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[/] [forwardcom/] [bintools/] [assem5.cpp] - Rev 166
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/**************************** assem5.cpp ******************************** * Author: Agner Fog * Date created: 2017-09-19 * Last modified: 2021-05-21 * Version: 1.11 * Project: Binary tools for ForwardCom instruction set * Module: assem.cpp * Description: * Module for assembling ForwardCom .as files. * This module contains functions for interpreting high level language constructs: * functions, branches, and loops * * Copyright 2017-2021 GNU General Public License http://www.gnu.org/licenses ******************************************************************************/ #include "stdafx.h" // Define high level block types const int HL_SECTION = 1; // section const int HL_FUNC = 2; // function const int HL_IF = 3; // if branch const int HL_ELSE = 4; // else branch const int HL_SWITCH = 5; // switch-case branch const int HL_FOR = 6; // for loop const int HL_FOR_IN = 7; // vector loop. for (v1 in [r2-r3]) {} const int HL_WHILE = 8; // while loop const int HL_DO_WHILE = 9; // do-while loop // invert condition code for branch instruction void invertCondition(SCode & code) { code.instruction ^= II_JUMP_INVERT; // invert condition code if ((code.dtype & TYP_FLOAT) && (code.instruction & 0xFF) == II_COMPARE && (code.instruction & 0x7F00) - 0x1000 < 0x2000) { // floating point compare instructions, except jump_ordered, must invert the unordered bit code.instruction ^= II_JUMP_UNORDERED; // inverse condition is unordered } } // if, else, switch, for, do, while statements void CAssembler::interpretHighLevelStatement() { //uint32_t label = 0; if (tokenN > 2 && tokens[tokenB].type == TOK_SYM && tokens[tokenB+1].id == ':') { // line starts with a label. insert label // (this will prevent merging of jump instruction. merging is not allowed when there is a label between the two instructions) SCode codeL; zeroAllMembers(codeL); //codeL.label = tokens[tokenB].value.w; //? codeL.label = tokens[tokenB].id; codeL.section = section; codeBuffer.push(codeL); // interpret directive after label tokenB += 2; tokenN -= 2; } uint32_t tok = tokenB; if (tokenN > 1 && tokens[tok].type == TOK_TYP) { tok++; // skip type keyword if (tok+1 < tokenB+tokenN && tokens[tok].type == TOK_OPR && tokens[tok].id == '+') tok++; // skip '+' after type } // expect HLL keyword here. dispatch to the corresponding function switch (tokens[tok].id) { case HLL_IF: codeIf(); break; case HLL_SWITCH: codeSwitch(); break; case HLL_CASE: codeCase(); break; case HLL_FOR: codeFor(); break; case HLL_WHILE: codeWhile(); break; case HLL_DO: codeDo(); break; case HLL_BREAK: case HLL_CONTINUE: if (tok != tokenB) { errors.report(tokens[tok]); // cannot have type token before break or continue break; } codeBreak(); break; case HLL_PUSH: // may be replaced by macro later codePush(); break; case HLL_POP: // may be replaced by macro later codePop(); break; default: errors.report(tokens[tok]); } } // finish {} block void CAssembler::interpretEndBracket() { uint32_t n = hllBlocks.numEntries(); if (n == 0) { errors.reportLine(ERR_BRACKET_END); // unmatched end bracket return; } // dispatch depending on type of block switch (hllBlocks[n-1].blockType) { case HL_FUNC: // function break; case HL_IF: case HL_ELSE: // if branch codeIf2(); break; case HL_FOR: // for loop codeFor2(); break; case HL_FOR_IN: // vector loop. for (v1 in [r2-r3]) {} codeForIn2(); break; case HL_WHILE: // while loop codeWhile2(); break; case HL_DO_WHILE: // do-while loop codeDo2(); break; case HL_SWITCH: // switch-case branch break; default: errors.reportLine(ERR_BRACKET_END); // should not occur } } // Interpret if statement in assembly code void CAssembler::codeIf() { uint32_t state = 0; // 0: start, 1: after type, 2: after if, 3: after (, 4: after (type, // 5: after expression, 6: after ')', 7: after { uint32_t tok; // current token index SBlock block; // block descriptor to save zeroAllMembers(block); // reset block.blockType = HL_IF; // if block SToken token; // current token SExpression expr; // expression in () SCode code; // instruction code zeroAllMembers(code); // reset // interpret line by state machine looping through tokens for (tok = tokenB; tok < tokenB + tokenN; tok++) { if (lineError) break; token = tokens[tok]; switch (state) { case 0: // start. expect type or 'if' if (token.type == TOK_TYP) { code.dtype = dataType = token.id & 0xFF; state = 1; } else if (token.id == HLL_IF) state = 2; else errors.report(token); break; case 1: // after type. expect '+' or 'if' if (token.type == TOK_OPR && token.id == '+') { code.dtype |= TYP_PLUS; } else if (token.id == HLL_IF) state = 2; else errors.report(token); break; case 2: // after if. expect '(' if (token.type == TOK_OPR && token.id == '(') state = 3; else errors.report(token.pos, token.stringLength, ERR_EXPECT_PARENTHESIS); break; case 3: // after '('. expect type or logical expression if (token.type == TOK_TYP && !code.dtype) { code.dtype = dataType = token.id & 0xFF; state = 4; break; } EXPRESSION: expr = expression(tok, tokenB + tokenN-tok, (code.dtype & TYP_UNS) != 0); if (lineError) return; // insert logical expression into block insertAll(code, expr); tok += expr.tokens - 1; state = 5; break; case 4: // after "if (type". expect '+' or expression if (token.type == TOK_OPR && token.id == '+') { code.dtype |= TYP_PLUS; break; } // not a '+'. expect expression goto EXPRESSION; case 5: // after expression. expect ')' if (token.type == TOK_OPR && token.id == ')') state = 6; else { errors.report(token); return; } break; } } // should end at state 6 because '{' should be on next pseudo-line if (state != 6) errors.report(token); if (lineError) return; if (linei == lines.numEntries()-1) { // no more lines errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } // get next line if (linei == lines.numEntries()-1) { // no more lines errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line lineError = false; // expect '{' if (tokens[tokenB].id != '{') { errors.reportLine(ERR_EXPECT_BRACKET); return; } // interpret the condition expression linei--; // make any error message apply to previous line interpretCondition(code); linei++; // make instruction code code.etype |= XPR_JUMPOS | XPR_SYM1; code.section = section; // check if {} contains a jump only uint32_t target2 = hasJump(linei+1); if (target2) { if (linei + 2 < lines.numEntries() && lines[linei+2].numTokens == 1) { tok = lines[linei+2].firstToken; if (tokens[tok].type == TOK_OPR && tokens[tok].id == '}') { // the {} block contains a jump and nothing else // make conditional jump to target2 instead code.sym5 = target2; linei += 2; // finished processing these two lines // check if it can be merged with previous instruction mergeJump(code); // finish code and fit it checkCode1(code); if (lineError) return; fitCode(code); // find an instruction variant that fits if (lineError) return; codeBuffer.push(code);// save code structure // check if there is an 'else' after if(){} if (linei + 2 < lines.numEntries() && lines[linei+1].numTokens == 1 && lines[linei+2].numTokens == 1) { tok = lines[linei+1].firstToken; if (tokens[tok].type == TOK_HLL && tokens[tok].id == HLL_ELSE) { tok = lines[linei+2].firstToken; if (tokens[tok].type == TOK_OPR && tokens[tok].id == '{') { // make the 'else' ignored linei += 2; // make block record with no label block.blockNumber = ++iIf; block.startBracket = tok; block.jumpLabel = 0; // store block in hllBlocks stack. will be retrieved at matching '}' hllBlocks.push(block); } } } return; } } } invertCondition(code); // invert condition. jump to else block if logical expression false if (code.instruction == (II_JUMP | II_JUMP_INVERT)) { // constant: don't jump code.instruction = 0; } // make block record with label name block.blockNumber = ++iIf; block.startBracket = tokenB; char name[32]; sprintf(name, "@if_%u_a", iIf); uint32_t symi = makeLabelSymbol(name); block.jumpLabel = symbols[symi].st_name; // store block in hllBlocks stack. will be retrieved at matching '}' hllBlocks.push(block); // store jump instruction code.sym5 = block.jumpLabel; // check if it can be merged with previous instruction mergeJump(code); // finish code and fit it checkCode1(code); if (lineError) return; fitCode(code); // find an instruction variant that fits if (lineError) return; codeBuffer.push(code);// save code structure } // Finish if statement at end bracket void CAssembler::codeIf2() { SCode code; // code record for jump label zeroAllMembers(code); // reset SBlock block = hllBlocks.pop(); // pop the stack of {} blocks uint32_t labelA = block.jumpLabel; // jump target label to place here // check if there is an 'else' following the if(){} if (block.blockType == HL_IF && linei+2 < lines.numEntries() && tokens[lines[linei+1].firstToken].id == HLL_ELSE) { // there is an else. get next line with the else linei++; if (lines[linei].numTokens > 1) errors.report(tokens[lines[linei].firstToken+1]); // something other than '{' after else // check if there is a '{' following the 'else' linei++; uint32_t tokenB = lines[linei].firstToken; if (lines[linei].numTokens > 1 || tokens[tokenB].type != TOK_OPR || tokens[tokenB].id != '{') { errors.reportLine(ERR_EXPECT_BRACKET); // expecting '{' return; } // make block record for jump to label b block.blockType = HL_ELSE; // if-else block block.startBracket = tokenB; // make label name char name[32]; sprintf(name, "@if_%u_b", block.blockNumber); uint32_t symi = makeLabelSymbol(name); block.jumpLabel = symbols[symi].st_name; hllBlocks.push(block); // store block in hllBlocks stack. will be retrieved at matching '}' // make jump instruction code.section = section; code.instruction = II_JUMP; code.etype = XPR_JUMPOS | XPR_SYM1; code.sym5 = block.jumpLabel; // check if it can be merged with previous instruction mergeJump(code); // finish code and save it checkCode1(code); if (lineError) return; fitCode(code); // find an instruction variant that fits if (lineError) return; codeBuffer.push(code);// save code structure } // make target label here if (labelA) { zeroAllMembers(code); code.section = section; code.label = labelA; // jump target label codeBuffer.push(code); // save code structure } } // Interpret while loop in assembly code void CAssembler::codeWhile() { uint32_t state = 0; // 0: start, 1: after type, 2: after while, 3: after (, 4: after (type, // 5: after expression, 6: after ')', 7: after { uint32_t tok; // current token index SBlock block; // block descriptor to save zeroAllMembers(block); // reset SToken token; // current token SExpression expr; // expression in () SCode code; // instruction code zeroAllMembers(code); // reset // interpret line by state machine looping through tokens (same as for codeIf) for (tok = tokenB; tok < tokenB + tokenN; tok++) { if (lineError) break; token = tokens[tok]; switch (state) { case 0: // start. expect type or 'while' if (token.type == TOK_TYP) { code.dtype = dataType = token.id & 0xFF; state = 1; } else if (token.id == HLL_WHILE) state = 2; else errors.report(token); break; case 1: // after type. expect '+' or 'while' if (token.type == TOK_OPR && token.id == '+') { code.dtype |= TYP_PLUS; } else if (token.id == HLL_WHILE) state = 2; else errors.report(token); break; case 2: // after if. expect '(' if (token.type == TOK_OPR && token.id == '(') state = 3; else errors.report(token.pos, token.stringLength, ERR_EXPECT_PARENTHESIS); break; case 3: // after '('. expect type or logical expression if (token.type == TOK_TYP && !code.dtype) { code.dtype = dataType = token.id & 0xFF; state = 4; break; } EXPRESSION: expr = expression(tok, tokenB + tokenN-tok, (code.dtype & TYP_UNS) != 0); if (lineError) return; // insert logical expression into block insertAll(code, expr); tok += expr.tokens - 1; state = 5; break; case 4: // after "while (type". expect '+' or expression if (token.type == TOK_OPR && token.id == '+') { code.dtype |= TYP_PLUS; break; } // not a '+'. expect expression goto EXPRESSION; case 5: // after expression. expect ')' if (token.type == TOK_OPR && token.id == ')') state = 6; else { errors.report(token); return; } break; } } // should end at state 6 because '{' should be on next pseudo-line if (state != 6) errors.report(token); if (lineError) return; if (linei == lines.numEntries()-1) { // no more lines errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } // get next line // get next line if (linei == lines.numEntries()-1) { // no more lines errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line lineError = false; // expect '{' if (tokens[tokenB].id != '{') { errors.reportLine(ERR_EXPECT_BRACKET); return; } // interpret the condition expression linei--; // make any error message apply to previous line interpretCondition(code); linei++; // make instruction code code.etype |= XPR_JUMPOS | XPR_SYM1; code.section = section; // make block record with label names block.blockType = HL_WHILE; // while-block block.blockNumber = ++iLoop; block.startBracket = tokenB; char name[32]; sprintf(name, "@while_%u_a", iLoop); uint32_t symi1 = makeLabelSymbol(name); block.jumpLabel = symbols[symi1].st_name; // label to jump back to sprintf(name, "@while_%u_b", iLoop); uint32_t symi2 = makeLabelSymbol(name); block.breakLabel = symbols[symi2].st_name; // label after loop. used if condition is false first time and for break statements block.continueLabel = 0xFFFFFFFF; // this label will only be made if there is a continue statement // make code to check condition before first iteration SCode code1 = code; invertCondition(code1); // invert condition to jump if false if (code1.instruction == (II_JUMP | II_JUMP_INVERT)) { // constant: don't jump code1.instruction = 0; } code1.sym5 = block.breakLabel; // check if it can be merged with previous instruction mergeJump(code1); // finish code and store it checkCode1(code1); if (lineError) return; fitCode(code1); // find an instruction variant that fits if (lineError) return; codeBuffer.push(code1);// save code structure // make loop label zeroAllMembers(code1); code1.label = block.jumpLabel; code1.section = section; codeBuffer.push(code1);// save code structure // make instruction to place at end of loop code.sym5 = block.jumpLabel; checkCode1(code); // store in codeBuffer2 for later insertion at the end of the loop block.codeBuffer2index = codeBuffer2.push(code); block.codeBuffer2num = 1; // store block in hllBlocks stack. will be retrieved at matching '}' hllBlocks.push(block); } // Finish while-loop at end bracket void CAssembler::codeWhile2() { SCode code; // code record for jump back SBlock block = hllBlocks.pop(); // pop the stack of {} blocks if (block.continueLabel != 0xFFFFFFFF) { // place label here as jump target for continue statements zeroAllMembers(code); code.label = block.continueLabel; code.section = section; codeBuffer.push(code); } uint32_t codebuf2num = codeBuffer2.numEntries(); if (block.codeBuffer2num && block.codeBuffer2index < codebuf2num) { // retrieve jumpback instruction code = codeBuffer2[block.codeBuffer2index]; if (code.instruction == (II_JUMP | II_JUMP_INVERT)) { // constant: don't jump code.instruction = 0; } // check if it can be merged with previous instruction mergeJump(code); // finish code and store it checkCode1(code); if (lineError) return; fitCode(code); // find an instruction variant that fits if (lineError) return; codeBuffer.push(code); // save code // remove from temporary buffer if (block.codeBuffer2index + 1 == codebuf2num) codeBuffer2.pop(); // place label for breaking out zeroAllMembers(code); code.label = block.breakLabel; code.section = section; codeBuffer.push(code); // save label return; } } // Interpret do-while loop in assembly code void CAssembler::codeDo() { SBlock block; // block record SCode code; // code record for label zeroAllMembers(block); zeroAllMembers(code); // make block record with label names block.blockType = HL_DO_WHILE; // do-while-block block.blockNumber = ++iLoop; char name[32]; sprintf(name, "@do_%u_a", iLoop); uint32_t symi1 = makeLabelSymbol(name); block.jumpLabel = symbols[symi1].st_name; // label to jump back to block.breakLabel = 0xFFFFFFFF; // this label will only be made if there is a break statement block.continueLabel = 0xFFFFFFFF; // this label will only be made if there is a continue statement // make loop label code.label = block.jumpLabel; code.section = section; codeBuffer.push(code); // save label // get next line with '{' if (linei == lines.numEntries()-1) { // no more lines errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line lineError = false; // expect '{' if (tokens[tokenB].id != '{') { errors.report(tokens[tokenB]); return; } block.startBracket = tokenB; hllBlocks.push(block); // store block in hllBlocks stack. will be retrieved at matching '}' } // Finish do-while loop at end bracket void CAssembler::codeDo2() { SCode code; // code record SBlock block = hllBlocks.pop(); // pop the stack of {} blocks if (block.continueLabel != 0xFFFFFFFF) { // place label here as jump target for continue statements zeroAllMembers(code); code.label = block.continueLabel; code.section = section; codeBuffer.push(code); } // find 'while' keyword in next pseudo-line after '}' if (linei+1 >= lines.numEntries()) { // no more lines errors.reportLine(ERR_WHILE_EXPECTED); return; } linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line lineError = false; // expect "while (expression)" uint32_t state = 0; // 0: start, 1: after type, 2: after 'while', 3: after (, 4: after (type, // 5: after expression, 6: after ')' uint32_t tok; // current token index SToken token; // current token SExpression expr; // expression in () zeroAllMembers(code); // reset code // interpret line by state machine looping through tokens for (tok = tokenB; tok < tokenB + tokenN; tok++) { if (lineError) return; token = tokens[tok]; switch (state) { case 0: // start. expect type or 'while' if (token.type == TOK_TYP) { code.dtype = dataType = token.id & 0xFF; state = 1; } else if (token.id == HLL_WHILE) state = 2; else errors.reportLine(ERR_WHILE_EXPECTED); break; case 1: // after type. expect '+' or 'while' if (token.type == TOK_OPR && token.id == '+') { code.dtype |= TYP_PLUS; } else if (token.id == HLL_WHILE) state = 2; else errors.report(token); break; case 2: // after 'while'. expect '(' if (token.type == TOK_OPR && token.id == '(') state = 3; else errors.report(token.pos, token.stringLength, ERR_EXPECT_PARENTHESIS); break; case 3: // after '('. expect type or logical expression if (token.type == TOK_TYP && !code.dtype) { code.dtype = dataType = token.id & 0xFF; state = 4; break; } EXPRESSION: expr = expression(tok, tokenB + tokenN - tok, (code.dtype & TYP_UNS) != 0); if (lineError) return; // insert logical expression into block insertAll(code, expr); tok += expr.tokens - 1; state = 5; break; case 4: // after "while (type". expect '+' or expression if (token.type == TOK_OPR && token.id == '+') { code.dtype |= TYP_PLUS; break; } // not a '+'. expect expression goto EXPRESSION; case 5: // after expression. expect ')' if (token.type == TOK_OPR && token.id == ')') state = 6; else { errors.report(token); return; } break; } } // should end at state 6 if (state != 6) errors.report(token); if (lineError) return; // make instruction with condition interpretCondition(code); code.etype |= XPR_JUMPOS | XPR_SYM1; code.section = section; code.sym5 = block.jumpLabel; if (code.instruction == (II_JUMP | II_JUMP_INVERT)) { // constant: don't jump code.instruction = 0; } // check if it can be merged with previous instruction mergeJump(code); // finish code and fit it checkCode1(code); if (lineError) return; fitCode(code); // find an instruction variant that fits if (lineError) return; codeBuffer.push(code);// save code structure if (block.breakLabel != 0xFFFFFFFF) { // place label here as jump target for break statements zeroAllMembers(code); code.label = block.breakLabel; code.section = section; codeBuffer.push(code); } } // Interpret for-loop in assembly code void CAssembler::codeFor() { uint32_t tok; // token number // search for 'in' keyword for (tok = tokenB; tok < tokenB + tokenN; tok++) { if (tokens[tok].type == TOK_HLL && tokens[tok].id == HLL_IN) { // this is a for-in vector loop codeForIn(); return; } } // this is a traditional for(;;) loop uint32_t state = 0; // state while interpreting line // 0: start, 1: after type, 2: after 'for', 3: after (, 4: after (type, SBlock block; // block descriptor to save zeroAllMembers(block); // reset block.blockType = HL_FOR; // 'for' block block.breakLabel = block.jumpLabel = block.continueLabel = 0xFFFFFFFF; SToken token; // current token SToken typeToken; // token defining type // uint32_t type = 0; // operand type for all three expressions in for(;;) dataType = 0; // operand type for all three expressions in for(;;) uint32_t symi = 0; // symbol index char name[48]; // symbol name int conditionFirst = 0; // evaluation of the condition before first iteration: // 0: condition must be checked before first iteration // 2: condition is false before first iteration. zero iterations // 3: condition is true before first iteration. no initial check needed // interpret line by state machine looping through tokens for (tok = tokenB; tok < tokenB + tokenN; tok++) { if (lineError) break; token = tokens[tok]; if (state == 0) { // start. expect type or 'for' if (token.type == TOK_TYP) { dataType = token.id & 0xFF; typeToken = token; state = 1; } else if (token.id == HLL_FOR) state = 2; else errors.report(token); } else if (state == 1) { // after type. expect '+' or 'for' if (token.type == TOK_OPR && token.id == '+') { dataType |= TYP_PLUS; } else if (token.id == HLL_FOR) state = 2; else errors.report(token); } else if (state == 2) { // after 'for'. expect '(' if (token.type == TOK_OPR && token.id == '(') state = 3; else errors.report(token.pos, token.stringLength, ERR_EXPECT_PARENTHESIS); } else if (state == 3) { // after '('. expect type or initialization if (token.type == TOK_TYP && !dataType) { dataType = token.id & 0xFF; typeToken = token; tok++; if (tok < tokenB + tokenN && tokens[tok].type == TOK_OPR && tokens[tok].id == '+') { // '+' after type dataType |= TYP_PLUS; tok++; } } state = 4; break; // end tok loop here } } if (state != 4) { errors.report(token); return; } if (lineError) return; // check type if (dataType == 0) { errors.reportLine(ERR_TYPE_MISSING); return; } // extend type to int32 if allowed. this allows various optimizations // (unsigned types not allowed, even if start and end values are known to be positive, because loop counter may become negative inside loop in rare cases) if ((dataType & TYP_PLUS) && ((dataType & 0xFF) < (TYP_INT32 & 0xFF))) dataType = TYP_INT32; // remake token sequence for generating initial instruction uint32_t tokensRestorePoint = tokens.numEntries(); typeToken.id = dataType; tokens.push(typeToken); uint32_t tokenFirst = tok; if (tokens[tokenFirst].type == TOK_TYP) tokenFirst++; // skip type token. it has already been inserted for (; tok < tokenB + tokenN; tok++) { // insert remaining tokens token = tokens[tok]; if (token.type == TOK_OPR && token.id == ';') break; tokens.push(tokens[tok]); } // make an instruction out of this sequence tokenB = tokensRestorePoint; tokenN = tokens.numEntries() - tokensRestorePoint; uint32_t codePoint = codeBuffer.numEntries(); SCode initializationCode; zeroAllMembers(initializationCode); if (tokenN > 1) { // skip if there is no code interpretCodeLine(); if (codeBuffer.numEntries() == codePoint + 1) { // remember initialization code initializationCode = codeBuffer[codePoint]; } } // remove temporary token sequence tokens.setNum(tokensRestorePoint); if (lineError) return; // get next line containing loop condition SCode conditionCode; zeroAllMembers(conditionCode); conditionCode.section = section; if (linei+2 >= lines.numEntries()) { // no more lines errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line if (tokenN == 1 && tokens[tokenB].type == TOK_OPR && tokens[tokenB].id == ';') { // no condition specified. infinite loop conditionFirst = 3; conditionCode.instruction = II_JUMP; conditionCode.etype = XPR_JUMPOS; } else { SExpression expr = expression(tokenB, tokenN, (dataType & TYP_UNS) != 0); if (lineError) return; insertAll(conditionCode, expr); // insert logical expression into block conditionCode.dtype = dataType; interpretCondition(conditionCode); // convert expression to conditional jump if (conditionCode.etype == XPR_INT) { // always true or always false conditionFirst = 2 + (conditionCode.value.w & 1); conditionCode.instruction = II_JUMP; conditionCode.etype = XPR_JUMPOS; conditionCode.value.i = 0; conditionCode.dtype = 0; } else { conditionCode.etype |= XPR_JUMPOS | XPR_SYM1; conditionCode.section = section; tok = tokenB + expr.tokens; // expect ';' after expression if (tokens[tok].type != TOK_OPR || tokens[tok].id != ';') { errors.report(tokens[tok]); } //uint32_t counterRegister = 0; uint64_t counterStart = 0; // are start and end values known constants? if (initializationCode.instruction == II_MOVE && (initializationCode.etype & XPR_INT) && initializationCode.dest && !(initializationCode.etype & (XPR_REG1 | XPR_MEM | XPR_OPTION))) { //counterRegister = initializationCode.dest; counterStart = initializationCode.value.i; if ((expr.etype & XPR_INT) && (expr.etype & XPR_REG1) && !(expr.etype & (XPR_REG2 | XPR_MEM | XPR_OPTION))) { // start and end values are integer constants if ((expr.instruction & 0xFF) == II_COMPARE) { // compare instruction. condition is in option bits switch ((expr.optionbits >> 1) & 3) { case 0: // == conditionFirst = 2 + (counterStart == expr.value.u); break; case 1: // < if (dataType & TYP_UNS) conditionFirst = 2 + (counterStart < expr.value.u); else conditionFirst = 2 + ((int64_t)counterStart < expr.value.i); break; case 2: // > if (dataType & TYP_UNS) conditionFirst = 2 + (counterStart > expr.value.u); else conditionFirst = 2 + ((int64_t)counterStart > expr.value.i); break; } if (expr.optionbits & 1) conditionFirst ^= 1; // invert if bit 0 } else if ((expr.instruction & 0xFF) == II_AND) { // bit test. if (r1 & 1 << n) conditionFirst = 2 + ((counterStart & ((uint64_t)1 << expr.value.u)) != 0); } } } } } // make block record with label name block.blockNumber = ++iLoop; if (conditionFirst == 0) { // condition must be checked before first iteration invertCondition(conditionCode); // invert condition sprintf(name, "@for_%u_b", iLoop); symi = makeLabelSymbol(name); block.breakLabel = symbols[symi].st_name; conditionCode.sym5 = block.breakLabel; // check if it can be merged with previous instruction mergeJump(conditionCode); checkCode1(conditionCode); // finish code and fit it if (lineError) return; fitCode(conditionCode); // find an instruction variant that fits if (lineError) return; codeBuffer.push(conditionCode); // save code structure invertCondition(conditionCode); // invert condition back again } else if (conditionFirst == 2) { // condition is known to be false. loop goes zero times SCode jumpAlways; zeroAllMembers(jumpAlways); jumpAlways.instruction = II_JUMP; // jump past loop jumpAlways.section = section; jumpAlways.etype = XPR_JUMPOS; sprintf(name, "@for_%u_goes_zero_times", iLoop); symi = makeLabelSymbol(name); block.breakLabel = symbols[symi].st_name; jumpAlways.sym5 = block.breakLabel; // check if it can be merged with previous instruction mergeJump(jumpAlways); checkCode1(jumpAlways); // finish code and fit it if (lineError) return; fitCode(jumpAlways); // find an instruction variant that fits if (lineError) return; codeBuffer.push(jumpAlways); // save code structure } // make label for loop back if (conditionCode.instruction != II_JUMP) { sprintf(name, "@for_%u_a", iLoop); } else { sprintf(name, "@infinite_loop_%u_a", iLoop); } symi = makeLabelSymbol(name); block.jumpLabel = symbols[symi].st_name; conditionCode.sym5 = block.jumpLabel; SCode codeLabel; zeroAllMembers(codeLabel); codeLabel.label = block.jumpLabel; codeLabel.section = section; codeBuffer.push(codeLabel); // get next line containing increment linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line // line must end with ')' if (tokenN < 1) { errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } if (tokens[tokenB+tokenN-1].type != TOK_OPR || tokens[tokenB+tokenN-1].id != ')') { errors.report(tokens[tokenB+tokenN-1]); // expecting ')' return; } // make instruction for loop counter increment tokens.push(typeToken); for (tok = tokenB; tok < tokenB + tokenN - 1; tok++) { // insert remaining tokens tokens.push(tokens[tok]); } // make an instruction out of this sequence tokenB = tokensRestorePoint; tokenN = tokens.numEntries() - tokensRestorePoint; SCode incrementCode; zeroAllMembers(incrementCode); codePoint = codeBuffer.numEntries(); if (tokenN > 1) { interpretCodeLine(); if (codeBuffer.numEntries() == codePoint + 1) { incrementCode = codeBuffer[codePoint]; incrementCode.section = section; } } // remove temporary token sequence tokens.setNum(tokensRestorePoint); // remove temporary incrementation code. it has to be inserted after the loop codeBuffer.setNum(codePoint); if (lineError) return; // save instructions in block block.codeBuffer2index = codeBuffer2.push(incrementCode); codeBuffer2.push(conditionCode); block.codeBuffer2num = 2; // get next line containing '{' linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line // line must contain '{' if (tokenN != 1 || tokens[tokenB].type != TOK_OPR || tokens[tokenB].id != '{') { errors.reportLine(ERR_EXPECT_BRACKET); return; } block.startBracket = tokenB; // save block to be recalled at end bracket hllBlocks.push(block); } // Finish for-loop at end bracket void CAssembler::codeFor2() { SCode incrementCode; // code record for incrementing loop counter SCode conditionCode; // code record for conditional jump back SCode labelCode; // code record for label SBlock block = hllBlocks.pop(); // pop the stack of {} blocks if (block.continueLabel != 0xFFFFFFFF) { // place label here as jump target for continue statements zeroAllMembers(labelCode); labelCode.label = block.continueLabel; labelCode.section = section; codeBuffer.push(labelCode); } uint32_t codebuf2num = codeBuffer2.numEntries(); if (block.codeBuffer2num == 2 && block.codeBuffer2index < codebuf2num) { // retrieve prepared instruction incrementCode = codeBuffer2[block.codeBuffer2index]; conditionCode = codeBuffer2[block.codeBuffer2index+1]; // finish increment code and store it if (incrementCode.instruction) { checkCode1(incrementCode); if (lineError) return; fitCode(incrementCode); // find an instruction variant that fits if (lineError) return; codeBuffer.push(incrementCode); // save code } // finish condition code and store it // check if it can be merged with previous instruction mergeJump(conditionCode); checkCode1(conditionCode); if (lineError) return; fitCode(conditionCode); // find an instruction variant that fits if (lineError) return; codeBuffer.push(conditionCode); // save code // remove from temporary buffer if (block.codeBuffer2index + 2 == codebuf2num) { codeBuffer2.pop(); codeBuffer2.pop(); } // place label for breaking out if (block.breakLabel != 0xFFFFFFFF) { zeroAllMembers(labelCode); labelCode.label = block.breakLabel; labelCode.section = section; codeBuffer.push(labelCode); // save label } } } // Interpret for-in vector loop in assembly code // for (float v1 in [r1-r2]) {} void CAssembler::codeForIn() { uint32_t state = 0; // state while interpreting line // 0: start, 1: after type, 2: after 'for', 3: after (, 4: after (type, // 5: after vector register, 6: after 'in', 7: after '[' // 8: after base register, 9: after '-', 10: after index register // 11: after ']', 12: after ')' SBlock block; // block descriptor to save zeroAllMembers(block); // reset block.blockType = HL_FOR_IN; // 'for-in' block block.breakLabel = block.jumpLabel = block.continueLabel = 0xFFFFFFFF; block.blockNumber = ++iLoop; // number to use in labels //uint32_t baseReg; // base register uint32_t indexReg = 0; // index register uint32_t tok; // token number SToken token; // current token uint32_t type = 0; // vector element type uint32_t symi; // symbol index char name[32]; // symbol name // interpret line by state machine looping through tokens for (tok = tokenB; tok < tokenB + tokenN; tok++) { if (lineError) break; token = tokens[tok]; switch (state) { case 0: // start. expect type or 'for' if (token.type == TOK_TYP) { type = token.id & 0xFF; state = 1; } else if (token.type == TOK_HLL && token.id == HLL_FOR) { state = 2; } else errors.report(token); break; case 1: // after type. expect 'for' ('+' not allowed after type) if (token.type == TOK_HLL && token.id == HLL_FOR) { state = 2; } else errors.report(token); break; case 2: // after 'for'. expect '(' if (token.type == TOK_OPR && token.id == '(') { state = 3; } else errors.report(token); break; case 3: // after '('. expect type or vector register if (token.type == TOK_TYP && !type) { type = token.id & 0xFF; state = 4; } else if (token.type == TOK_REG) { // must be vector register if (!(token.id & REG_V)) errors.report(token.pos, token.stringLength, ERR_WRONG_REG_TYPE); state = 5; } else errors.report(token); break; case 4: // after type. expect vector register if (token.type == TOK_REG) { // must be vector register if (!(token.id & REG_V)) errors.report(token.pos, token.stringLength, ERR_WRONG_REG_TYPE); state = 5; } else errors.report(token); break; case 5: // after vector register. expect 'in' if (token.type == TOK_HLL && token.id == HLL_IN) { state = 6; } else errors.report(token); break; case 6: // after 'in'. expect '[' if (token.type == TOK_OPR && token.id == '[') { state = 7; } else errors.report(token); break; case 7: // after '['. expect base register if (token.type == TOK_REG) { // must be general purpose register if (!(token.id & REG_R)) errors.report(token.pos, token.stringLength, ERR_WRONG_REG_TYPE); //baseReg = token.id; state = 8; } else errors.report(token); break; case 8: // after base register. expect '-' if (token.type == TOK_OPR && token.id == '-') { state = 9; } else errors.report(token); break; case 9: // after '-'. expect index register if (token.type == TOK_REG) { // must be general purpose register, except r31 if (!(token.id & REG_R) || token.id == (REG_R|31)) errors.report(token.pos, token.stringLength, ERR_WRONG_REG_TYPE); indexReg = token.id; state = 10; } else errors.report(token); break; case 10: // after index register. expect ']' if (token.type == TOK_OPR && token.id == ']') { state = 11; } else errors.report(token); break; case 11: // after ']'. expect ')' if (token.type == TOK_OPR && token.id == ')') { state = 12; } else errors.report(token); break; default: errors.report(token); } } // get next line and expect '{' if (linei == lines.numEntries()-1) { // no more lines errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } linei++; tokenB = lines[linei].firstToken; // first token in line tokenN = lines[linei].numTokens; // number of tokens in line lineError = false; // expect '{' if (tokens[tokenB].id != '{') { errors.reportLine(ERR_EXPECT_BRACKET); return; } block.startBracket = tokenB; // look at preceding instruction to see if value of index register is known to be positive bool startCheckNeeded = true; SCode previousInstruction; if (codeBuffer.numEntries()) { previousInstruction = codeBuffer[codeBuffer.numEntries()-1]; // recall previous instruction if (previousInstruction.section == section && previousInstruction.instruction == II_MOVE && (previousInstruction.etype & XPR_INT) && previousInstruction.dest == indexReg && !(previousInstruction.etype & (XPR_REG1 | XPR_MEM | XPR_OPTION)) && previousInstruction.value.i > 0) { startCheckNeeded = false; } } if (startCheckNeeded) { // make label name for break sprintf(name, "@for_%u_b", iLoop); symi = makeLabelSymbol(name); block.breakLabel = symbols[symi].st_name; // label to jump back to // make conditional jump if index not positive SCode startCheck; zeroAllMembers(startCheck); startCheck.section = section; startCheck.instruction = II_COMPARE | II_JUMP_POSITIVE | II_JUMP_INVERT; startCheck.reg1 = indexReg; startCheck.sym5 = block.breakLabel; startCheck.etype = XPR_INT | XPR_REG | XPR_REG1 | XPR_JUMPOS; startCheck.line = linei; startCheck.dtype = TYP_INT64; mergeJump(startCheck); // check if it can be merged with previous instruction checkCode1(startCheck); fitCode(startCheck); // find an instruction variant that fits if (lineError) return; codeBuffer.push(startCheck); // save instruction } // make label name for loop sprintf(name, "@for_%u_a", iLoop); symi = makeLabelSymbol(name); block.jumpLabel = symbols[symi].st_name; // label to jump back to SCode labelCode; zeroAllMembers(labelCode); labelCode.section = section; labelCode.label = block.jumpLabel; codeBuffer.push(labelCode); // save label // save index registr and type in block block.codeBuffer2num = indexReg; block.codeBuffer2index = type; // save block to be recalled at '}' hllBlocks.push(block); } // Finish for-in vector loop in assembly code void CAssembler::codeForIn2() { SCode code; // code record for jump back SBlock block = hllBlocks.pop(); // pop the stack of {} blocks if (block.continueLabel != 0xFFFFFFFF) { // place label here as jump target for continue statements zeroAllMembers(code); code.label = block.continueLabel; code.section = section; codeBuffer.push(code); } // make loop instruction zeroAllMembers(code); code.section = section; code.line = linei; code.instruction = II_SUB_MAXLEN | II_JUMP_POSITIVE; code.reg1 = code.dest = block.codeBuffer2num; code.value.u = block.codeBuffer2index & 0xF; // element type in vector code.dtype = TYP_INT64; code.sym5 = block.jumpLabel; code.etype = XPR_INT | XPR_REG | XPR_REG1 | XPR_JUMPOS; // fit code and save it checkCode1(code); fitCode(code); if (lineError) return; codeBuffer.push(code); // save instruction // make break label if (block.breakLabel != 0xFFFFFFFF) { zeroAllMembers(code); code.section = section; code.label = block.breakLabel; codeBuffer.push(code); // save label } } // Interpret switch statement in assembly code void CAssembler::codeSwitch() { /* CMetaBuffer<CDynamicArray<SCcaseLabel> > caseLabels; CDynamicArray<SCode> extraCode; if (caseLabels.numEntries() == 0) caseLabels.setNum(switchNumber); */ } // Interpret switch case label in assembly code void CAssembler::codeCase() {} // Finish switch statement at end bracket void CAssembler::codeSwitch2() { } // Interpret break or continue statement in assembly code void CAssembler::codeBreak() { uint32_t symi = findBreakTarget(tokens[tokenB].id); if (symi == 0) { errors.report(tokens[tokenB].pos, tokens[tokenB].stringLength, tokens[tokenB].id == HLL_BREAK ? ERR_MISPLACED_BREAK : ERR_MISPLACED_CONTINUE); return; } // make jump to symi SCode code; zeroAllMembers(code); code.section = section; code.instruction = II_JUMP; code.etype = XPR_JUMPOS | XPR_SYM1; code.sym5 = symi; // check if it can be merged with previous instruction mergeJump(code); // finish code and save it checkCode1(code); if (lineError) return; fitCode(code); // find an instruction variant that fits if (lineError) return; codeBuffer.push(code);// save code structure } // Find or make the target symbol of a break or continue statement uint32_t CAssembler::findBreakTarget(uint32_t k) { // k is HLL_BREAK or HLL_CONTINUE int32_t blocki; // block index uint32_t symi; // symbol id bool found = false; // target found // search backwords through blocks to find the first block that can have break/continue for (blocki = (int32_t)hllBlocks.numEntries() - 1; blocki >= 0; blocki--) { switch (hllBlocks[blocki].blockType) { case HL_FOR: case HL_FOR_IN: case HL_WHILE: case HL_DO_WHILE: // can have break and continue found = true; break; case HL_SWITCH: // can have break, but not continue if (k == HLL_BREAK) found = true; break; case HL_FUNC: case HL_SECTION: // stop search and fail return 0; } if (found) break; } if (!found) return 0; // not found char prefix; // find symbol in block if (k == HLL_BREAK) { symi = hllBlocks[blocki].breakLabel; prefix = 'b'; } else { symi = hllBlocks[blocki].continueLabel; prefix = 'c'; } if (symi != 0xFFFFFFFF) return symi; // symbol has already been assigned // symbol has not been assigned yet. give it a name const char * blockName = 0; switch (hllBlocks[blocki].blockType) { case HL_FOR: case HL_FOR_IN: blockName = "for"; break; case HL_WHILE: blockName = "while"; break; case HL_DO_WHILE: blockName = "do"; break; case HL_SWITCH: blockName = "switch"; break; default: return 0; } char name[32]; sprintf(name, "@%s_%u_%c", blockName, hllBlocks[blocki].blockNumber, prefix); symi = makeLabelSymbol(name); symi = symbols[symi].st_name; // save name in block, in case it is needed again if (k == HLL_BREAK) { hllBlocks[blocki].breakLabel = symi; } else { hllBlocks[blocki].continueLabel = symi; } return symi; } // Make a symbol for branch label etc., address not known yet. Returns zero if already defined uint32_t CAssembler::makeLabelSymbol(const char * name) { ElfFWC_Sym2 sym; zeroAllMembers(sym); sym.st_type = STT_FUNC; sym.st_other = STV_HIDDEN | STV_IP; sym.st_section = section; sym.st_name = symbolNameBuffer.putStringN(name, (uint32_t)strlen(name)); uint32_t symi = addSymbol(sym); // save symbol with name if (symi == 0) { errors.reportLine(ERR_SYMBOL_DEFINED); } return symi; } // Merge jump instruction with preceding arithmetic instruction. // If successful, returns true and puts the result in code1 bool CAssembler::mergeJump(SCode & code2) { if (cmd.optiLevel == 0) return false; // merge only if optimization is on if (code2.label) return false; // cannot merge if there is a label between the two instructions if (codeBuffer.numEntries() == 0) return false; // no previous instruction to merge with SCode code1 = codeBuffer[codeBuffer.numEntries()-1]; // previous code if (code1.section != code2.section) return false; // must be in same section SCode code3 = code1 | code2; // combined code code3.reg1 = code1.reg1; code3.dest = code1.dest; uint32_t type = code1.dtype; // first instruction cannot have memory operand or other special options if (code1.etype & (XPR_MEM | XPR_SYM1 | XPR_MASK | XPR_OPTION | XPR_OPTIONS | XPR_JUMPOS | XPR_ERROR)) return false; if (!(code2.etype & XPR_JUMPOS)) return false; /*if (code2.instruction == II_JUMP) { // combine unconditional jump with add/sub if (code2.etype & (XPR_MEM | XPR_OPTION | XPR_REG)) return false; if ((code1.instruction & ~1) != II_ADD) return false; // only add and sub if (type & TYP_FLOAT) return false; // successful combination of add/sub and jump codeBuffer.pop(); // remove previous code from buffer code2 = code3; return true; } */ // second instruction must test the result of the first instruction if (code1.dest != code2.reg1) return false; // must have same operand type if ((code1.dtype & 0xF) > (code2.dtype & 0xF)) { if (!(code2.dtype & TYP_PLUS)) return false; } if ((code1.dtype & 0xF) < (code2.dtype & 0xF)) { if (!(code1.dtype & TYP_PLUS)) return false; type = code2.dtype; } type |= code2.dtype & TYP_UNS; // signed/unsigned distinction only relevant for second instruction code3.dtype = type; // check if constant bigger than 32 bits if ((type & XPR_INT) && !(type & TYP_UNS) && (code1.value.i < (int32_t)0x80000000 || code1.value.i > (int32_t)0x7FFFFFFF)) return false; if ((type & XPR_INT) && (type & TYP_UNS) && (code1.value.u > (uint64_t)0xFFFFFFFF)) return false; if ((type & XPR_FLT) && (type & 0xFF) > TYP_FLOAT32) return false; switch (code1.instruction) { case II_ADD: case II_SUB: if (type & TYP_FLOAT) return false; if (code1.instruction == II_ADD && code1.value.u == 1 && !(type & TYP_UNS)) { // check if it fits increment_compare/jump below/above code3.value.u = code2.value.u; /* uint32_t nbits = (1 << (type & 7)) * 8; // number of bits in constant if ((code2.instruction & 0xFFFE00) == II_JUMP_NEGATIVE && (code2.etype & XPR_INT) && (code3.value.u & (((uint64_t)1 << nbits) - 1)) != (uint64_t)1 << (nbits - 1)) { // check for overflow // convert jump_sbelow n to jump_sbeloweq n-1 // or jump_saboveeq n to jump sabove n-1 code3.value.u--; code3.instruction ^= II_JUMP_NEGATIVE ^ II_JUMP_POSITIVE ^ II_JUMP_INVERT; }*/ if ((code3.instruction & 0xFFFE00) == II_JUMP_POSITIVE || (code3.instruction & 0xFFFE00) == II_JUMP_NEGATIVE) { // successful combination of add 1 and jump_sbelow/above code3.instruction = (code3.instruction & 0xFFFF00) | II_INCREMENT; code3.etype = (code1.etype & ~XPR_IMMEDIATE) | code2.etype; codeBuffer.pop(); // remove previous code from buffer code2 = code3; return true; } } // add/sub + compare if (!(code2.etype & XPR_INT) || code2.value.i != 0 || (code2.instruction & 0xFF) != II_COMPARE) return false; // must compare against zero //??: if ((type & TYP_UNS) && (code3.instruction & 0xFFFE00) != II_JUMP_ZERO) return false; // unsigned works only for == and != // successful combination of add/sub and signed compare with zero code3.instruction = code1.instruction | (code2.instruction & 0xFFFF00); code3.etype = code1.etype | (code2.etype & ~(XPR_IMMEDIATE | XPR_OPTIONS)); codeBuffer.pop(); // remove previous code from buffer code2 = code3; return true; case II_AND: case II_OR: case II_XOR: //case II_SHIFT_LEFT: case II_SHIFT_RIGHT_U: // must compare for equal to zero if (!(code2.etype & XPR_INT) || code2.value.i != 0) return false; //if ((code2.instruction & 0xFFFE00) != II_JUMP_ZERO) return false; if ((code2.instruction & ~ II_JUMP_INVERT) != (II_JUMP_ZERO | II_COMPARE)) return false; // combine instruction codes code3.instruction = code1.instruction | (code2.instruction & 0xFFFF00); code3.etype = code1.etype | (code2.etype & ~XPR_IMMEDIATE); // successful combination of and/or/xor/shift and compare with zero codeBuffer.pop(); // remove previous code from buffer code2 = code3; return true; } // everything else fails return false; } // check if line contains unconditional direct jump and nothing else uint32_t CAssembler::hasJump(uint32_t line) { if (cmd.optiLevel == 0) return 0; // don't optimize jump if optimization is off if (line >= lines.numEntries()) return 0; // there is no line here uint32_t tokB = lines[line].firstToken; uint32_t tokN = lines[line].numTokens; // number of tokens in line if (tokN > 0 && tokens[tokB+tokN-1].type == TOK_OPR && tokens[tokB+tokN-1].id == ';') tokN--; // ignore ';' lineError = false; if (tokN == 1 && tokens[tokB].type == TOK_HLL) { // high level keyword if (tokens[tokB].id == HLL_BREAK || tokens[tokB].id == HLL_CONTINUE) { return findBreakTarget(tokens[tokB].id); // break or continue statement } } if (tokN == 2 && tokens[tokB].type == TOK_INS && tokens[tokB].id == II_JUMP && tokens[tokB+1].type == TOK_SYM) { // jump symbol // return tokens[tokB+1].value.w; return tokens[tokB+1].id; } return 0; // anything else } // interpret condition in if(), while(), and for(;;) statements void CAssembler::interpretCondition(SCode & code) { if ((code.instruction & 0xFF) == II_COMPARE) { // compare instruction. condition is in option bits switch ((code.optionbits >> 1) & 3) { case 0: code.instruction |= II_JUMP_ZERO; break; case 1: code.instruction |= (code.dtype & TYP_UNS) ? II_JUMP_CARRY : II_JUMP_NEGATIVE; break; case 2: code.instruction |= (code.dtype & TYP_UNS) ? II_JUMP_UABOVE : II_JUMP_POSITIVE; break; case 3: errors.reportLine(ERR_EXPECT_LOGICAL); // should not occur } if (code.optionbits & 1) code.instruction ^= II_JUMP_INVERT; // invert if bit 0 if (code.dtype & TYP_FLOAT) { // floating point. resolve ordered/unordered //if ((code.instruction & 0x7F00) == (II_JUMP_NOTZERO & 0x7F00)) code.optionbits |= 8; // a != b is unordered. This has already been done in CAssembler::op2Registers if ((code.optionbits & 8) && (code.instruction & 0x7F00) - 0x1000 < 0x2000) { code.instruction ^= II_JUMP_UNORDERED; // unordered bit } } } else if ((code.instruction & 0xFF) == II_AND && (code.etype & XPR_INT)) { // if (r1 & ) if (code.value.u != 0 && (code.value.u & (code.value.u-1)) == 0) { // n is a power of 2. test_bit code.instruction = II_TEST_BIT | II_JUMP_TRUE; code.value.u = bitScanReverse(code.value.u); } else { code.instruction = II_TEST_BITS_OR | II_JUMP_TRUE; } if (code.optionbits & 4) code.instruction ^= II_JUMP_INVERT; } else if ((code.instruction & 0xFF) == II_TEST_BITS_AND && (code.etype & XPR_INT)) { code.instruction |= II_JUMP_TRUE; if (code.optionbits & 1) code.instruction ^= II_JUMP_INVERT; } else if (code.instruction == 0 && code.etype == XPR_INT) { // constant condition. always true or always false code.instruction = II_JUMP; if (code.value.i == 0) code.instruction |= II_JUMP_INVERT; //!! code.etype = 0; } else { // unrecognized expression errors.reportLine(ERR_EXPECT_LOGICAL); code.instruction = II_JUMP; } code.optionbits = 0; } // push registers on stack void CAssembler::codePush() { uint32_t state = 0; // 0: begin, 1: after type, 2: after 'push', 3: after '(', // 4: after register 1, 5: after comma, 6: after register 2, 7: after comma, // 8: after constant, 9: after ')' int32_t reg1 = -1; // register 1, stack pointer if specified int32_t reg2 = -1; // register 2 uint32_t imm = -1; // immediate operand uint32_t ot = 3; // operand type uint32_t tok = 0; // token index SToken token; // token SCode code; // code structure zeroAllMembers(code); code.section = section; // loop through tokens on line for (tok = tokenB; tok < tokenB + tokenN; tok++) { token = tokens[tok]; if (token.type == TOK_XPR && expressions[token.value.w].etype & XPR_REG) { // this is an alias for a register. Translate to register token.type = TOK_REG; token.id = expressions[token.value.w].reg1; } switch (state) { case 0: // begin. expect type or 'push' if (token.id == HLL_PUSH) state = 2; else if (token.type == TOK_TYP) { ot = tokens[tok].id; state = 1; } else errors.report(token); break; case 1: // after type. expect 'push' if (token.id == HLL_PUSH) state = 2; else errors.report(token); break; case 2: // after 'push'. expect '(' if (token.type == TOK_OPR && token.id == '(') state = 3; else errors.report(token); break; case 3: // after '('. expect register if (token.type != TOK_REG) { errors.report(token); return; } state = 4; reg1 = token.id; break; case 4: // after register. expect ',' or ')' if (token.type == TOK_OPR && token.id == ',') state = 5; else if (token.type == TOK_OPR && token.id == ')') state = 9; else errors.report(token); break; case 5: // after comma. expect register or constant if (token.type == TOK_REG) { reg2 = token.id; state = 6; } else if (token.type == TOK_NUM || token.type == TOK_SYM) { imm = expression(tok, 1, 0).value.w; state = 8; } else errors.report(token); break; case 6: // after second register. expect comma or ')' if (token.type == TOK_OPR && token.id == ',') state = 7; else if (token.type == TOK_OPR && token.id == ')') state = 9; else errors.report(token); break; case 7: // after second comma. expect constant if (token.type == TOK_NUM || token.type == TOK_SYM) { imm = expression(tok, 1, 0).value.w; state = 8; } else errors.report(token); break; case 8: // after constant. expect ')' if (token.type == TOK_OPR && token.id == ')') state = 9; else errors.report(token); break; default: // after ')'. expect nothing errors.report(token); break; } } if (state != 9) { errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } if (reg2 == -1) { // stack pointer not specified. use default stack pointer reg2 = reg1; reg1 = 0x1F | REG_R; } if (int32_t(imm) == -1) { // no immediate operand. push only one register imm = reg2 & 0x1F; } if ((imm & 0x1F) < uint32_t(reg2 & 0x1F)) { errors.reportLine(ERR_OPERANDS_WRONG_ORDER); return; } if (!(reg1 & REG_R)) { errors.reportLine(ERR_WRONG_OPERANDS); return; } if ((reg2 & REG_V) && (imm & 0x80)) { errors.reportLine(ERR_WRONG_OPERANDS); return; } code.instruction = II_PUSH; code.dest = reg1; code.reg1 = reg2; code.value.u = imm; code.etype = XPR_INT | XPR_REG | XPR_REG1; code.dtype = TYP_INT8 | (ot & 0xF); checkCode1(code); fitCode(code); if (lineError) return; codeBuffer.push(code); // save code } // pop register from stack void CAssembler::codePop() { uint32_t state = 0; // 0: begin, 1: after type, 2: after 'push', 3: after '(', // 4: after register 1, 5: after comma, 6: after register 2, 7: after comma, // 8: after constant, 9: after ')' int32_t reg1 = -1; // register 1, stack pointer if specified int32_t reg2 = -1; // register 2 uint32_t imm = -1; // immediate operand uint32_t ot = 3; // operand type uint32_t tok = 0; // token index SToken token; // token SCode code; // code structure zeroAllMembers(code); code.section = section; // loop through tokens on line for (tok = tokenB; tok < tokenB + tokenN; tok++) { token = tokens[tok]; if (token.type == TOK_XPR && expressions[token.value.w].etype & XPR_REG) { // this is an alias for a register. Translate to register token.type = TOK_REG; token.id = expressions[token.value.w].reg1; } switch (state) { case 0: // begin. expect type or 'push' if (token.id == HLL_POP) state = 2; else if (token.type == TOK_TYP) { ot = tokens[tok].id; state = 1; } else errors.report(token); break; case 1: // after type. expect 'push' if (token.id == HLL_POP) state = 2; else errors.report(token); break; case 2: // after 'push'. expect '(' if (token.type == TOK_OPR && token.id == '(') state = 3; else errors.report(token); break; case 3: // after '('. expect register if (token.type != TOK_REG) { errors.report(token); return; } state = 4; reg1 = token.id; break; case 4: // after register. expect ',' or ')' if (token.type == TOK_OPR && token.id == ',') state = 5; else if (token.type == TOK_OPR && token.id == ')') state = 9; else errors.report(token); break; case 5: // after comma. expect register or constant if (token.type == TOK_REG) { reg2 = token.id; state = 6; } else if (token.type == TOK_NUM || token.type == TOK_SYM) { imm = expression(tok, 1, 0).value.w; state = 8; } else errors.report(token); break; case 6: // after second register. expect comma or ')' if (token.type == TOK_OPR && token.id == ',') state = 7; else if (token.type == TOK_OPR && token.id == ')') state = 9; else errors.report(token); break; case 7: // after second comma. expect constant if (token.type == TOK_NUM || token.type == TOK_SYM) { imm = expression(tok, 1, 0).value.w; state = 8; } else errors.report(token); break; case 8: // after constant. expect ')' if (token.type == TOK_OPR && token.id == ')') state = 9; else errors.report(token); break; default: // after ')'. expect nothing errors.report(token); break; } } if (state != 9) { errors.reportLine(ERR_UNFINISHED_INSTRUCTION); return; } if (reg2 == -1) { // stack pointer not specified. use default stack pointer reg2 = reg1; reg1 = 0x1F | REG_R; } if (int32_t(imm) == -1) { // no immediate operand. push only one register imm = reg2 & 0x1F; } if ((imm & 0x1F) < uint32_t(reg2 & 0x1F)) { errors.reportLine(ERR_OPERANDS_WRONG_ORDER); return; } if (!(reg1 & REG_R)) { errors.reportLine(ERR_WRONG_OPERANDS); return; } if ((reg2 & REG_V) && (imm & 0x80)) { errors.reportLine(ERR_WRONG_OPERANDS); return; } code.instruction = II_POP; code.dest = reg1; code.reg1 = reg2; code.value.u = imm; code.etype = XPR_INT | XPR_REG | XPR_REG1; code.dtype = TYP_INT8 | (ot & 0xF); checkCode1(code); fitCode(code); if (lineError) return; codeBuffer.push(code); // save code }
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