//----------------------------------------------------------------------------- // 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 PIC16... assembler, for our own internal use, plus routines to generate // code from the ladder logic structure, plus routines to generate the // runtime needed to schedule the cycles. // Jonathan Westhues, Oct 2004 //----------------------------------------------------------------------------- #include "linuxUI.h" #include #include #include #include #include "ldmicro.h" #include "intcode.h" // not complete; just what I need typedef enum Pic16OpTag { OP_VACANT, OP_ADDWF, OP_ANDWF, OP_CALL, OP_BSF, OP_BCF, OP_BTFSC, OP_BTFSS, OP_GOTO, OP_CLRF, OP_CLRWDT, OP_COMF, OP_DECF, OP_DECFSZ, OP_INCF, OP_INCFSZ, OP_IORWF, OP_MOVLW, OP_MOVF, OP_MOVWF, OP_NOP, OP_RETFIE, OP_RETURN, OP_RLF, OP_RRF, OP_SUBLW, OP_SUBWF, OP_XORWF, } Pic16Op; #define DEST_F 1 #define DEST_W 0 #define STATUS_RP1 6 #define STATUS_RP0 5 #define STATUS_Z 2 #define STATUS_C 0 typedef struct Pic16InstructionTag { Pic16Op op; DWORD arg1; DWORD arg2; } Pic16Instruction; #define MAX_PROGRAM_LEN 128*1024 static Pic16Instruction PicProg[MAX_PROGRAM_LEN]; static DWORD PicProgWriteP; // Scratch variables, for temporaries static DWORD Scratch0; static DWORD Scratch1; static DWORD Scratch2; static DWORD Scratch3; static DWORD Scratch4; static DWORD Scratch5; static DWORD Scratch6; static DWORD Scratch7; // The extra byte to program, for the EEPROM (because we can only set // up one byte to program at a time, and we will be writing two-byte // variables, in general). static DWORD EepromHighByte; static DWORD EepromHighByteWaitingAddr; static int EepromHighByteWaitingBit; // Subroutines to do multiply/divide static DWORD MultiplyRoutineAddress; static DWORD DivideRoutineAddress; static BOOL MultiplyNeeded; static BOOL DivideNeeded; // For yet unresolved references in jumps static DWORD FwdAddrCount; // As I start to support the paging; it is sometimes necessary to pick // out the high vs. low portions of the address, so that the high portion // goes in PCLATH, and the low portion is just used for the jump. #define FWD_LO(x) ((x) | 0x20000000) #define FWD_HI(x) ((x) | 0x40000000) // Some useful registers, which I think are mostly in the same place on // all the PIC16... devices. #define REG_INDF 0x00 #define REG_STATUS 0x03 #define REG_FSR 0x04 #define REG_PCLATH 0x0a #define REG_INTCON 0x0b #define REG_PIR1 0x0c #define REG_PIE1 0x8c #define REG_TMR1L 0x0e #define REG_TMR1H 0x0f #define REG_T1CON 0x10 #define REG_CCPR1L 0x15 #define REG_CCPR1H 0x16 #define REG_CCP1CON 0x17 #define REG_CMCON 0x1f #define REG_TXSTA 0x98 #define REG_RCSTA 0x18 #define REG_SPBRG 0x99 #define REG_TXREG 0x19 #define REG_RCREG 0x1a #define REG_ADRESH 0x1e #define REG_ADRESL 0x9e #define REG_ADCON0 0x1f #define REG_ADCON1 0x9f #define REG_T2CON 0x12 #define REG_CCPR2L 0x1b #define REG_CCP2CON 0x1d #define REG_PR2 0x92 // These move around from device to device. static DWORD REG_EECON1; static DWORD REG_EECON2; static DWORD REG_EEDATA; static DWORD REG_EEADR; static DWORD REG_ANSEL; static DWORD REG_ANSELH; static int IntPc; static void CompileFromIntermediate(BOOL topLevel); //----------------------------------------------------------------------------- // A convenience function, whether we are using a particular MCU. //----------------------------------------------------------------------------- static BOOL McuIs(char *str) { return strcmp(Prog.mcu->mcuName, str) == 0; } //----------------------------------------------------------------------------- // Wipe the program and set the write pointer back to the beginning. //----------------------------------------------------------------------------- static void WipeMemory(void) { memset(PicProg, 0, sizeof(PicProg)); PicProgWriteP = 0; } //----------------------------------------------------------------------------- // Store an instruction at the next spot in program memory. Error condition // if this spot is already filled. We don't actually assemble to binary yet; // there may be references to resolve. //----------------------------------------------------------------------------- static void Instruction(Pic16Op op, DWORD arg1, DWORD arg2) { if(PicProg[PicProgWriteP].op != OP_VACANT) oops(); PicProg[PicProgWriteP].op = op; PicProg[PicProgWriteP].arg1 = arg1; PicProg[PicProgWriteP].arg2 = arg2; PicProgWriteP++; } //----------------------------------------------------------------------------- // Allocate a unique descriptor for a forward reference. Later that forward // reference gets assigned to an absolute address, and we can go back and // fix up the reference. //----------------------------------------------------------------------------- static DWORD AllocFwdAddr(void) { FwdAddrCount++; return 0x80000000 | FwdAddrCount; } //----------------------------------------------------------------------------- // Go back and fix up the program given that the provided forward address // corresponds to the next instruction to be assembled. //----------------------------------------------------------------------------- static void FwdAddrIsNow(DWORD addr) { if(!(addr & 0x80000000)) oops(); BOOL seen = FALSE; DWORD i; for(i = 0; i < PicProgWriteP; i++) { if(PicProg[i].arg1 == addr) { // Insist that they be in the same page, but otherwise assume // that PCLATH has already been set up appropriately. if((i >> 11) != (PicProgWriteP >> 11)) { Error(_("Internal error relating to PIC paging; make program " "smaller or reshuffle it.")); CompileError(); } PicProg[i].arg1 = PicProgWriteP; seen = TRUE; } else if(PicProg[i].arg1 == FWD_LO(addr)) { PicProg[i].arg1 = (PicProgWriteP & 0x7ff); seen = TRUE; } else if(PicProg[i].arg1 == FWD_HI(addr)) { PicProg[i].arg1 = (PicProgWriteP >> 8); } } if(!seen) oops(); } //----------------------------------------------------------------------------- // Given an opcode and its operands, assemble the 14-bit instruction for the // PIC. Check that the operands do not have more bits set than is meaningful; // it is an internal error if they do. //----------------------------------------------------------------------------- static DWORD Assemble(Pic16Op op, DWORD arg1, DWORD arg2) { #define CHECK(v, bits) if((v) != ((v) & ((1 << (bits))-1))) oops() switch(op) { case OP_ADDWF: CHECK(arg2, 1); CHECK(arg1, 7); return (7 << 8) | (arg2 << 7) | arg1; case OP_ANDWF: CHECK(arg2, 1); CHECK(arg1, 7); return (5 << 8) | (arg2 << 7) | arg1; case OP_BSF: CHECK(arg2, 3); CHECK(arg1, 7); return (5 << 10) | (arg2 << 7) | arg1; case OP_BCF: CHECK(arg2, 3); CHECK(arg1, 7); return (4 << 10) | (arg2 << 7) | arg1; case OP_BTFSC: CHECK(arg2, 3); CHECK(arg1, 7); return (6 << 10) | (arg2 << 7) | arg1; case OP_BTFSS: CHECK(arg2, 3); CHECK(arg1, 7); return (7 << 10) | (arg2 << 7) | arg1; case OP_CLRF: CHECK(arg1, 7); CHECK(arg2, 0); return (3 << 7) | arg1; case OP_CLRWDT: return 0x0064; case OP_COMF: CHECK(arg2, 1); CHECK(arg1, 7); return (9 << 8) | (arg2 << 7) | arg1; case OP_DECF: CHECK(arg1, 7); CHECK(arg2, 1); return (3 << 8) | (arg2 << 7) | arg1; case OP_DECFSZ: CHECK(arg1, 7); CHECK(arg2, 1); return (11 << 8) | (arg2 << 7) | arg1; case OP_GOTO: // Very special case: we will assume that the PCLATH stuff has // been taken care of already. arg1 &= 0x7ff; CHECK(arg1, 11); CHECK(arg2, 0); return (5 << 11) | arg1; case OP_CALL: CHECK(arg1, 11); CHECK(arg2, 0); return (4 << 11) | arg1; case OP_INCF: CHECK(arg1, 7); CHECK(arg2, 1); return (10 << 8) | (arg2 << 7) | arg1; case OP_INCFSZ: CHECK(arg1, 7); CHECK(arg2, 1); return (15 << 8) | (arg2 << 7) | arg1; case OP_IORWF: CHECK(arg2, 1); CHECK(arg1, 7); return (4 << 8) | (arg2 << 7) | arg1; case OP_MOVLW: CHECK(arg1, 8); CHECK(arg2, 0); return (3 << 12) | arg1; case OP_MOVF: CHECK(arg1, 7); CHECK(arg2, 1); return (8 << 8) | (arg2 << 7) | arg1; case OP_MOVWF: CHECK(arg1, 7); CHECK(arg2, 0); return (1 << 7) | arg1; case OP_NOP: return 0x0000; case OP_RETURN: return 0x0008; case OP_RETFIE: return 0x0009; case OP_RLF: CHECK(arg1, 7); CHECK(arg2, 1); return (13 << 8) | (arg2 << 7) | arg1; case OP_RRF: CHECK(arg1, 7); CHECK(arg2, 1); return (12 << 8) | (arg2 << 7) | arg1; case OP_SUBLW: CHECK(arg1, 8); CHECK(arg2, 0); return (15 << 9) | arg1; case OP_SUBWF: CHECK(arg1, 7); CHECK(arg2, 1); return (2 << 8) | (arg2 << 7) | arg1; case OP_XORWF: CHECK(arg1, 7); CHECK(arg2, 1); return (6 << 8) | (arg2 << 7) | arg1; default: oops(); break; } } //----------------------------------------------------------------------------- // Write an intel IHEX format description of the program assembled so far. // This is where we actually do the assembly to binary format. //----------------------------------------------------------------------------- static void WriteHexFile(FILE *f) { BYTE soFar[16]; int soFarCount = 0; DWORD soFarStart = 0; // always start from address 0 fprintf(f, ":020000040000FA\n"); DWORD i; for(i = 0; i < PicProgWriteP; i++) { DWORD w = Assemble(PicProg[i].op, PicProg[i].arg1, PicProg[i].arg2); if(soFarCount == 0) soFarStart = i; soFar[soFarCount++] = (BYTE)(w & 0xff); soFar[soFarCount++] = (BYTE)(w >> 8); if(soFarCount >= 0x10 || i == (PicProgWriteP-1)) { StartIhex(f); WriteIhex(f, soFarCount); WriteIhex(f, (BYTE)((soFarStart*2) >> 8)); WriteIhex(f, (BYTE)((soFarStart*2) & 0xff)); WriteIhex(f, 0x00); int j; for(j = 0; j < soFarCount; j++) { WriteIhex(f, soFar[j]); } FinishIhex(f); soFarCount = 0; } } StartIhex(f); // Configuration words start at address 0x2007 in program memory; and the // hex file addresses are by bytes, not words, so we start at 0x400e. // There may be either 16 or 32 bits of conf word, depending on the part. if(McuIs("Microchip PIC16F887 40-PDIP") || McuIs("Microchip PIC16F886 28-PDIP or 28-SOIC")) { WriteIhex(f, 0x04); WriteIhex(f, 0x40); WriteIhex(f, 0x0E); WriteIhex(f, 0x00); WriteIhex(f, (Prog.mcu->configurationWord >> 0) & 0xff); WriteIhex(f, (Prog.mcu->configurationWord >> 8) & 0xff); WriteIhex(f, (Prog.mcu->configurationWord >> 16) & 0xff); WriteIhex(f, (Prog.mcu->configurationWord >> 24) & 0xff); } else { if(Prog.mcu->configurationWord & 0xffff0000) oops(); WriteIhex(f, 0x02); WriteIhex(f, 0x40); WriteIhex(f, 0x0E); WriteIhex(f, 0x00); WriteIhex(f, (Prog.mcu->configurationWord >> 0) & 0xff); WriteIhex(f, (Prog.mcu->configurationWord >> 8) & 0xff); } FinishIhex(f); // end of file record fprintf(f, ":00000001FF\n"); } //----------------------------------------------------------------------------- // Generate code to write an 8-bit value to a particular register. Takes care // of the bank switching if necessary; assumes that code is called in bank // 0. //----------------------------------------------------------------------------- static void WriteRegister(DWORD reg, BYTE val) { if(reg & 0x080) Instruction(OP_BSF, REG_STATUS, STATUS_RP0); if(reg & 0x100) Instruction(OP_BSF, REG_STATUS, STATUS_RP1); Instruction(OP_MOVLW, val, 0); Instruction(OP_MOVWF, (reg & 0x7f), 0); if(reg & 0x080) Instruction(OP_BCF, REG_STATUS, STATUS_RP0); if(reg & 0x100) Instruction(OP_BCF, REG_STATUS, STATUS_RP1); } //----------------------------------------------------------------------------- // Call a subroutine, that might be in an arbitrary page, and then put // PCLATH back where we want it. //----------------------------------------------------------------------------- static void CallWithPclath(DWORD addr) { // Set up PCLATH for the jump, and then do it. Instruction(OP_MOVLW, FWD_HI(addr), 0); Instruction(OP_MOVWF, REG_PCLATH, 0); Instruction(OP_CALL, FWD_LO(addr), 0); // Restore PCLATH to something appropriate for our page. (We have // already made fairly sure that we will never try to compile across // a page boundary.) Instruction(OP_MOVLW, (PicProgWriteP >> 8), 0); Instruction(OP_MOVWF, REG_PCLATH, 0); } // Note that all of these are single instructions on the PIC; this is not the // case for their equivalents on the AVR! #define SetBit(reg, b) Instruction(OP_BSF, reg, b) #define ClearBit(reg, b) Instruction(OP_BCF, reg, b) #define IfBitClear(reg, b) Instruction(OP_BTFSS, reg, b) #define IfBitSet(reg, b) Instruction(OP_BTFSC, reg, b) static void CopyBit(DWORD addrDest, int bitDest, DWORD addrSrc, int bitSrc) { IfBitSet(addrSrc, bitSrc); SetBit(addrDest, bitDest); IfBitClear(addrSrc, bitSrc); ClearBit(addrDest, bitDest); } //----------------------------------------------------------------------------- // Handle an IF statement. Flow continues to the first instruction generated // by this function if the condition is true, else it jumps to the given // address (which is an FwdAddress, so not yet assigned). Called with IntPc // on the IF statement, returns with IntPc on the END IF. //----------------------------------------------------------------------------- static void CompileIfBody(DWORD condFalse) { IntPc++; CompileFromIntermediate(FALSE); if(IntCode[IntPc].op == INT_ELSE) { IntPc++; DWORD endBlock = AllocFwdAddr(); Instruction(OP_GOTO, endBlock, 0); FwdAddrIsNow(condFalse); CompileFromIntermediate(FALSE); FwdAddrIsNow(endBlock); } else { FwdAddrIsNow(condFalse); } if(IntCode[IntPc].op != INT_END_IF) oops(); } //----------------------------------------------------------------------------- // Compile the intermediate code to PIC16 native code. //----------------------------------------------------------------------------- static void CompileFromIntermediate(BOOL topLevel) { DWORD addr, addr2; int bit, bit2; DWORD addrl, addrh; DWORD addrl2, addrh2; DWORD addrl3, addrh3; // Keep track of which 2k section we are using. When it looks like we // are about to run out, fill with nops and move on to the next one. DWORD section = 0; for(; IntPc < IntCodeLen; IntPc++) { // Try for a margin of about 400 words, which is a little bit // wasteful but considering that the formatted output commands // are huge, probably necessary. Of course if we are in our // last section then it is silly to do that, either we make it // or we're screwed... if(topLevel && (((PicProgWriteP + 400) >> 11) != section) && ((PicProgWriteP + 400) < Prog.mcu->flashWords)) { // Jump to the beginning of the next section Instruction(OP_MOVLW, (PicProgWriteP >> 8) + (1<<3), 0); Instruction(OP_MOVWF, REG_PCLATH, 0); Instruction(OP_GOTO, 0, 0); // Then, just burn the last of this section with NOPs. while((PicProgWriteP >> 11) == section) { Instruction(OP_MOVLW, 0xab, 0); } section = (PicProgWriteP >> 11); // And now PCLATH is set up, so everything in our new section // should just work } IntOp *a = &IntCode[IntPc]; switch(a->op) { case INT_SET_BIT: MemForSingleBit(a->name1, FALSE, &addr, &bit); SetBit(addr, bit); break; case INT_CLEAR_BIT: MemForSingleBit(a->name1, FALSE, &addr, &bit); ClearBit(addr, bit); break; case INT_COPY_BIT_TO_BIT: MemForSingleBit(a->name1, FALSE, &addr, &bit); MemForSingleBit(a->name2, FALSE, &addr2, &bit2); CopyBit(addr, bit, addr2, bit2); break; case INT_SET_VARIABLE_TO_LITERAL: MemForVariable(a->name1, &addrl, &addrh); WriteRegister(addrl, a->literal & 0xff); WriteRegister(addrh, a->literal >> 8); break; case INT_INCREMENT_VARIABLE: { MemForVariable(a->name1, &addrl, &addrh); DWORD noCarry = AllocFwdAddr(); Instruction(OP_INCFSZ, addrl, DEST_F); Instruction(OP_GOTO, noCarry, 0); Instruction(OP_INCF, addrh, DEST_F); FwdAddrIsNow(noCarry); break; } case INT_IF_BIT_SET: { DWORD condFalse = AllocFwdAddr(); MemForSingleBit(a->name1, TRUE, &addr, &bit); IfBitClear(addr, bit); Instruction(OP_GOTO, condFalse, 0); CompileIfBody(condFalse); break; } case INT_IF_BIT_CLEAR: { DWORD condFalse = AllocFwdAddr(); MemForSingleBit(a->name1, TRUE, &addr, &bit); IfBitSet(addr, bit); Instruction(OP_GOTO, condFalse, 0); CompileIfBody(condFalse); break; } case INT_IF_VARIABLE_LES_LITERAL: { DWORD notTrue = AllocFwdAddr(); DWORD isTrue = AllocFwdAddr(); DWORD lsbDecides = AllocFwdAddr(); // V = Rd7*(Rr7')*(R7') + (Rd7')*Rr7*R7 ; but only one of the // product terms can be true, and we know which at compile // time BYTE litH = (a->literal >> 8); BYTE litL = (a->literal & 0xff); MemForVariable(a->name1, &addrl, &addrh); // var - lit Instruction(OP_MOVLW, litH, 0); Instruction(OP_SUBWF, addrh, DEST_W); IfBitSet(REG_STATUS, STATUS_Z); Instruction(OP_GOTO, lsbDecides, 0); Instruction(OP_MOVWF, Scratch0, 0); if(litH & 0x80) { Instruction(OP_COMF, addrh, DEST_W); Instruction(OP_ANDWF, Scratch0, DEST_W); Instruction(OP_XORWF, Scratch0, DEST_F); } else { Instruction(OP_COMF, Scratch0, DEST_W); Instruction(OP_ANDWF, addrh, DEST_W); Instruction(OP_XORWF, Scratch0, DEST_F); } IfBitSet(Scratch0, 7); // var - lit < 0, var < lit Instruction(OP_GOTO, isTrue, 0); Instruction(OP_GOTO, notTrue, 0); FwdAddrIsNow(lsbDecides); // var - lit < 0 // var < lit Instruction(OP_MOVLW, litL, 0); Instruction(OP_SUBWF, addrl, DEST_W); IfBitClear(REG_STATUS, STATUS_C); Instruction(OP_GOTO, isTrue, 0); Instruction(OP_GOTO, notTrue, 0); FwdAddrIsNow(isTrue); CompileIfBody(notTrue); break; } case INT_IF_VARIABLE_EQUALS_VARIABLE: { DWORD notEqual = AllocFwdAddr(); MemForVariable(a->name1, &addrl, &addrh); MemForVariable(a->name2, &addrl2, &addrh2); Instruction(OP_MOVF, addrl, DEST_W); Instruction(OP_SUBWF, addrl2, DEST_W); IfBitClear(REG_STATUS, STATUS_Z); Instruction(OP_GOTO, notEqual, 0); Instruction(OP_MOVF, addrh, DEST_W); Instruction(OP_SUBWF, addrh2, DEST_W); IfBitClear(REG_STATUS, STATUS_Z); Instruction(OP_GOTO, notEqual, 0); CompileIfBody(notEqual); break; } case INT_IF_VARIABLE_GRT_VARIABLE: { DWORD notTrue = AllocFwdAddr(); DWORD isTrue = AllocFwdAddr(); DWORD lsbDecides = AllocFwdAddr(); MemForVariable(a->name1, &addrl, &addrh); MemForVariable(a->name2, &addrl2, &addrh2); // first, a signed comparison of the high octets, which is // a huge pain on the PIC16 DWORD iu = addrh2, ju = addrh; DWORD signa = Scratch0; DWORD signb = Scratch1; Instruction(OP_COMF, ju, DEST_W); Instruction(OP_MOVWF, signb, 0); Instruction(OP_ANDWF, iu, DEST_W); Instruction(OP_MOVWF, signa, 0); Instruction(OP_MOVF, iu, DEST_W); Instruction(OP_IORWF, signb, DEST_F); Instruction(OP_COMF, signb, DEST_F); Instruction(OP_MOVF, ju, DEST_W); Instruction(OP_SUBWF, iu, DEST_W); IfBitSet(REG_STATUS, STATUS_Z); Instruction(OP_GOTO, lsbDecides, 0); Instruction(OP_ANDWF, signb, DEST_F); Instruction(OP_MOVWF, Scratch2, 0); Instruction(OP_COMF, Scratch2, DEST_W); Instruction(OP_ANDWF, signa, DEST_W); Instruction(OP_IORWF, signb, DEST_W); Instruction(OP_XORWF, Scratch2, DEST_F); IfBitSet(Scratch2, 7); Instruction(OP_GOTO, isTrue, 0); Instruction(OP_GOTO, notTrue, 0); FwdAddrIsNow(lsbDecides); Instruction(OP_MOVF, addrl, DEST_W); Instruction(OP_SUBWF, addrl2, DEST_W); IfBitClear(REG_STATUS, STATUS_C); Instruction(OP_GOTO, isTrue, 0); Instruction(OP_GOTO, notTrue, 0); FwdAddrIsNow(isTrue); CompileIfBody(notTrue); break; } case INT_SET_VARIABLE_TO_VARIABLE: MemForVariable(a->name1, &addrl, &addrh); MemForVariable(a->name2, &addrl2, &addrh2); Instruction(OP_MOVF, addrl2, DEST_W); Instruction(OP_MOVWF, addrl, 0); Instruction(OP_MOVF, addrh2, DEST_W); Instruction(OP_MOVWF, addrh, 0); break; // The add and subtract routines must be written to return correct // results if the destination and one of the operands happen to // be the same registers (e.g. for B = A - B). case INT_SET_VARIABLE_ADD: MemForVariable(a->name1, &addrl, &addrh); MemForVariable(a->name2, &addrl2, &addrh2); MemForVariable(a->name3, &addrl3, &addrh3); Instruction(OP_MOVF, addrl2, DEST_W); Instruction(OP_ADDWF, addrl3, DEST_W); Instruction(OP_MOVWF, addrl, 0); ClearBit(Scratch0, 0); IfBitSet(REG_STATUS, STATUS_C); SetBit(Scratch0, 0); Instruction(OP_MOVF, addrh2, DEST_W); Instruction(OP_ADDWF, addrh3, DEST_W); Instruction(OP_MOVWF, addrh, 0); IfBitSet(Scratch0, 0); Instruction(OP_INCF, addrh, DEST_F); break; case INT_SET_VARIABLE_SUBTRACT: MemForVariable(a->name1, &addrl, &addrh); MemForVariable(a->name2, &addrl2, &addrh2); MemForVariable(a->name3, &addrl3, &addrh3); Instruction(OP_MOVF, addrl3, DEST_W); Instruction(OP_SUBWF, addrl2, DEST_W); Instruction(OP_MOVWF, addrl, 0); ClearBit(Scratch0, 0); IfBitSet(REG_STATUS, STATUS_C); SetBit(Scratch0, 0); Instruction(OP_MOVF, addrh3, DEST_W); Instruction(OP_SUBWF, addrh2, DEST_W); Instruction(OP_MOVWF, addrh, 0); IfBitClear(Scratch0, 0); // bit is carry / (not borrow) Instruction(OP_DECF, addrh, DEST_F); break; case INT_SET_VARIABLE_MULTIPLY: MultiplyNeeded = TRUE; MemForVariable(a->name1, &addrl, &addrh); MemForVariable(a->name2, &addrl2, &addrh2); MemForVariable(a->name3, &addrl3, &addrh3); Instruction(OP_MOVF, addrl2, DEST_W); Instruction(OP_MOVWF, Scratch0, 0); Instruction(OP_MOVF, addrh2, DEST_W); Instruction(OP_MOVWF, Scratch1, 0); Instruction(OP_MOVF, addrl3, DEST_W); Instruction(OP_MOVWF, Scratch2, 0); Instruction(OP_MOVF, addrh3, DEST_W); Instruction(OP_MOVWF, Scratch3, 0); CallWithPclath(MultiplyRoutineAddress); Instruction(OP_MOVF, Scratch2, DEST_W); Instruction(OP_MOVWF, addrl, 0); Instruction(OP_MOVF, Scratch3, DEST_W); Instruction(OP_MOVWF, addrh, 0); break; case INT_SET_VARIABLE_DIVIDE: DivideNeeded = TRUE; MemForVariable(a->name1, &addrl, &addrh); MemForVariable(a->name2, &addrl2, &addrh2); MemForVariable(a->name3, &addrl3, &addrh3); Instruction(OP_MOVF, addrl2, DEST_W); Instruction(OP_MOVWF, Scratch0, 0); Instruction(OP_MOVF, addrh2, DEST_W); Instruction(OP_MOVWF, Scratch1, 0); Instruction(OP_MOVF, addrl3, DEST_W); Instruction(OP_MOVWF, Scratch2, 0); Instruction(OP_MOVF, addrh3, DEST_W); Instruction(OP_MOVWF, Scratch3, 0); CallWithPclath(DivideRoutineAddress); Instruction(OP_MOVF, Scratch0, DEST_W); Instruction(OP_MOVWF, addrl, 0); Instruction(OP_MOVF, Scratch1, DEST_W); Instruction(OP_MOVWF, addrh, 0); break; case INT_UART_SEND: { MemForVariable(a->name1, &addrl, &addrh); MemForSingleBit(a->name2, TRUE, &addr, &bit); DWORD noSend = AllocFwdAddr(); IfBitClear(addr, bit); Instruction(OP_GOTO, noSend, 0); Instruction(OP_MOVF, addrl, DEST_W); Instruction(OP_MOVWF, REG_TXREG, 0); FwdAddrIsNow(noSend); ClearBit(addr, bit); DWORD notBusy = AllocFwdAddr(); Instruction(OP_BSF, REG_STATUS, STATUS_RP0); Instruction(OP_BTFSC, REG_TXSTA ^ 0x80, 1); Instruction(OP_GOTO, notBusy, 0); Instruction(OP_BCF, REG_STATUS, STATUS_RP0); SetBit(addr, bit); FwdAddrIsNow(notBusy); Instruction(OP_BCF, REG_STATUS, STATUS_RP0); break; } case INT_UART_RECV: { MemForVariable(a->name1, &addrl, &addrh); MemForSingleBit(a->name2, TRUE, &addr, &bit); ClearBit(addr, bit); // If RCIF is still clear, then there's nothing to do; in that // case jump to the end, and leave the rung-out clear. DWORD done = AllocFwdAddr(); IfBitClear(REG_PIR1, 5); Instruction(OP_GOTO, done, 0); // RCIF is set, so we have a character. Read it now. Instruction(OP_MOVF, REG_RCREG, DEST_W); Instruction(OP_MOVWF, addrl, 0); Instruction(OP_CLRF, addrh, 0); // and set rung-out true SetBit(addr, bit); // And check for errors; need to reset the UART if yes. DWORD yesError = AllocFwdAddr(); IfBitSet(REG_RCSTA, 1); // overrun error Instruction(OP_GOTO, yesError, 0); IfBitSet(REG_RCSTA, 2); // framing error Instruction(OP_GOTO, yesError, 0); // Neither FERR nor OERR is set, so we're good. Instruction(OP_GOTO, done, 0); FwdAddrIsNow(yesError); // An error did occur, so flush the FIFO. Instruction(OP_MOVF, REG_RCREG, DEST_W); Instruction(OP_MOVF, REG_RCREG, DEST_W); // And clear and then set CREN, to clear the error flags. ClearBit(REG_RCSTA, 4); SetBit(REG_RCSTA, 4); FwdAddrIsNow(done); break; } case INT_SET_PWM: { int target = atoi(a->name2); // So the PWM frequency is given by // target = xtal/(4*prescale*pr2) // xtal/target = 4*prescale*pr2 // and pr2 should be made as large as possible to keep // resolution, so prescale should be as small as possible int pr2; int prescale; for(prescale = 1;;) { int dv = 4*prescale*target; pr2 = (Prog.mcuClock + (dv/2))/dv; if(pr2 < 3) { Error(_("PWM frequency too fast.")); CompileError(); } if(pr2 >= 256) { if(prescale == 1) { prescale = 4; } else if(prescale == 4) { prescale = 16; } else { Error(_("PWM frequency too slow.")); CompileError(); } } else { break; } } // First scale the input variable from percent to timer units, // with a multiply and then a divide. MultiplyNeeded = TRUE; DivideNeeded = TRUE; MemForVariable(a->name1, &addrl, &addrh); Instruction(OP_MOVF, addrl, DEST_W); Instruction(OP_MOVWF, Scratch0, 0); Instruction(OP_CLRF, Scratch1, 0); Instruction(OP_MOVLW, pr2, 0); Instruction(OP_MOVWF, Scratch2, 0); Instruction(OP_CLRF, Scratch3, 0); CallWithPclath(MultiplyRoutineAddress); Instruction(OP_MOVF, Scratch3, DEST_W); Instruction(OP_MOVWF, Scratch1, 0); Instruction(OP_MOVF, Scratch2, DEST_W); Instruction(OP_MOVWF, Scratch0, 0); Instruction(OP_MOVLW, 100, 0); Instruction(OP_MOVWF, Scratch2, 0); Instruction(OP_CLRF, Scratch3, 0); CallWithPclath(DivideRoutineAddress); Instruction(OP_MOVF, Scratch0, DEST_W); Instruction(OP_MOVWF, REG_CCPR2L, 0); // Only need to do the setup stuff once MemForSingleBit("$pwm_init", FALSE, &addr, &bit); DWORD skip = AllocFwdAddr(); IfBitSet(addr, bit); Instruction(OP_GOTO, skip, 0); SetBit(addr, bit); // Set up the CCP2 and TMR2 peripherals. WriteRegister(REG_PR2, (pr2-1)); WriteRegister(REG_CCP2CON, 0x0c); // PWM mode, ignore lsbs BYTE t2con = (1 << 2); // timer 2 on if(prescale == 1) t2con |= 0; else if(prescale == 4) t2con |= 1; else if(prescale == 16) t2con |= 2; else oops(); WriteRegister(REG_T2CON, t2con); FwdAddrIsNow(skip); break; } // A quick helper macro to set the banksel bits correctly; this is necessary // because the EEwhatever registers are all over in the memory maps. #define EE_REG_BANKSEL(r) \ if((r) & 0x80) { \ if(!(m & 0x80)) { \ m |= 0x80; \ Instruction(OP_BSF, REG_STATUS, STATUS_RP0); \ } \ } else { \ if(m & 0x80) { \ m &= ~0x80; \ Instruction(OP_BCF, REG_STATUS, STATUS_RP0); \ } \ } \ if((r) & 0x100) { \ if(!(m & 0x100)) { \ m |= 0x100; \ Instruction(OP_BSF, REG_STATUS, STATUS_RP1); \ } \ } else { \ if(m & 0x100) { \ m &= ~0x100; \ Instruction(OP_BCF, REG_STATUS, STATUS_RP1); \ } \ } case INT_EEPROM_BUSY_CHECK: { DWORD isBusy = AllocFwdAddr(); DWORD done = AllocFwdAddr(); MemForSingleBit(a->name1, FALSE, &addr, &bit); WORD m = 0; EE_REG_BANKSEL(REG_EECON1); IfBitSet(REG_EECON1 ^ m, 1); Instruction(OP_GOTO, isBusy, 0); EE_REG_BANKSEL(0); IfBitClear(EepromHighByteWaitingAddr, EepromHighByteWaitingBit); Instruction(OP_GOTO, done, 0); // So there is not a write pending, but we have another // character to transmit queued up. EE_REG_BANKSEL(REG_EEADR); Instruction(OP_INCF, REG_EEADR ^ m, DEST_F); EE_REG_BANKSEL(0); Instruction(OP_MOVF, EepromHighByte, DEST_W); EE_REG_BANKSEL(REG_EEDATA); Instruction(OP_MOVWF, REG_EEDATA ^ m, 0); EE_REG_BANKSEL(REG_EECON1); Instruction(OP_BCF, REG_EECON1 ^ m, 7); Instruction(OP_BSF, REG_EECON1 ^ m, 2); Instruction(OP_MOVLW, 0x55, 0); Instruction(OP_MOVWF, REG_EECON2 ^ m, 0); Instruction(OP_MOVLW, 0xaa, 0); Instruction(OP_MOVWF, REG_EECON2 ^ m, 0); Instruction(OP_BSF, REG_EECON1 ^ m, 1); EE_REG_BANKSEL(0); ClearBit(EepromHighByteWaitingAddr, EepromHighByteWaitingBit); FwdAddrIsNow(isBusy); // Have to do these explicitly; m is out of date due to jump. Instruction(OP_BCF, REG_STATUS, STATUS_RP0); Instruction(OP_BCF, REG_STATUS, STATUS_RP1); SetBit(addr, bit); FwdAddrIsNow(done); break; } case INT_EEPROM_WRITE: { MemForVariable(a->name1, &addrl, &addrh); WORD m = 0; SetBit(EepromHighByteWaitingAddr, EepromHighByteWaitingBit); Instruction(OP_MOVF, addrh, DEST_W); Instruction(OP_MOVWF, EepromHighByte, 0); EE_REG_BANKSEL(REG_EEADR); Instruction(OP_MOVLW, a->literal, 0); Instruction(OP_MOVWF, REG_EEADR ^ m, 0); EE_REG_BANKSEL(0); Instruction(OP_MOVF, addrl, DEST_W); EE_REG_BANKSEL(REG_EEDATA); Instruction(OP_MOVWF, REG_EEDATA ^ m, 0); EE_REG_BANKSEL(REG_EECON1); Instruction(OP_BCF, REG_EECON1 ^ m, 7); Instruction(OP_BSF, REG_EECON1 ^ m, 2); Instruction(OP_MOVLW, 0x55, 0); Instruction(OP_MOVWF, REG_EECON2 ^ m, 0); Instruction(OP_MOVLW, 0xaa, 0); Instruction(OP_MOVWF, REG_EECON2 ^ m, 0); Instruction(OP_BSF, REG_EECON1 ^ m, 1); EE_REG_BANKSEL(0); break; } case INT_EEPROM_READ: { int i; MemForVariable(a->name1, &addrl, &addrh); WORD m = 0; for(i = 0; i < 2; i++) { EE_REG_BANKSEL(REG_EEADR); Instruction(OP_MOVLW, a->literal+i, 0); Instruction(OP_MOVWF, REG_EEADR ^ m, 0); EE_REG_BANKSEL(REG_EECON1); Instruction(OP_BCF, REG_EECON1 ^ m, 7); Instruction(OP_BSF, REG_EECON1 ^ m, 0); EE_REG_BANKSEL(REG_EEDATA); Instruction(OP_MOVF, REG_EEDATA ^ m , DEST_W); EE_REG_BANKSEL(0); if(i == 0) { Instruction(OP_MOVWF, addrl, 0); } else { Instruction(OP_MOVWF, addrh, 0); } } break; } case INT_READ_ADC: { BYTE adcs; MemForVariable(a->name1, &addrl, &addrh); if(Prog.mcuClock > 5000000) { adcs = 2; // 32*Tosc } else if(Prog.mcuClock > 1250000) { adcs = 1; // 8*Tosc } else { adcs = 0; // 2*Tosc } int goPos, chsPos; if(McuIs("Microchip PIC16F887 40-PDIP") || McuIs("Microchip PIC16F886 28-PDIP or 28-SOIC")) { goPos = 1; chsPos = 2; } else { goPos = 2; chsPos = 3; } WriteRegister(REG_ADCON0, (BYTE) ((adcs << 6) | (MuxForAdcVariable(a->name1) << chsPos) | (0 << goPos) | // don't start yet // bit 1 unimplemented (1 << 0)) // A/D peripheral on ); WriteRegister(REG_ADCON1, (1 << 7) | // right-justified (0 << 0) // for now, all analog inputs ); if(strcmp(Prog.mcu->mcuName, "Microchip PIC16F88 18-PDIP or 18-SOIC")==0) { WriteRegister(REG_ANSEL, 0x7f); } if(McuIs("Microchip PIC16F887 40-PDIP") || McuIs("Microchip PIC16F886 28-PDIP or 28-SOIC")) { WriteRegister(REG_ANSEL, 0xff); WriteRegister(REG_ANSELH, 0x3f); } // need to wait Tacq (about 20 us) for mux, S/H etc. to settle int cyclesToWait = ((Prog.mcuClock / 4) * 20) / 1000000; cyclesToWait /= 3; if(cyclesToWait < 1) cyclesToWait = 1; Instruction(OP_MOVLW, cyclesToWait, 0); Instruction(OP_MOVWF, Scratch1, 0); DWORD wait = PicProgWriteP; Instruction(OP_DECFSZ, Scratch1, DEST_F); Instruction(OP_GOTO, wait, 0); SetBit(REG_ADCON0, goPos); DWORD spin = PicProgWriteP; IfBitSet(REG_ADCON0, goPos); Instruction(OP_GOTO, spin, 0); Instruction(OP_MOVF, REG_ADRESH, DEST_W); Instruction(OP_MOVWF, addrh, 0); Instruction(OP_BSF, REG_STATUS, STATUS_RP0); Instruction(OP_MOVF, REG_ADRESL ^ 0x80, DEST_W); Instruction(OP_BCF, REG_STATUS, STATUS_RP0); Instruction(OP_MOVWF, addrl, 0); // hook those pins back up to the digital inputs in case // some of them are used that way WriteRegister(REG_ADCON1, (1 << 7) | // right-justify A/D result (6 << 0) // all digital inputs ); if(strcmp(Prog.mcu->mcuName, "Microchip PIC16F88 18-PDIP or 18-SOIC")==0) { WriteRegister(REG_ANSEL, 0x00); } if(McuIs("Microchip PIC16F887 40-PDIP") || McuIs("Microchip PIC16F886 28-PDIP or 28-SOIC")) { WriteRegister(REG_ANSEL, 0x00); WriteRegister(REG_ANSELH, 0x00); } break; } case INT_END_IF: case INT_ELSE: return; case INT_SIMULATE_NODE_STATE: case INT_COMMENT: break; default: oops(); break; } if(((PicProgWriteP >> 11) != section) && topLevel) { // This is particularly prone to happening in the last section, // if the program doesn't fit (since we won't have attempted // to add padding). Error(_("Internal error relating to PIC paging; make program " "smaller or reshuffle it.")); CompileError(); } } } //----------------------------------------------------------------------------- // Configure Timer1 and Ccp1 to generate the periodic `cycle' interrupt // that triggers all the ladder logic processing. We will always use 16-bit // Timer1, with the prescaler configured appropriately. //----------------------------------------------------------------------------- static void ConfigureTimer1(int cycleTimeMicroseconds) { int divisor = 1; int countsPerCycle; while(divisor < 16) { int timerRate = (Prog.mcuClock / (4*divisor)); // hertz double timerPeriod = 1e6 / timerRate; // timer period, us countsPerCycle = (int)(cycleTimeMicroseconds / timerPeriod); if(countsPerCycle < 1000) { Error(_("Cycle time too fast; increase cycle time, or use faster " "crystal.")); CompileError(); } else if(countsPerCycle > 0xffff) { if(divisor >= 8) { Error( _("Cycle time too slow; decrease cycle time, or use slower " "crystal.")); CompileError(); } } else { break; } divisor *= 2; } WriteRegister(REG_CCPR1L, countsPerCycle & 0xff); WriteRegister(REG_CCPR1H, countsPerCycle >> 8); WriteRegister(REG_TMR1L, 0); WriteRegister(REG_TMR1H, 0); BYTE t1con = 0; // set up prescaler if(divisor == 1) t1con |= 0x00; else if(divisor == 2) t1con |= 0x10; else if(divisor == 4) t1con |= 0x20; else if(divisor == 8) t1con |= 0x30; else oops(); // enable clock, internal source t1con |= 0x01; WriteRegister(REG_T1CON, t1con); BYTE ccp1con; // compare mode, reset TMR1 on trigger ccp1con = 0x0b; WriteRegister(REG_CCP1CON, ccp1con); } //----------------------------------------------------------------------------- // Write a subroutine to do a 16x16 signed multiply. One operand in // Scratch1:Scratch0, other in Scratch3:Scratch2, result in Scratch3:Scratch2. //----------------------------------------------------------------------------- static void WriteMultiplyRoutine(void) { DWORD result3 = Scratch5; DWORD result2 = Scratch4; DWORD result1 = Scratch3; DWORD result0 = Scratch2; DWORD multiplicand0 = Scratch0; DWORD multiplicand1 = Scratch1; DWORD counter = Scratch6; DWORD dontAdd = AllocFwdAddr(); DWORD top; FwdAddrIsNow(MultiplyRoutineAddress); Instruction(OP_CLRF, result3, 0); Instruction(OP_CLRF, result2, 0); Instruction(OP_BCF, REG_STATUS, STATUS_C); Instruction(OP_RRF, result1, DEST_F); Instruction(OP_RRF, result0, DEST_F); Instruction(OP_MOVLW, 16, 0); Instruction(OP_MOVWF, counter, 0); top = PicProgWriteP; Instruction(OP_BTFSS, REG_STATUS, STATUS_C); Instruction(OP_GOTO, dontAdd, 0); Instruction(OP_MOVF, multiplicand0, DEST_W); Instruction(OP_ADDWF, result2, DEST_F); Instruction(OP_BTFSC, REG_STATUS, STATUS_C); Instruction(OP_INCF, result3, DEST_F); Instruction(OP_MOVF, multiplicand1, DEST_W); Instruction(OP_ADDWF, result3, DEST_F); FwdAddrIsNow(dontAdd); Instruction(OP_BCF, REG_STATUS, STATUS_C); Instruction(OP_RRF, result3, DEST_F); Instruction(OP_RRF, result2, DEST_F); Instruction(OP_RRF, result1, DEST_F); Instruction(OP_RRF, result0, DEST_F); Instruction(OP_DECFSZ, counter, DEST_F); Instruction(OP_GOTO, top, 0); Instruction(OP_RETURN, 0, 0); } //----------------------------------------------------------------------------- // Write a subroutine to do a 16/16 signed divide. Call with dividend in // Scratch1:0, divisor in Scratch3:2, and get the result in Scratch1:0. //----------------------------------------------------------------------------- static void WriteDivideRoutine(void) { DWORD dividend0 = Scratch0; DWORD dividend1 = Scratch1; DWORD divisor0 = Scratch2; DWORD divisor1 = Scratch3; DWORD remainder0 = Scratch4; DWORD remainder1 = Scratch5; DWORD counter = Scratch6; DWORD sign = Scratch7; DWORD dontNegateDivisor = AllocFwdAddr(); DWORD dontNegateDividend = AllocFwdAddr(); DWORD done = AllocFwdAddr(); DWORD notNegative = AllocFwdAddr(); DWORD loop; FwdAddrIsNow(DivideRoutineAddress); Instruction(OP_MOVF, dividend1, DEST_W); Instruction(OP_XORWF, divisor1, DEST_W); Instruction(OP_MOVWF, sign, 0); Instruction(OP_BTFSS, divisor1, 7); Instruction(OP_GOTO, dontNegateDivisor, 0); Instruction(OP_COMF, divisor0, DEST_F); Instruction(OP_COMF, divisor1, DEST_F); Instruction(OP_INCF, divisor0, DEST_F); Instruction(OP_BTFSC, REG_STATUS, STATUS_Z); Instruction(OP_INCF, divisor1, DEST_F); FwdAddrIsNow(dontNegateDivisor); Instruction(OP_BTFSS, dividend1, 7); Instruction(OP_GOTO, dontNegateDividend, 0); Instruction(OP_COMF, dividend0, DEST_F); Instruction(OP_COMF, dividend1, DEST_F); Instruction(OP_INCF, dividend0, DEST_F); Instruction(OP_BTFSC, REG_STATUS, STATUS_Z); Instruction(OP_INCF, dividend1, DEST_F); FwdAddrIsNow(dontNegateDividend); Instruction(OP_CLRF, remainder1, 0); Instruction(OP_CLRF, remainder0, 0); Instruction(OP_BCF, REG_STATUS, STATUS_C); Instruction(OP_MOVLW, 17, 0); Instruction(OP_MOVWF, counter, 0); loop = PicProgWriteP; Instruction(OP_RLF, dividend0, DEST_F); Instruction(OP_RLF, dividend1, DEST_F); Instruction(OP_DECF, counter, DEST_F); Instruction(OP_BTFSC, REG_STATUS, STATUS_Z); Instruction(OP_GOTO, done, 0); Instruction(OP_RLF, remainder0, DEST_F); Instruction(OP_RLF, remainder1, DEST_F); Instruction(OP_MOVF, divisor0, DEST_W); Instruction(OP_SUBWF, remainder0, DEST_F); Instruction(OP_BTFSS, REG_STATUS, STATUS_C); Instruction(OP_DECF, remainder1, DEST_F); Instruction(OP_MOVF, divisor1, DEST_W); Instruction(OP_SUBWF, remainder1, DEST_F); Instruction(OP_BTFSS, remainder1, 7); Instruction(OP_GOTO, notNegative, 0); Instruction(OP_MOVF, divisor0, DEST_W); Instruction(OP_ADDWF, remainder0, DEST_F); Instruction(OP_BTFSC, REG_STATUS, STATUS_C); Instruction(OP_INCF, remainder1, DEST_F); Instruction(OP_MOVF, divisor1, DEST_W); Instruction(OP_ADDWF, remainder1, DEST_F); Instruction(OP_BCF, REG_STATUS, STATUS_C); Instruction(OP_GOTO, loop, 0); FwdAddrIsNow(notNegative); Instruction(OP_BSF, REG_STATUS, STATUS_C); Instruction(OP_GOTO, loop, 0); FwdAddrIsNow(done); Instruction(OP_BTFSS, sign, 7); Instruction(OP_RETURN, 0, 0); Instruction(OP_COMF, dividend0, DEST_F); Instruction(OP_COMF, dividend1, DEST_F); Instruction(OP_INCF, dividend0, DEST_F); Instruction(OP_BTFSC, REG_STATUS, STATUS_Z); Instruction(OP_INCF, dividend1, DEST_F); Instruction(OP_RETURN, 0, 0); } //----------------------------------------------------------------------------- // Compile the program to PIC16 code for the currently selected processor // and write it to the given file. Produce an error message if we cannot // write to the file, or if there is something inconsistent about the // program. //----------------------------------------------------------------------------- void CompilePic16(char *outFile) { FILE *f = fopen(outFile, "w"); if(!f) { Error(_("Couldn't open file '%s'"), outFile); return; } if(setjmp(CompileErrorBuf) != 0) { fclose(f); return; } WipeMemory(); AllocStart(); Scratch0 = AllocOctetRam(); Scratch1 = AllocOctetRam(); Scratch2 = AllocOctetRam(); Scratch3 = AllocOctetRam(); Scratch4 = AllocOctetRam(); Scratch5 = AllocOctetRam(); Scratch6 = AllocOctetRam(); Scratch7 = AllocOctetRam(); // Allocate the register used to hold the high byte of the EEPROM word // that's queued up to program, plus the bit to indicate that it is // valid. EepromHighByte = AllocOctetRam(); AllocBitRam(&EepromHighByteWaitingAddr, &EepromHighByteWaitingBit); DWORD progStart = AllocFwdAddr(); // Our boot vectors; not necessary to do it like this, but it lets // bootloaders rewrite the beginning of the program to do their magic. // PCLATH is init to 0, but apparently some bootloaders want to see us // initialize it again. Instruction(OP_BCF, REG_PCLATH, 3); Instruction(OP_BCF, REG_PCLATH, 4); Instruction(OP_GOTO, progStart, 0); Instruction(OP_NOP, 0, 0); Instruction(OP_NOP, 0, 0); Instruction(OP_NOP, 0, 0); Instruction(OP_NOP, 0, 0); Instruction(OP_NOP, 0, 0); FwdAddrIsNow(progStart); // Now zero out the RAM Instruction(OP_MOVLW, Prog.mcu->ram[0].start + 8, 0); Instruction(OP_MOVWF, REG_FSR, 0); Instruction(OP_MOVLW, Prog.mcu->ram[0].len - 8, 0); Instruction(OP_MOVWF, Scratch0, 0); DWORD zeroMem = PicProgWriteP; Instruction(OP_CLRF, REG_INDF, 0); Instruction(OP_INCF, REG_FSR, DEST_F); Instruction(OP_DECFSZ, Scratch0, DEST_F); Instruction(OP_GOTO, zeroMem, 0); DivideRoutineAddress = AllocFwdAddr(); DivideNeeded = FALSE; MultiplyRoutineAddress = AllocFwdAddr(); MultiplyNeeded = FALSE; ConfigureTimer1(Prog.cycleTime); // Set up the TRISx registers (direction). 1 means tri-stated (input). BYTE isInput[MAX_IO_PORTS], isOutput[MAX_IO_PORTS]; BuildDirectionRegisters(isInput, isOutput); if(McuIs("Microchip PIC16F877 40-PDIP") || McuIs("Microchip PIC16F819 18-PDIP or 18-SOIC") || McuIs("Microchip PIC16F88 18-PDIP or 18-SOIC") || McuIs("Microchip PIC16F876 28-PDIP or 28-SOIC") || McuIs("Microchip PIC16F887 40-PDIP") || McuIs("Microchip PIC16F886 28-PDIP or 28-SOIC")) { REG_EECON1 = 0x18c; REG_EECON2 = 0x18d; REG_EEDATA = 0x10c; REG_EEADR = 0x10d; } else if(McuIs("Microchip PIC16F628 18-PDIP or 18-SOIC")) { REG_EECON1 = 0x9c; REG_EECON2 = 0x9d; REG_EEDATA = 0x9a; REG_EEADR = 0x9b; } else { oops(); } if(McuIs("Microchip PIC16F887 40-PDIP") || McuIs("Microchip PIC16F886 28-PDIP or 28-SOIC")) { REG_ANSEL = 0x188; REG_ANSELH = 0x189; } else { REG_ANSEL = 0x9b; } if(strcmp(Prog.mcu->mcuName, "Microchip PIC16F877 40-PDIP")==0) { // This is a nasty special case; one of the extra bits in TRISE // enables the PSP, and must be kept clear (set here as will be // inverted). isOutput[4] |= 0xf8; } if(strcmp(Prog.mcu->mcuName, "Microchip PIC16F877 40-PDIP")==0 || strcmp(Prog.mcu->mcuName, "Microchip PIC16F819 18-PDIP or 18-SOIC")==0 || strcmp(Prog.mcu->mcuName, "Microchip PIC16F876 28-PDIP or 28-SOIC")==0) { // The GPIOs that can also be A/D inputs default to being A/D // inputs, so turn that around WriteRegister(REG_ADCON1, (1 << 7) | // right-justify A/D result (6 << 0) // all digital inputs ); } if(strcmp(Prog.mcu->mcuName, "Microchip PIC16F88 18-PDIP or 18-SOIC")==0) { WriteRegister(REG_ANSEL, 0x00); // all digital inputs } if(strcmp(Prog.mcu->mcuName, "Microchip PIC16F628 18-PDIP or 18-SOIC")==0) { // This is also a nasty special case; the comparators on the // PIC16F628 are enabled by default and need to be disabled, or // else the PORTA GPIOs don't work. WriteRegister(REG_CMCON, 0x07); } if(McuIs("Microchip PIC16F887 40-PDIP") || McuIs("Microchip PIC16F886 28-PDIP or 28-SOIC")) { WriteRegister(REG_ANSEL, 0x00); // all digital inputs WriteRegister(REG_ANSELH, 0x00); // all digital inputs } if(PwmFunctionUsed()) { // Need to clear TRIS bit corresponding to PWM pin int i; for(i = 0; i < Prog.mcu->pinCount; i++) { if(Prog.mcu->pinInfo[i].pin == Prog.mcu->pwmNeedsPin) { McuIoPinInfo *iop = &(Prog.mcu->pinInfo[i]); isOutput[iop->port - 'A'] |= (1 << iop->bit); break; } } if(i == Prog.mcu->pinCount) oops(); } int i; for(i = 0; Prog.mcu->dirRegs[i] != 0; i++) { WriteRegister(Prog.mcu->outputRegs[i], 0x00); WriteRegister(Prog.mcu->dirRegs[i], ~isOutput[i]); } if(UartFunctionUsed()) { if(Prog.baudRate == 0) { Error(_("Zero baud rate not possible.")); fclose(f); return; } // So now we should set up the UART. First let us calculate the // baud rate; there is so little point in the fast baud rates that // I won't even bother, so // bps = Fosc/(64*(X+1)) // bps*64*(X + 1) = Fosc // X = Fosc/(bps*64)-1 // and round, don't truncate int divisor = (Prog.mcuClock + Prog.baudRate*32)/(Prog.baudRate*64) - 1; double actual = Prog.mcuClock/(64.0*(divisor+1)); double percentErr = 100*(actual - Prog.baudRate)/Prog.baudRate; if(fabs(percentErr) > 2) { ComplainAboutBaudRateError(divisor, actual, percentErr); } if(divisor > 255) ComplainAboutBaudRateOverflow(); WriteRegister(REG_SPBRG, divisor); WriteRegister(REG_TXSTA, 0x20); // only TXEN set WriteRegister(REG_RCSTA, 0x90); // only SPEN, CREN set } DWORD top = PicProgWriteP; IfBitClear(REG_PIR1, 2); Instruction(OP_GOTO, PicProgWriteP - 1, 0); Instruction(OP_BCF, REG_PIR1, 2); Instruction(OP_CLRWDT, 0, 0); IntPc = 0; CompileFromIntermediate(TRUE); MemCheckForErrorsPostCompile(); // This is probably a big jump, so give it PCLATH. Instruction(OP_CLRF, REG_PCLATH, 0); Instruction(OP_GOTO, top, 0); // Once again, let us make sure not to put stuff on a page boundary if((PicProgWriteP >> 11) != ((PicProgWriteP + 150) >> 11)) { DWORD section = (PicProgWriteP >> 11); // Just burn the last of this section with NOPs. while((PicProgWriteP >> 11) == section) { Instruction(OP_MOVLW, 0xab, 0); } } if(MultiplyNeeded) WriteMultiplyRoutine(); if(DivideNeeded) WriteDivideRoutine(); WriteHexFile(f); fclose(f); char str[MAX_PATH+500]; sprintf(str, _("Compile successful; wrote IHEX for PIC16 to '%s'.\r\n\r\n" "Configuration word (fuses) has been set for crystal oscillator, BOD " "enabled, LVP disabled, PWRT enabled, all code protection off.\r\n\r\n" "Used %d/%d words of program flash (chip %d%% full)."), outFile, PicProgWriteP, Prog.mcu->flashWords, (100*PicProgWriteP)/Prog.mcu->flashWords); CompileSuccessfulMessage(str); }