4coder/non-source/test_data/lots_of_files/fsm.c

321 lines
7.6 KiB
C
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2018-03-16 18:19:11 +00:00
/* FSM for LC */
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#define NUMMEMORY 65536 /* maximum number of words in memory */
#define NUMREGS 8 /* number of machine registers */
#define MAXLINELENGTH 1000
typedef struct stateStruct {
int pc;
int mem[NUMMEMORY];
int reg[NUMREGS];
int memoryAddress;
int memoryData;
int instrReg;
int aluOperand;
int aluResult;
int numMemory;
} stateType;
void printState(stateType *, char *);
void run(stateType);
int memoryAccess(stateType *, int);
int convertNum(int);
int
main(int argc, char *argv[])
{
int i;
char line[MAXLINELENGTH];
stateType state;
FILE *filePtr;
if (argc != 2) {
printf("error: usage: %s <machine-code file>\n", argv[0]);
exit(1);
}
/* initialize memories and registers */
for (i=0; i<NUMMEMORY; i++) {
state.mem[i] = 0;
}
for (i=0; i<NUMREGS; i++) {
state.reg[i] = 0;
}
state.pc=0;
/*
* read machine-code file into instruction/data memory
* (starting at address 0)
*/
filePtr = fopen(argv[1], "r");
if (filePtr == NULL) {
printf("error: can't open file %s\n", argv[1]);
perror("fopen");
exit(1);
}
for (state.numMemory=0; fgets(line, MAXLINELENGTH, filePtr) != NULL;
state.numMemory++) {
if (sscanf(line, "%d", state.mem+state.numMemory) != 1) {
printf("error in reading address %d\n", state.numMemory);
exit(1);
}
printf("memory[%d]=%d\n", state.numMemory, state.mem[state.numMemory]);
}
printf("\n");
/* run never returns */
run(state);
return 0;
}
void
printState_(stateType *statePtr, char *stateName, int showAll)
{
int i;
static int cycle = 0;
printf("\n@@@\nstate %s (cycle %d)\n", stateName, cycle++);
if (showAll){
printf("\tpc %d\n", statePtr->pc);
printf("\tmemory:\n");
for (i=0; i<statePtr->numMemory; i++) {
printf("\t\tmem[ %d ] %d\n", i, statePtr->mem[i]);
}
printf("\tregisters:\n");
for (i=0; i<NUMREGS; i++) {
printf("\t\treg[ %d ] %d\n", i, statePtr->reg[i]);
}
printf("\tinternal registers:\n");
printf("\t\tmemoryAddress %d\n", statePtr->memoryAddress);
printf("\t\tmemoryData %d\n", statePtr->memoryData);
printf("\t\tinstrReg %d\n", statePtr->instrReg);
printf("\t\taluOperand %d\n", statePtr->aluOperand);
printf("\t\taluResult %d\n", statePtr->aluResult);
}
}
#define printState(s,n) printState_(s,n,1)
void
printStateReal(stateType *statePtr, char *stateName)
{
printState_(statePtr, stateName, 1);
}
/*
* Access memory:
* readFlag=1 ==> read from memory
* readFlag=0 ==> write to memory
* Return 1 if the memory operation was successful, otherwise return 0
*/
int
memoryAccess(stateType *statePtr, int readFlag)
{
static int lastAddress = -1;
static int lastReadFlag = 0;
static int lastData = 0;
static int delay = 0;
if (statePtr->memoryAddress < 0 || statePtr->memoryAddress >= NUMMEMORY) {
printf("memory address out of range\n");
exit(1);
}
/*
* If this is a new access, reset the delay clock.
*/
if ( (statePtr->memoryAddress != lastAddress) ||
(readFlag != lastReadFlag) ||
(readFlag == 0 && lastData != statePtr->memoryData) ) {
delay = statePtr->memoryAddress % 3;
lastAddress = statePtr->memoryAddress;
lastReadFlag = readFlag;
lastData = statePtr->memoryData;
}
if (delay == 0) {
/* memory is ready */
if (readFlag) {
statePtr->memoryData = statePtr->mem[statePtr->memoryAddress];
} else {
statePtr->mem[statePtr->memoryAddress] = statePtr->memoryData;
}
return 1;
} else {
/* memory is not ready */
delay--;
return 0;
}
}
int
convertNum(int num)
{
/* convert a 16-bit number into a 32-bit integer */
if (num & (1 << 15) ) {
num -= (1 << 16);
}
return num;
}
#define OP_ADD 0
#define OP_NAND 1
#define OP_LW 2
#define OP_SW 3
#define OP_BEQ 4
#define OP_JALR 5
#define OP_HALT 6
#define OP_NOOP 7
void
run(stateType state)
{
int bus;
fetch:
printState(&state, "fetch");
bus = state.pc;
state.memoryAddress = bus;
state.pc++;
goto fetch2;
fetch2:
printState(&state, "fetch2");
if (memoryAccess(&state, 1)) goto decode1;
goto fetch2;
decode1:
printState(&state, "decode1");
bus = state.memoryData;
state.instrReg = bus;
goto decode2;
decode2:
printState(&state, "decode2");
bus = state.reg[(state.instrReg >> 19) & 7];
state.aluOperand = bus;
if ((state.instrReg>>22) == OP_ADD) goto add1;
if ((state.instrReg>>22) == OP_NAND) goto nand1;
if ((state.instrReg>>22) == OP_LW) goto lw1;
if ((state.instrReg>>22) == OP_SW) goto sw1;
if ((state.instrReg>>22) == OP_BEQ) goto beq1;
if ((state.instrReg>>22) == OP_JALR) goto jalr1;
if ((state.instrReg>>22) == OP_HALT) goto halt;
if ((state.instrReg>>22) == OP_NOOP) goto fetch;
exit(1);
add1:
printState(&state, "add1");
bus = state.reg[(state.instrReg >> 16) & 7];
state.aluResult = state.aluOperand + bus;
goto alu_finish;
nand1:
printState(&state, "nand1");
bus = state.reg[(state.instrReg >> 16) & 7];
state.aluResult = ~(state.aluOperand & bus);
goto alu_finish;
alu_finish:
printState(&state, "alu_finish");
bus = state.aluResult;
state.reg[(state.instrReg) & 7] = bus;
goto fetch;
lw1:
printState(&state, "lw1");
bus = convertNum(state.instrReg & 0xFFFF);
state.aluResult = state.aluOperand + bus;
goto lw2;
lw2:
printState(&state, "lw2");
bus = state.aluResult;
state.memoryAddress = bus;
goto lw3;
lw3:
printState(&state, "lw3");
if (memoryAccess(&state, 1)) goto lw4;
goto lw3;
lw4:
printState(&state, "lw4");
bus = state.memoryData;
state.reg[(state.instrReg >> 16) & 7] = bus;
goto fetch;
sw1:
printState(&state, "sw1");
bus = convertNum(state.instrReg & 0xFFFF);
state.aluResult = state.aluOperand + bus;
goto sw2;
sw2:
printState(&state, "sw2");
bus = state.aluResult;
state.memoryAddress = bus;
goto sw3;
sw3:
printState(&state, "sw3");
bus = state.reg[(state.instrReg >> 16) & 7];
state.memoryData = bus;
goto sw4;
sw4:
printState(&state, "sw4");
if (memoryAccess(&state, 0)) goto fetch;
goto sw4;
beq1:
printState(&state, "beq1");
bus = state.reg[(state.instrReg >> 16) & 7];
state.aluResult = state.aluOperand - bus;
goto beq2;
beq2:
printState(&state, "beq2");
bus = convertNum(state.instrReg & 0xFFFF);
state.aluOperand = bus;
if (state.aluResult == 0) goto beq3;
goto fetch;
beq3:
printState(&state, "beq3");
bus = state.pc;
state.aluResult = state.aluOperand + bus;
goto beq4;
beq4:
printState(&state, "beq4");
bus = state.aluResult;
state.pc = bus;
goto fetch;
jalr1:
printState(&state, "jalr1");
bus = state.pc;
state.reg[(state.instrReg >> 16) & 7] = bus;
goto jalr2;
jalr2:
printState(&state, "jalr2");
bus = state.reg[(state.instrReg >> 19) & 7];
state.pc = bus;
goto fetch;
halt:
printStateReal(&state, "halt");
exit(0);
}