SU503240A1 - Firmware Control - Google Patents

Description

nor, if necessary, conditional branching on the result of the execution of this or previous microcommand, field 5 for indicating the address of the next microcommand. The micro-command code from field 3 and the branch code from field 4 are decrypted by the decoder 6 of the micro-command code and the decoder 7 of the branch code, respectively, and are applied to the control unit 8.

The address of a selectable microcommand is formed in address register 9. When the current command is executed, its code is stored in register 10 of the opcode.

At the end of the sampling of the next processor instruction from the main memory, its operation code is transferred to the operation code register 10 and stored there until the command is executed. The instruction execution firmware is entered by sampling a micro-command that has a zero code in the address field 5, and in field 3 the code by which the control device 8 excites the operation start bar 11, and the output of the OR 12 element is transferring the contents of register 10. the operation code through the second element “AND 13 and the second element“ OR 14 to the senior bits of the register of the 9 address.

The element “NOT 15 in this case blocks the inputs of the first element“ AND 16, transmitting the high-order bits of the address field 5 to the high-order bits of register 9 of the address.

In the lower bits of the register 9, the address through the first element "OR 17 and the third element" and 18 is transmitted to the zero code from the lower bits of the address field 5.

Thus, the processor proceeds to the instruction execution firmware.

When performing a sequence of microcommands in the firmware, the inputs and output of the third element OR 12 have a zero value, and the output of the element NOT is a single value, and the address of the next microcommand is formed by passing the address of the 9 most significant bits of the address field 5 through the first element 16 and the second element “OR 14, and the lower bits of the address floor 5 through the first element“ OR 17 and the third element “AND 18.

The reception of information in the address register 9 is gated by a signal generated by the control unit at the second output.

In the case of a microcommand with a branch in the branch field 4., the corresponding branch code is written down, which, after decryption in the decoder 7, the branch code produces. through the first element "OR 17 and the third element" And 18 is transferred to the lower bits of the address register.

The younger branches of the address bits in the address field 5 must be zero.

value. The higher bits of register 9 addresses in this case are determined by the higher bits of the address field 5.

If it is necessary to enter the general micro subprograms, the address of the first micro subprogram is recorded in the address field 5. In the last microcommand of the microsubprogramme, a branching code is written in the branching field, which excites the spike 19 of the return of the decoder 7 of the branching code, and the address field 5 contains an address other than zero.

At the end of the micro subprogram, the system automatically returns to the fixed cell of the current execution zone.

teams. Then, during the execution of a command, a transition to another firmware can be made, after the execution of which an automatic return to another, fixed cell of the command execution area occurs, determined by the content of the low-order bits of the address field 5.

Consider, for example, coma.ndy multiply with floating point and normalize the result. The following microsubprograms are used to execute this command: micro order subcontractor; micro sub multiplication mantis; microsubroutine normalization of the result.

We write the microinstruction in the form of uiuzus, where ai is the code of microinstructions, az is the branch field; “3 is the address field of the next microcommand.

Let us assume that the excitation of the return region occurs at a fixed value of the field

branch az 1 and the specified multiply instruction has an opcode 57.

Then, in the last microcommand for completing the cycle of fetching a command from the RAM and creating the address for the execution address, the processor enters the firmware for executing the multiply command, starting at address 570.

At the end of the sampling of the operand from the operative memory, a transition is carried out to the micro-program of addition, the last microcommand of which has the form a.

Upon completion of the execution of this micro-command, a transition is made to the cell 571. Then the processor performs some preparatory operations and proceeds to the micro multiplication subprogram of the mantissus, the last micro-command of which has the form ai 12.

At the end of the execution of this microcommand, transition 572 is performed,

in which the microinstruction of the transition to the microsubroutine of the normalization of the result is recorded. The last microcommand of this firmware is ai 13. After the execution of this microcommand is completed, a transition is made to the cell 573.

Then the processor sends the result to the desired

registers and proceeds to execute the next program's fetch firmware.

When using micro subroutine

normalization of results in a team