//----------------------------------------------------------------------------- // Copyright 2007 Jonathan Westhues // // This file is part of LDmicro. // // LDmicro is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // LDmicro is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with LDmicro. If not, see . //------ // // A crunched-down version of the intermediate code (e.g. assigning addresses // to all the variables instead of just working with their names), suitable // for interpretation. // Jonathan Westhues, Aug 2005 //----------------------------------------------------------------------------- #include "linuxUI.h" #include #include #include #include "ldmicro.h" #include "intcode.h" static char Variables[MAX_IO][MAX_NAME_LEN]; static int VariablesCount; static char InternalRelays[MAX_IO][MAX_NAME_LEN]; static int InternalRelaysCount; typedef struct { WORD op; WORD name1; WORD name2; WORD name3; SWORD literal; } BinOp; static BinOp OutProg[MAX_INT_OPS]; static WORD AddrForInternalRelay(char *name) { int i; for(i = 0; i < InternalRelaysCount; i++) { if(strcmp(InternalRelays[i], name)==0) { return i; } } strcpy(InternalRelays[i], name); InternalRelaysCount++; return i; } static WORD AddrForVariable(char *name) { int i; for(i = 0; i < VariablesCount; i++) { if(strcmp(Variables[i], name)==0) { return i; } } strcpy(Variables[i], name); VariablesCount++; return i; } static void Write(FILE *f, BinOp *op) { BYTE *b = (BYTE *)op; int i; for(i = 0; i < sizeof(*op); i++) { fprintf(f, "%02x", b[i]); } fprintf(f, "\n"); } void CompileInterpreted(char *outFile) { FILE *f = fopen(outFile, "w"); if(!f) { Error(_("Couldn't write to '%s'"), outFile); return; } InternalRelaysCount = 0; VariablesCount = 0; fprintf(f, "$$LDcode\n"); int ipc; int outPc; BinOp op; // Convert the if/else structures in the intermediate code to absolute // conditional jumps, to make life a bit easier for the interpreter. #define MAX_IF_NESTING 32 int ifDepth = 0; // PC for the if(...) instruction, which we will complete with the // 'jump to if false' address (which is either the ELSE+1 or the ENDIF+1) int ifOpIf[MAX_IF_NESTING]; // PC for the else instruction, which we will complete with the // 'jump to if reached' address (which is the ENDIF+1) int ifOpElse[MAX_IF_NESTING]; outPc = 0; for(ipc = 0; ipc < IntCodeLen; ipc++) { memset(&op, 0, sizeof(op)); op.op = IntCode[ipc].op; switch(IntCode[ipc].op) { case INT_CLEAR_BIT: case INT_SET_BIT: op.name1 = AddrForInternalRelay(IntCode[ipc].name1); break; case INT_COPY_BIT_TO_BIT: op.name1 = AddrForInternalRelay(IntCode[ipc].name1); op.name2 = AddrForInternalRelay(IntCode[ipc].name2); break; case INT_SET_VARIABLE_TO_LITERAL: op.name1 = AddrForVariable(IntCode[ipc].name1); op.literal = IntCode[ipc].literal; break; case INT_SET_VARIABLE_TO_VARIABLE: op.name1 = AddrForVariable(IntCode[ipc].name1); op.name2 = AddrForVariable(IntCode[ipc].name2); break; case INT_INCREMENT_VARIABLE: op.name1 = AddrForVariable(IntCode[ipc].name1); break; case INT_SET_VARIABLE_ADD: case INT_SET_VARIABLE_SUBTRACT: case INT_SET_VARIABLE_MULTIPLY: case INT_SET_VARIABLE_DIVIDE: op.name1 = AddrForVariable(IntCode[ipc].name1); op.name2 = AddrForVariable(IntCode[ipc].name2); op.name3 = AddrForVariable(IntCode[ipc].name3); break; case INT_IF_BIT_SET: case INT_IF_BIT_CLEAR: op.name1 = AddrForInternalRelay(IntCode[ipc].name1); goto finishIf; case INT_IF_VARIABLE_LES_LITERAL: op.name1 = AddrForVariable(IntCode[ipc].name1); op.literal = IntCode[ipc].literal; goto finishIf; case INT_IF_VARIABLE_EQUALS_VARIABLE: case INT_IF_VARIABLE_GRT_VARIABLE: op.name1 = AddrForVariable(IntCode[ipc].name1); op.name2 = AddrForVariable(IntCode[ipc].name2); goto finishIf; finishIf: ifOpIf[ifDepth] = outPc; ifOpElse[ifDepth] = 0; ifDepth++; // jump target will be filled in later break; case INT_ELSE: ifOpElse[ifDepth-1] = outPc; // jump target will be filled in later break; case INT_END_IF: --ifDepth; if(ifOpElse[ifDepth] == 0) { // There is no else; if should jump straight to the // instruction after this one if the condition is false. OutProg[ifOpIf[ifDepth]].name3 = outPc-1; } else { // There is an else clause; if the if is false then jump // just past the else, and if the else is reached then // jump to the endif. OutProg[ifOpIf[ifDepth]].name3 = ifOpElse[ifDepth]; OutProg[ifOpElse[ifDepth]].name3 = outPc-1; } // But don't generate an instruction for this. continue; case INT_SIMULATE_NODE_STATE: case INT_COMMENT: // Don't care; ignore, and don't generate an instruction. continue; case INT_EEPROM_BUSY_CHECK: case INT_EEPROM_READ: case INT_EEPROM_WRITE: case INT_READ_ADC: case INT_SET_PWM: case INT_UART_SEND: case INT_UART_RECV: default: Error(_("Unsupported op (anything ADC, PWM, UART, EEPROM) for " "interpretable target.")); fclose(f); return; } memcpy(&OutProg[outPc], &op, sizeof(op)); outPc++; } int i; for(i = 0; i < outPc; i++) { Write(f, &OutProg[i]); } memset(&op, 0, sizeof(op)); op.op = INT_END_OF_PROGRAM; Write(f, &op); fprintf(f, "$$bits\n"); for(i = 0; i < InternalRelaysCount; i++) { if(InternalRelays[i][0] != '$') { fprintf(f, "%s,%d\n", InternalRelays[i], i); } } fprintf(f, "$$int16s\n"); for(i = 0; i < VariablesCount; i++) { if(Variables[i][0] != '$') { fprintf(f, "%s,%d\n", Variables[i], i); } } fprintf(f, "$$cycle %d us\n", Prog.cycleTime); fclose(f); char str[MAX_PATH+500]; sprintf(str, _("Compile successful; wrote interpretable code to '%s'.\r\n\r\n" "You probably have to adapt the interpreter to your application. See " "the documentation."), outFile); CompileSuccessfulMessage(str); }