WO1996025706A1

WO1996025706A1 - Microprocessor circuit with at least one arithmetic unit and one control unit

Info

Publication number: WO1996025706A1
Application number: PCT/DE1996/000164
Authority: WO
Inventors: Klaus Buchenrieder
Original assignee: Siemens Aktiengesellschaft
Priority date: 1995-02-15
Filing date: 1996-02-02
Publication date: 1996-08-22
Also published as: TW305973B

Abstract

The object of microprocessor circuits which have to be suitable for solving different problems is to expand the microprocessor or controller such that the basic logic functions made available by the arithmetic or control unit can be dynamically adapted to a different task definition. In order to achieve this object, a configurable logic unit (KE) which can be programmed according to the additional problems to be solved by the microprocessor circuit is also integrated in the semiconductor component on which the arithmetic unit (RW) and the control unit (CW) are disposed. The programmable logic unit can be provided in the microprocessor circuit adjacent the arithmetic logic unit or in the control unit as a microprogram memory or as a sequencer which applies control commands to the arithmetic logic unit.

Description

description

Microprocessor circuit with at least one arithmetic unit and a control unit

The adaptation of the arithmetic or control unit, or input and output unit of a microprocessor circuit or a controller, to specific tasks has hitherto been achieved in several ways. A distinction is made between methods in which the adaptation is determined statically, i.e. in an initialization phase, or dynamically, i.e. regardless of time is possible at any time.

The static adjustment is carried out using task-oriented command sets. The control or arithmetic unit is already designed for a certain class of problems, e.g. Machine control, signal processing etc., designed accordingly. The instruction sets are usually extensive and not optimized for a specific task, but for an application class.

Static adjustment can also be done with the help of freely loadable micro programs. The microprogram, i.e. the entire contents of the microprogram memory, loaded and then the calculation started. With this method, the structure of the arithmetic unit is not changed.

The dynamic adaptation to a specific task can be carried out using configurable coprocessors. The command set is expanded here by calling external functions via reserved machine commands. The method allows special hardware to be used externally to the processor by transferring operands and operations to accelerate the computing process. The dynamic reconfigurability of the external coprocessor logic provides a high degree of flexibility. The problem underlying the invention is to expand a microprocessor circuit or controller circuit so that the basic functionality provided by the arithmetic or control unit or by the input / output unit can be dynamically adapted to a desired task. This problem is solved according to the features of claim 1.

The invention thus solves the problem of dynamic adaptation or expansion of the basic functionality of a microprocessor circuit or a controller circuit provided by the arithmetic or control unit or by the input / output unit, in that the microprocessor or controller chip in addition to the hard-wired logic and the existing, additional, dynamically reprogrammable memory structures

(Reconfigurable) logic and memory elements can be integrated.

In contrast to the dynamic expansion of a computer core using dynamically reprogrammable logic, the external logic is integrated directly on the processor / controller module.

The one used to adapt the microprocessor circuit or controller circuit to specific tasks

Logic unit can be arranged at various points in the microprocessor circuit or controller circuit or input / output mechanism. Individual locations within the microprocessor circuit for the arrangement of the configurable logic unit can be found in the dependent claims.

The invention is further explained on the basis of exemplary embodiments. 1 shows the basic diagram of a microprocessor circuit in which a configurable logic unit is used, FIG. 2 shows the locations within the microprocessor circuit that are suitable for installing the configurable logic unit,

FIG. 3 shows a second exemplary embodiment for the arrangement of the configurable logic unit within the microprocessor circuit,

Figure 4 shows an embodiment of a configurable logic unit.

The construction of part of a microprocessor circuit, namely the arithmetic unit, results from FIG. The arithmetic unit in normal configuration consists of an arithmetic logic unit ALU, an accumulator AK, a shift register SH, a multiplexer MUX1 and a register block RG1. In normal operation, operands OP1, OP2 are fed to the arithmetic logic unit ALU, linked there and then fed to the accumulator AK. Shift processes can be carried out via the accumulator AK and the shift register SH and the result can be fed back to the ALU via the register block RG1 or can be output as the result ER at the output.

In order to be able to adapt this arithmetic unit to additional tasks, a configurable logic unit KE1 can be inserted into the arithmetic unit. Then, in addition to the linking of the operands OP1, OP2, the ALU enables a link via the configurable logic unit KE1. In order to open this path, some circuit parts have to be inserted, namely a data selector DS and a further multiplexer MUX2. Operand OP2 can either be fed to ALU or logic unit KE1 via data selector DS; the same applies to operand OP1. Either the output of the ALU or the logic unit KE to the accumulator AK can be switched through via the multiplexer MUX2. For example, five elementary commands that can be carried out in the ALU can be available for the arithmetic unit. These commands are further commands that are made possible by the logic unit KE1. The logic unit KE1 is configured accordingly. A configurable logic unit can then be used to execute several new commands directly in logic. This results in a measurable difference in execution time and a significant increase in performance.

The arithmetic unit can be expanded in several ways. As FIG. 2 shows, configurable logic units can be accommodated in the control unit CW and / or in the arithmetic unit RW. In Figure 2, the logic units are again designated KE, a logic unit KE3 can e.g. are provided in the control unit CW, another logic unit KE2 in the arithmetic unit RW. The fully or partially configurable arithmetic unit RW receives the data to be processed from registers RG3 and RG4 at the inputs R and S. The result of the calculation is output at the output F and stored in the accumulator AK. The corresponding linking function was defined in a configuration phase before the calculation. At the same time the control unit CW was set for this new command, e.g. the logic unit KE3, which e.g. is implemented as a microprogram memory. The additional units in the control unit are normally provided there, e.g. RG2 is a state variable register, SL is a jump and branch logic unit and T is the clock for operating the microprocessor circuit.

A further implementation possibility is to additionally add a configurable sequencer KE 4 implemented in hardware to the arithmetic logic unit RW. This additional logic unit KE4 results from FIG. 3. It takes over the control of the

Arithmetic unit. The advantage of this design is that the clock speed of the KE4 seguercer is precisely tailored to the needs of the arithmetic unit RW can be adapted. The clock frequency of the sequencer KE4 can also be designed higher than the other clock rates. Operations of the arithmetic unit can thus be carried out at high speed. In addition, the control unit CW can be easily generated. Since the actual sequencer only has to transfer function calls to the arithmetic unit, this also simplifies the programming of the control unit CW. Ideally, only the corresponding function calls should be saved in the control unit. The microprograms are therefore shorter and the microprogram memory can be designed with considerably less space.

If not only the register blocks, but also additional cache memories, which are also integrated with the microprocessor, are controlled by the configurable logic unit in the arithmetic logic unit, then optimal memory access mechanisms can be implemented for the respective task. This leads to a further increase in performance.

For dynamic adaptation of the basic functionality provided by the input / output plant to a desired task, e.g. an input / output unit or an external bus controller can also be implemented as a reconfigurable logic unit on the chip or semiconductor component. These logic units can then be programmed and used by the user depending on the need and application. There is no need to set up special external logic units.

FIG. 4 shows how a configurable logic unit can be constructed. Such a configurable logic unit can consist of three configurable basic elements, namely a configurable logic block CLB, an input / output block IOB and connection blocks ICB. The function of the logic unit is determined by means of the configurable logic blocks CLB, which are connected by the connection units ICB. be tied, realized. Input / output blocks IOB establish the connection to the surrounding logic. All basic elements are programmed before each operation. Programming is carried out with the aid of information KI, which are applied to configuration lines KL. The configuration lines KL are fed to the individual configurable units CLB, CB and IOB. In this way, with the help of the configurable logic blocks CLB and the connection blocks ICB, functional units can be set that generate the additional functions.

Claims

claims

1. microprocessor circuit with at least one arithmetic unit (RW), one control unit (CW), which are designed for a predetermined set of basic functions,

- In which a configurable logic unit (KE) is additionally integrated on a semiconductor module together with the arithmetic unit and the control unit, by means of which an additional number of functions can be implemented in an adjustable manner.

2. Microprocessor circuit according to claim 1,

- The configurable logic unit (KE1) is arranged in parallel to an arithmetic logic unit (ALU) contained in the arithmetic unit, - In either the arithmetic logic unit (ALU) or the logic unit (KE1) via a data selector (DS ) the operands can be supplied, and either the output of the arithmetic unit (ALU) or logic unit (KE1) to an accumulator (AK) can be switched through a multiplexer (MUX2).

3. microprocessor circuit according to claim 2,

- In which a configurable logic unit (KE3) is arranged in the control unit and is designed as a microprogram memory.

4. microprocessor circuit according to claim 1 or 2,

- In which, in addition to the arithmetic unit, the configurable logic block (KE4) is arranged as a sequencer, which applies the control commands from the control unit to the arithmetic unit in a functional manner.

5. Microprocessor circuit according to one of the preceding claims,

- In which, in addition to the arithmetic unit and control unit, a configurable logic block is integrated as an input / output unit. Summary

Microprocessor circuit with at least one arithmetic unit and a control unit

In microprocessor circuits, which must be suitable for different problems, the task is to expand the microprocessor or controller so that the basic functionality provided by the computing or control unit can be dynamically adapted to a changed task position. To solve this problem, a configurable logic unit (KE) is integrated on the semiconductor module on which the arithmetic logic unit (RW) and control unit (CW) is arranged, which logic unit (KE) corresponds to the additional tasks to be solved by the microprocessor circuit is programmable.

This programmable logic unit can be implemented in the microprocessor circuit in addition to the arithmetic logic unit or in the control unit as a microprogram memory or as a sequencer that applies control commands to the arithmetic logic unit. Figure 2