline executable instructions in the plurality of instructions, and, if so, then allocating each multi-pipeline executable instructions to a different execution pipeline to the extent possible.

8. The method as recited in claim 1, wherein the criteria includes allocating instructions to the execution pipelines in substantially inverse proportion to the average number of non-multi-pipeline executable instructions received by each execution pipeline.

9. The method as recited in claim 1, wherein the criteria includes allocating slightly more multi-pipeline executable instructions to the execution pipelines configured to execute multiplication instructions relative to the number of multi-pipe executable instructions allocated to execution pipelines configured to execute addition instructions.

10. A method for allocating a plurality of instructions to a plurality of execution pipelines, wherein the plurality of execution pipelines comprises at least one addition pipeline, at least one multiplication pipeline, and at least one store pipeline, the method comprising:

receiving the plurality of instructions, wherein one or more of the plurality of instructions are junk ops; and

allocating each of the plurality of instructions that are not junk ops according to instruction type; and

allocating each of the plurality of instructions that are junk ops to maximize compliance with at least the following criteria: (i) the one or more store pipelines receive on average as many junk ops as the one or more addition pipelines and one or more multiplication pipelines combined.

11. The method as recited in claim 10, wherein the criteria further includes: (ii) if there are more stores than store pipelines, then no junk ops are sent to store pipelines.

12. The method as recited in claim 11, wherein the criteria further includes: (iii) no execution pipelines receive more than one junk ops per clock cycle.

13. The method as recited in claim 12, wherein the criteria further includes: (iv) the one or more addition pipelines receive more junk ops on average than the multiplication pipelines.

14. A microprocessor comprising:

an instruction cache configured to store integer instructions and floating point instructions; and

a floating point unit configured to receive the floating point instructions from the instruction cache, wherein the floating point unit comprises:

a plurality of execution pipelines; and

a rename unit configured to allocate the floating point instructions received by the floating point unit to the execution pipelines, wherein the floating point instructions include single pipeline executable instructions that are executable by a particular type of execution pipeline and multi-pipeline executable instructions that are executable by more than one particular type of execution pipeline, wherein the rename unit is configured to allocate multi-pipeline executable instructions substantially in accordance with at least the following criteria:

(i) the execution pipelines configured to execute store instructions receive on average as many multi-pipeline executable instructions as the execution pipelines configured to execute add and multiply instructions combined.

15. The method as recited in claim 14, wherein a first number of execution pipelines are configured to execute store instructions, wherein the criteria further include: (ii) if there are more store instructions in a particular clock cycle than the first number, then no multi-pipeline executable instructions are sent to the execution pipelines configured to execute store instructions.

16. The method as recited in claim 14, wherein the criteria further include: (iii) no execution pipelines receive more than one multi-pipeline executable instruction per clock cycle.

17. The method as recited in claim 14, wherein a first number of execution pipelines are configured to execute store instructions, wherein a second number of execution pipelines are configured to execute add instructions, wherein a third number of execution pipelines are configured to execute multiply instructions, wherein the criteria further include: (iv) the pipelines configured to execute add instructions receive more multi-pipeline executable instructions on average than the pipelines configured to execute multiply instructions.

18. A computer system comprising:

a main memory;

a communications device; and

a microprocessor coupled to the main memory and the communications device, wherein the microprocessor comprises:

an instruction cache configured to store floating point instructions and integer instructions; and

a floating point unit coupled to receive the floating point instructions from the instruction cache, wherein the floating point unit comprises:

a plurality of execution pipelines; and

a rename unit configured to allocate the floating point instructions received by the floating point unit to the execution pipelines, wherein the floating point instructions include single pipeline executable instructions that are executable by a particular type of execution pipeline and multi-pipeline executable instructions that are executable by more than one particular type of execution pipeline, wherein the rename unit is configured to allocate multi-pipeline executable instructions substantially in accordance with at least the following criteria:

(i) the execution pipelines configured to execute store instructions receive on average as many multi-pipeline executable instructions as the execution pipelines configured to execute add and multiply instructions combined.

19. The system as recited in claim 18, wherein the criteria further include: (iii) no execution pipelines receive more than one multi-pipeline executable instruction per clock cycle.

20. A computer software program embodied on a computer-readable media, wherein the program comprises a plurality of instructions, wherein the plurality of instructions are configured to:

allocate a plurality of instructions to a plurality of execution pipelines, wherein the plurality of execution pipelines comprises at least one addition pipeline, at least one multiplication pipeline, and at least one store pipeline, wherein the instructions are configured to allocate each of the plurality of instructions that are non-multi-pipeline executable according to instruction type and each of the plurality of instructions that are multi-pipeline executable according to at least the following criteria: (i) the one or more store pipelines receive on average as many multi-pipeline executable instructions as the one or more addition pipelines and one or more multiplication pipelines combined; and (ii) if there are more stores than the number of store pipelines, no multi-pipeline executable instructions are sent to the one or more store pipelines.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to the field of microprocessors and, more particularly, to superscalar floating point units.

2. Description of the Related Art

Most microprocessors must support multiple data types. For example, x86-compatible microprocessors must execute two types of instructions; one set defined to operate on integer data types, and a second set defined to operate on floating point data types. In contrast with integers, floating point numbers have fractional components and are typically represented in exponent-significand format. For example, the values 2.15.times.10.sup.3 and -10.5 are floating point numbers while the numbers -1, 0, and 7 are integers. The term "floating point" is derived from the fact that there is no fixed number of digits before or after the decimal point, i.e., the decimal point can float. Using the same number of bits, the floating point format can represent numbers within a much larger range than integer format. For example, a 32-bit signed integer can represent the integers between -2.sup.31 and 2.sup.31 -1 (using two's complement format). In contrast, a 32-bit ("single precision") floating point number as defined by the Institute of Electrical and Electronic Engineers (IEEE) Standard 754 has a range (in normalized format) from 2.sup.-126 to 2.sup.127.times.(2-2.sup.23) in both positive and negative numbers.

FIG. 1 illustrates an exemplary format for an 8-bit integer 100. As the figure illustrates, negative integers are represented using the two's complement format 106. To negate an integer, all bits are inverted to obtain the one's complement format 102. A constant 104 of one is then added to the least significant bit (LSB).

FIG. 2 shows an exemplary format for a floating point value. Value 110 a 32-bit (single precision) floating point number. Value 110 is represented by a significand 112 (23 bits), a biased exponent 114 (8 bits), and a sign bit 116. The base for the floating point number (2 in this case) is raised to the power of the exponent and multiplied by the significand to arrive at the number represented. In microprocessors, base 2 is most common. The significand comprises a number of bits used to represent the most significant digits of the number. Typically, the significand comprises one bit to the left of the radix point and the remaining bits to the right of the radix point. A number in this form is said to be "normalized". In order to save space, in some formats the bit to the left of the radix point, known as the integer bit, is not explicitly stored. Instead, it is implied in the format of the number.

Floating point values may also be represented in 64-bit (double precision) or 80-bit (extended precision) format. As with the single precision format, a double precision format value is represented by a significand (52 bits), a biased exponent (11 bits), and a sign bit. An extended precision format value is represented by a significand (64 bits), a biased exponent (15 bits), and a sign bit. However, unlike the other formats, the significand in extended precision includes an explicit integer bit. Additional information regarding floating point number formats may be obtained in IEEE Standard 754.

The recent increased demand for graphics-intensive applications (e.g., 3D games and virtual reality programs) has placed greater emphasis on a microprocessor's floating point performance. Given the vast amount of software available for x86 microprocessors, there is particularly high demand for x86-compatible microprocessors having high performance floating point units. Thus, microprocessor designers are continually seeking new ways to improve the floating point performance of x86-compatible microprocessors.

One technique used by microprocessor designers to improve the performance of all floating point instructions is pipelining. In a pipelined microprocessor, the microprocessor begins executing a second instruction before the first has been completed. Thus, several instructions are in the pipeline simultaneously, each at a different processing stage. The pipeline is divided into a number of pipeline stages, and each stage can execute its operation concurrently with the other stages. When a stage completes an operation, it passes the result to the next stage in the pipeline and fetches the next operation from the preceding stage. The final results of each instruction emerge at the end of the pipeline in rapid succession.

Typical pipeline stages in a modem microprocessor include fetching, decoding, address generation, scheduling, execution, and retiring. Fetching entails loading the instruction from the instruction cache. Decoding involves examining the fetched instruction to determine how large it is, whether or not it requires an access to memory to read data for execution, etc. Address generation involves calculating memory addresses for instructions that access memory. Scheduling involves the task of determining which instructions are available to be executed and then conveying those instructions and their associated data to the appropriate execution units. The execution stage actually executes the instructions based on information provided by the earlier stages. After the instruction is executed, the results produced are written back either to an internal register or the system memory during the retire stage.

Yet another technique used to improve performance is out-of-order execution. Out-of-order execution involves reordering the instructions being executed (to the extent allowed by dependencies) so as to keep as many of the microprocessor's floating point execution units as busy as possible. As used herein, a microprocessor may have a number of execution units (also called functional units), each optimized to perform a particular task or set of tasks. For example, one execution unit may be optimized to perform integer addition, while another execution unit may be configured to perform floating point addition.

Another popular technique used to improve floating point performance is parallel execution. Parallel execution allows more than one instruction to be executed per clock cycle. This is accomplished by having multiple execution pipelines. For example, an addition instruction may be executed in an addition execution pipeline at the same time that a multiply instruction is executed in a multiply execution pipeline. Microprocessors and floating point units that support parallel execution and pipelining are often referred to as "superscalar" because they are able to execute more than one instruction per clock cycle.

Another method used by some designers to improve performance and simplify the design of the microprocessor is to logically separate the floating point portions of the microprocessor from the integer portions. In this configuration, the floating point portions of the microprocessor are referred to as a floating point coprocessor or floating point unit (FPU), even though it is typically implemented on the same silicon substrate as the microprocessor. If a floating point instruction is detected by the microprocessor, the instruction is handed off the to floating point coprocessor for execution. The coprocessor then executes the instruction independently from the rest of the microprocessor. Since the floating point coprocessor has its own set of registers, this technique works well for most floating point instructions.

Still another feature implemented in some modern floating point units is register renaming. Register renaming utilizes a set of pointers to indirectly access registers. Turning to FIGS. 3A-B, an example of register renaming is shown. FIG. 3A illustrates one type of register renaming that utilizes a register map 70 that includes a pointer for each register and a top-of-stack pointer 72. For example, when an instruction accesses the top of stack register, the floating point unit reads top-of-stack pointer 72, which points to one of the pointers in the register map. That pointer in turn points to an actual register in register stack 74.

FIG. 3B illustrates one particular advantage of register renaming for register exchange operations such as FXCH. FXCH instructions exchange the contents of a particular register with the contents of the top of stack register. Using register renaming, however, FXCH instructions may be executed by simply swapping pointers. This is typically much faster than the traditional method for performing FXCH instructions which includes the following steps: (i) reading out the contents of the top of stack register, (ii) storing the contents into a temporary register, (iii) copying the contents of the source register into the top of stack register, and then (iv) copying the contents of the temporary storage register into the source register. Swapping pointers in the register map also simplifies the floating point unit's hardware because a small pointer (e.g., 3-bits) may be swapped in lieu of transferring lengthy (e.g., 80-bit) floating point values.

FIG. 4 is a basic diagram illustrating one embodiment of an example microprocessor 98 with a floating point unit 86 that implements pipelining, parallel execution, and register renaming. In this example, instructions are read from memory into instruction cache 80. When the instruction is fetched from instruction cache 80, it is conveyed to alignment unit 82, which aligns the instruction and provides it to decode unit 84 for decoding. At this point, floating point instructions may be separated from integer instructions. Floating point instructions are sent to floating point unit 86, where register renaming is performed by register renaming unit 88. Next, the instructions are stored in scheduler 90. Scheduler 90 is configured to select multiple instructions for execution during each clock cycle. The selected instructions are conveyed to functional pipelines 92-96. As previously noted, having a plurality of execution pipelines allows for parallel execution.

One potential performance problem associated with the floating point unit illustrated in FIG. 4 are so-called "junk ops". Junk ops are instructions that are completed early in the processing pipeline. For example, a floating point register exchange (FXCH) instruction is a junk op because it is actually executed in register rename unit 88. However, most junk ops must nevertheless still pass through one of the execution pipelines to perform exception checking (e.g., stack overflow or underflow). Since each execution pipeline contains hardware to perform exception checking for its corresponding type of instruction, junk ops may be routed to any pipeline for exception checking. Thus, unlike most floating point instructions, junk ops are not limited to a particular execution pipeline. For example, floating point add instructions are typically limited to add pipe 92, while floating point multiply instructions are limited to multiply pipe 94. A junk op, however, may pass through any of pipelines 92-96.

Thus, junk ops are multi-pipeline executable instructions. As used herein, the term "multi-pipeline executable instruction" refers to instructions that are capable of being executed by more than one type of execution pipeline. Floating point load instructions are one example of multi-pipeline executable instructions because they are typically capable of being executed by add pipelines, multiply pipelines, and store pipelines within floating point units. In contrast, single pipeline executable instructions are instructions that are forced to use a particular type of execution pipeline to execute. For example, floating point add instructions (FADD) are typically required to pass through the floating point unit's addition pipeline to execute. Typically they cannot be executed in the floating point unit's multiply pipeline or store pipeline.

In addition to being multi-pipeline executable, another characteristic of junk ops is that they typically have no dependencies on other instructions once they reach scheduler 90. This is because they have already been executed by the time they reach scheduler 90. As a result, scheduler 90 tends to schedule them early with respect to other instructions that have dependencies. This flexibility tends to complicate the control logic within schedule unit 90. Since schedule unit 90 is configured to schedule multiple instructions per clock cycle, the scheduling algorithm must be careful not to block non-junk ops with junk ops. For example, assuming schedule unit 90 has one store instruction and three junk ops available for execution, then schedule unit 90 would ideally schedule the store instruction for execution in the store pipe 96, with the first two junk ops being scheduled to add and multiply pipes 92 and 94. The third junk op may schedule during the next clock cycle. This advantageously prevents the junk ops, which are unconstrained in their scheduling, from blocking the execution of a non-junk op. Thus an intelligent system for junk op pipe selection is needed.

One solution may be to construct a state machine that looks at past mixes of instructions and schedules junk ops for the least used pipeline. However, this solution may require substantial hardware resources to implement. Given the complexity of the floating point unit as a whole and the scarcity of die space, a less space-consuming simplified solution is particularly desirable. More generally, a simplified method for allocating multi-pipeline executable instructions to a plurality of execution pipelines is also desired.

SUMMARY

The problems outlined above may at least in part be solved by a microprocessor having a floating point unit configured to efficiently allocate junk ops to a plurality of execution pipelines. In one embodiment, the floating point unit may comprise at least one addition pipeline, at least one multiplication pipeline, and at least one store pipeline. The floating point unit may advantageously be configured to allocate junk ops according to one or more of the following criteria: (i) the one or more store pipelines receive on average as many junk ops as the one or more addition pipelines and one or more multiplication pipelines combined; (ii) if there are more store instructions than store pipelines, then no junk ops are sent to any of the store pipelines; (iii) no execution pipelines receive more than one junk op per clock cycle; and (iv) the one or more addition pipelines receive more junk ops on average than the multiplication pipelines. Advantageously, in some embodiments the criteria set forth above may be implemented in parallel using simple logic gates.

A method for allocating multi-pipeline executable instructions is also contemplated. In one embodiment the method includes receiving a plurality of instructions in which one or more instructions are multi-pipeline executable and the remaining instructions are single-pipeline executable. As noted above, multi-pipeline executable instructions are capable of being executed by more than one type of execution pipeline, while single-pipeline executable instructions are executable by only one type of execution pipeline. Each single-pipeline executable instruction is allocated to one of the execution pipelines according to the instruction's type (e.g., add instructions to an addition pipeline, and multiply instructions to a multiplication pipeline).

The method may further include one or more of the following: (i) determining whether at least one other multi-pipeline executable instruction is present in the plurality of instructions; and (ii) determining whether at least one other single-pipeline executable instruction must be executed by a particular pipeline (e.g., a store pipeline) that executes instructions that, on average, occur less frequently than instructions that must be executed by the other execution pipelines.

Each multi-pipeline executable instruction may be allocated to one of the remaining pipelines according to a set of criteria. The set of criteria may include one or more of the following: (iii) allocating the plurality of instructions so that any execution pipelines configured to perform store operations receive on average as many multi-pipeline executable instructions as the remaining execution pipelines combined; (iv) determining if there are two or more multi-pipeline executable instructions in the plurality of instructions, and, if so, refraining from allocating the multi-pipeline executable instructions to a particular one of the execution pipelines (e.g., the store pipeline) that executes single-pipeline executable instructions that on average occur more frequently than single-pipeline executable instructions that must be executed by the other execution pipelines.

Additional criteria may include one or more of the following: (v) determining if there are two or more multi-pipeline executable instructions in the plurality of instructions, and, if so, then allocating each multi-pipeline executable instructions to a different execution pipeline to the extent possible; (vi) allocating instructions to the execution pipelines in substantially inverse proportion to the average number of non-multi-pipeline executable instructions received; and (vii) allocating slightly more multi-pipeline executable instructions to the execution pipelines configured to execute multiplication instructions relative to the number of multi-pipe executable instructions allocated to execution pipelines configured to execute addition instructions.

A computer system configured to efficiently allocate multi-pipeline executable instructions is also contemplated. In one embodiment, the computer system may comprise a system memory, a communications device for transmitting and receiving data across a network, and one or more microprocessors coupled to the memory and the communications device. The microprocessors may advantageously be configured as described above.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the accompanying drawings.

FIG. 1 illustrates an exemplary format for an integer.

FIG. 2 shows an exemplary format for a floating point value.

FIGS. 3A and 3B show one embodiment of register renaming.

FIG. 4 is a diagram of one embodiment of a microprocessor with a floating point unit.

FIG. 5 is a block diagram of another embodiment of a microprocessor.

FIG. 6 is a block diagram of one embodiment of the floating point unit from the microprocessor of FIG. 5.

FIG. 7 is a flowchart of one embodiment of a method for junk op pipe selection.

FIG. 8 is one embodiment of a software code segment configured to implement part of the method from FIG. 7.

FIG. 9 is a table showing an example of one embodiment of the pipe selection results that may achieved using the method of FIG. 7.

FIG. 10 is a block diagram of one embodiment of a computer system configured to utilize the microprocessor of FIG. 5.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the drawings and detailed description thereto are not intended to limit the invention to the particular form disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the present invention as defined by the appended claims.

DETAILED DESCRIPTION OF SEVERAL EMBODIMENTS

Example Microprocessor--FIG. 5

Turning now to FIG. 5, a block diagram of one embodiment of a microprocessor 10 is shown. As used herein the term "microprocessor" may refer to x86 compatible microprocessors, other microprocessors (e.g., RISC, VLIW), digital signal processors, micro-controllers, and other embedded and or integrated control and calculation devices. Additional embodiments are possible and contemplated.

This embodiment of microprocessor 10 includes a prefetch/predecode unit 12, a branch prediction unit 14, an instruction cache 16, an instruction alignment unit 18, a plurality of decode units 20A-20C, a plurality of reservation stations 22A-22C, a plurality of functional units 24A-24C, a load/store unit 26, a data cache 28, a register file 30, a reorder buffer 32, an MROM unit 34, and a floating point unit (FPU) 36, which in turn comprises multiplier 50. Before examining in detail one embodiment of FPU 36 that efficiently allocates junk op pipelines, the operation of microprocessor 10 will be briefly discussed. Note that elements referred to herein with a particular reference number followed by a letter may be collectively referred to by the reference number alone. For example, decode units 20A-20C may be collectively referred to as decode units 20.

Prefetch/predecode unit 12 is coupled to receive instructions from a main memory subsystem (not shown), and is further coupled to instruction cache 16 and branch prediction unit 14. Similarly, branch prediction unit 14 is coupled to instruction cache 16. Still further, branch prediction unit 14 is coupled to decode units 20 and functional units 24. Instruction cache 16 is further coupled to MROM unit 34 and instruction alignment unit 18. Instruction alignment unit 18, which comprises an early decode unit (EDU) 44, is in turn coupled to decode units 20. Each decode unit 20A-20C is coupled to load/store unit 26 and to respective reservation stations 22A-22C. Reservation stations 22A-22C are further coupled to respective functional units 24A-24C. Additionally, decode units 20 and reservation stations 22 are coupled to register file 30 and reorder buffer 32. Functional units 24 are coupled to load/store unit 26, register file 30, and reorder buffer 32 as well. Data cache 28 is coupled to load/store unit 26 and to the main memory subsystem. MROM unit 34, which also comprises an early decode unit (EDU) 42, is coupled to decode units 20 and FPU 36. Finally, FPU 36 is coupled to load/store unit 26 and reorder buffer 32.

Instruction cache 16 is a high speed cache memory provided to store instructions. Instructions are fetched from instruction cache 16 and dispatched to decode units 20. In one embodiment, instruction cache 16 is configured to store up to 64 kilobytes of instructions in a 2-way set associative structure having 64-byte lines (a byte comprises 8 binary bits). Instruction cache 16 may additionally employ a way prediction scheme in order to speed access times to the instruction cache. Instead of accessing tags identifying each line of instructions and comparing the tags to the fetch address to select a way, instruction cache 16 may predict the way that is accessed. In this manner, the way is selected prior to accessing the instruction storage. The access time of instruction cache 16 may be similar to a direct-mapped cache. A tag comparison is performed and, if the way prediction is incorrect, the correct instructions are fetched and the incorrect instructions are discarded. It is noted that instruction cache 16 may be implemented in a fully-associative, set-associative, or direct-mapped configuration.

Instructions are fetched from main memory and stored into instruction cache 16 by prefetch/predecode unit 12. Instructions may be prefetched prior to the request thereof in accordance with a prefetch scheme. A variety of prefetch schemes may be employed by prefetch/predecode unit 12. As prefetch/predecode unit 12 transfers instructions from main memory to instruction cache 16, prefetch/predecode unit 12 generates three predecode bits for each byte of the instructions: a start bit, an end bit, and a functional bit. The predecode bits form tags indicative of the boundaries of each instruction. The predecode tags may also convey additional information such as whether a given instruction may be decoded directly by decode units 20 or whether the instruction is executed by invoking a microcode procedure controlled by MROM unit 34, as will be described in greater detail below. Still further, prefetch/predecode unit 12 may be configured to detect branch instructions and to store branch prediction information corresponding to the branch instructions into branch prediction unit 14.

One encoding of the predecode tags for an embodiment of microprocessor 10 employing a variable byte length instruction set will now be described. A variable byte length instruction set is an instruction set in which different instructions may occupy differing numbers of bytes. An exemplary variable byte length instruction set employed by one embodiment of microprocessor 10 is the x86 instruction set.

In the exemplary encoding, if a given byte is the first byte of an instruction, the start bit for that byte is set. If the byte is the last byte of an instruction, the end bit for that byte is set. Instructions which may be directly decoded by decode units 20 are referred to as "fast path" instructions. The remaining x86 instructions are referred to as MROM instructions, according to one embodiment. For fast path instructions, the functional bit is set for each prefix byte included in the instruction, and cleared for other bytes. Alternatively, for MROM instructions, the functional bit is cleared for each prefix byte and set for other bytes. The type of instruction may be determined by examining the functional bit corresponding to the end byte. If that functional bit is clear, the instruction is a fast path instruction. Conversely, if that functional bit is set, the instruction is an MROM instruction. The opcode of an instruction may thereby be located within an instruction which may be directly decoded by decode units 20 as the byte associated with the first clear functional bit in the instruction. For example, a fast path instruction including two prefix bytes, a Mod R/M byte, and an immediate data byte would have start, end, and functional bits as follows:

                  Start bits                 10000
                  End bits                   00001
                  Functional bits              11000

          Sign      Exponent      Significand       Value
            x    00...00.sub.2    0.00...00.sub.2         Zero
            x    11...11.sub.2    1.00...00.sub.2       Infinity
            x    11...11.sub.2    1.1xx...xx.sub.2         QNaN
            x    11...11.sub.2    1.0xx...xx.sub.2         SNaN
            x    00...00.sub.2    0.xx...xx.sub.2       Denormal

• Inventors
  Meier, Stephan G.; Juffa, Norbert; Weber, Frederick D.; Oberman, Stuart F.;
• Assignee
  Advanced Micro Devices, Inc. (Sunnyvale, CA)
• Published
  Apr-9-2002
• Current US Classes:
  712/215
  712/222
  718/104
• Application #
  370789
• International Classes
  G06F 009/38
• Field of Search
  709/104 712/215 712/222
• Examiner
  Kim; Kenneth S.
• Agent
  Conley, Rose & Tayon, PC, Kivlin; B. Noel
• US Patent References:
  5465373
  6144982
  6279101