def binaryOperation(operation, reg1, reg2, outputReg, props):
resultLines = []
standardComment = utils.formatComment('{} = {} {} {}'.format(outputReg, reg1, operation, reg2), props, 2)
operationComment = utils.formatComment('{} {} {}'.format(reg1, '/' if operation == '%' else operation, reg2), props, 2)
if reg1 == '0': reg1 = '$0'
if reg2 == '0': reg2 = '$0'
reg1 = utils.getRegister(reg1)
reg2 = utils.getRegister(reg2)
didChangeReg1 = False
if (not operation in BIN_OPERATORS_IMM and utils.isIntOrChar(reg1)) or (utils.isIntOrChar(reg1) and utils.isIntOrChar(reg2)):
tempReg = utils.getTempRegister(props['tempRegisters'], 0)
resultLines.append(general.loadIntOrChar(reg1, tempReg, props))
reg1 = tempReg
didChangeReg1 = True
if not operation in BIN_OPERATORS_IMM and utils.isIntOrChar(reg2):
tempReg = utils.getTempRegister(props['tempRegisters'], 1 if didChangeReg1 else 0)
resultLines.append(general.loadIntOrChar(reg2, tempReg, props))
reg2 = tempReg
# Using 2 registers
if utils.isRegister(reg1) and utils.isRegister(reg2):
if operation in BIN_RESULT_REGS:
# Move from hi/lo
resultLines.append('{} {}, {}{}'.format(BIN_OPERATORS[operation], reg1, reg2, operationComment))
resultLines.append(general.loadRegHiLo(BIN_RESULT_REGS[operation], outputReg, {**props, 'comment': standardComment}))
else:
resultLines.append('{} {}, {}, {}{}'.format(BIN_OPERATORS[operation], utils.getRegister(outputReg), reg1, reg2, standardComment))
else:
# Immediate
regNum, number = (reg1, utils.getIntOrChar(reg2)) if utils.isRegister(reg1) else (reg2, utils.getIntOrChar(reg1))
resultLines.append('{} {}, {}, {}{}'.format(BIN_OPERATORS_IMM[operation], utils.getRegister(outputReg), regNum, number, standardComment))
return { 'lines': resultLines, 'reg': outputReg }
def loadFromAddress(address, loadType, outputReg, props, outerInner=None):
numLoadFuncs = {
'int': 'lw',
'short': 'lh',
'byte': 'lb',
'char': 'lb',
'number': 'lw',
'address': 'lw'
}
loadFunc = 'lw'
if definitions.getSupertype(loadType) == 'address': loadType = 'address'
if loadType in numLoadFuncs: loadFunc = numLoadFuncs[loadType]
if utils.isRegister(address):
raise utils.CompileException('Can\'t load directly from register')
if outerInner == None:
comment = utils.formatComment('{} = {}'.format(outputReg, address),
props, 2)
else:
comment = utils.formatComment(
'{} = {}[{}]'.format(outputReg, outerInner[0], outerInner[1]),
props, 2)
return '{} {}, {}{}'.format(loadFunc, utils.getRegister(outputReg),
address, comment)
def parseAssignment(line, props):
resultLines = []
lhs, rhs = [s.strip() for s in line.split('=')]
if utils.isRegister(lhs):
reg = lhs.split(' as ')[0].strip() if ' as ' in lhs else lhs
parsedRHS = expressions.parseRHS(rhs, props, reg)
resultLines += parsedRHS['lines']
else:
inferredType = expressions.parseLHS(lhs, props)['type']
parsedRHS = expressions.parseRHS(rhs, props, 'any', inferredType)
resultLines += parsedRHS['lines']
resultType = parsedRHS['type']
limitedProps = utils.propsWithTempRegExcl(props, [parsedRHS['reg']])
parsedLHS = expressions.parseLHS(lhs, limitedProps)
resultLines += parsedLHS['lines']
resultType = definitions.updateType(resultType, parsedLHS['elemtype'])
resultLines.append(
general.storeToAddress(parsedLHS['address'], resultType,
parsedRHS['reg'], props))
lastLine = resultLines[-1]
if '#' in lastLine:
lastLine = lastLine[:lastLine.index('#')].strip()
resultLines[-1] = lastLine + utils.formatComment(line, props)
return resultLines
def loadAsAddress(address, outputReg, props, outerInner=None):
if utils.isRegister(address):
raise utils.CompileException('Can\'t load register as address')
if outerInner == None:
comment = utils.formatComment(
'{} = address of {}'.format(outputReg, address), props, 2)
else:
comment = utils.formatComment(
'{} = address of {}[{}]'.format(outputReg, outerInner[0],
outerInner[1]), props, 2)
return '{} {}, {}{}'.format('la', utils.getRegister(outputReg), address,
comment)
def storeToAddress(address, storeType, outputReg, props):
if utils.isRegister(address):
raise utils.CompileException('Can\'t store to register')
numStoreFuncs = {
'int': 'sw',
'short': 'sh',
'byte': 'sb',
'char': 'sb',
'number': 'sw'
}
storeFunc = 'sw'
if storeType in definitions.NUM_TYPES: storeFunc = numStoreFuncs[storeType]
comment = utils.formatComment('{} = {}'.format(address, outputReg), props,
2)
return '{} {}, {}{}'.format(storeFunc, utils.getRegister(outputReg),
address, comment)
def parseRHS(expression, props, outputReg='any', inferredType='any'):
# Convert the expression to postfix (RPN) notation
splitExp = parser.infixToPostfix(parser.splitExpression(expression))
allTempRegs = props['tempRegisters']
resultLines = []
resultAddr = None
# Parse the expression as a stack of operations
equationStack = []
typeStack = []
asAddressStack = []
availableTempRegIdx = 0
for i, item in enumerate(splitExp):
val1, val2 = item, None
val1Type, val2Type = inferredType, inferredType
val1AsAddress, val2AsAddress = False, False
val1Addr, val2Addr = None, None # Haven't optimized address addition yet
reg1, reg2 = None, None
limitedProps = utils.propsWithTempRegOffset(props, availableTempRegIdx)
finalIteration = i == len(splitExp) - 1 or (
i == len(splitExp) - 3 and
(splitExp[-1] == 'as' or splitExp[-1] == 'addressof'))
targetReg = utils.getTempRegister(limitedProps['tempRegisters'], 0)
if finalIteration:
if utils.isSysFunc(item) and outputReg == 'any': targetReg = '$v0'
elif outputReg == 'any':
targetReg = utils.getTempRegister(allTempRegs, 0)
else:
targetReg = outputReg
prevTempReg = None if availableTempRegIdx < 1 else utils.getTempRegister(
allTempRegs, availableTempRegIdx - 1)
prevPrevTempReg = None if availableTempRegIdx < 2 else utils.getTempRegister(
allTempRegs, availableTempRegIdx - 2)
if item in operations.BIN_OPERATORS or item == 'as':
val1, val2 = equationStack[-2], equationStack[-1]
val1Type, val2Type = typeStack[-2], typeStack[-1]
val1AsAddress, val2AsAddress = asAddressStack[-2], asAddressStack[
-1]
elif item in operations.UN_OPERATORS or item == 'addressof':
val1, val1Type, val1AsAddress = equationStack[-1], typeStack[
-1], asAddressStack[-1]
# Special operators
if item == 'as':
equationStack.pop()
asAddressStack.pop()
typeStack.pop()
typeStack.pop()
typeStack.append(val2)
val1, val1Type, val1AsAddress = equationStack[-1], typeStack[
-1], asAddressStack[-1]
elif item == 'addressof':
asAddressStack.pop()
asAddressStack.append(True)
val1, val1Type, val1AsAddress = equationStack[-1], typeStack[
-1], asAddressStack[-1]
else:
# Get first register
if item in operations.BIN_OPERATORS or item in operations.UN_OPERATORS:
if utils.isIntOrChar(val1): reg1 = val1
else:
if utils.isRegister(val1): reg1 = val1
else: reg1 = targetReg
parsed = parseSingleRHS(val1, limitedProps, reg1, val1Type,
val1AsAddress)
resultLines += parsed['lines']
val1Type, val1Addr = parsed['type'], parsed['address']
if not utils.isRegister(val1):
limitedProps = utils.propsWithTempRegOffset(
limitedProps, 1)
# Get Second register
if item in operations.BIN_OPERATORS:
if utils.isIntOrChar(val2): reg2 = val2
else:
if utils.isRegister(val2): reg2 = val2
elif reg1 == targetReg:
reg2 = utils.getTempRegister(
limitedProps['tempRegisters'], 0)
else:
reg2 = targetReg
parsed = parseSingleRHS(val2, limitedProps, reg2, val2Type,
val2AsAddress)
resultLines += parsed['lines']
val2Type, val2Addr = parsed['type'], parsed['address']
if not utils.isRegister(val2):
limitedProps = utils.propsWithTempRegOffset(
limitedProps, 1)
# Do binary operation
if item in operations.BIN_OPERATORS:
# Try to re-use/free-up temporary registers where possible
equationReg = targetReg
if utils.isTempRegister(equationReg, allTempRegs):
if val1 == prevPrevTempReg: equationReg = val1
elif val2 == prevTempReg: equationReg = val2
else: availableTempRegIdx += 1
if val1 == prevPrevTempReg and val2 == prevTempReg:
# Suggested Optimization: Even though it frees up a register, it doesn't
# keep track of the value inside it. This could potentially prevent
# the same value from being re-loaded.
availableTempRegIdx -= 1
# Parse the operation
parsedOperation = operations.binaryOperation(
item, reg1, reg2, equationReg, limitedProps)
resultLines += parsedOperation['lines']
equationStack.pop()
equationStack.pop()
typeStack.pop()
typeStack.pop()
asAddressStack.pop()
asAddressStack.pop()
equationStack.append(parsedOperation['reg'])
typeStack.append(definitions.mergeType(val1Type, val2Type))
asAddressStack.append(False)
# Do unary operation
elif item in operations.UN_OPERATORS:
# Try to re-use/free-up temporary registers where possible
equationReg = targetReg
if utils.isTempRegister(equationReg, allTempRegs):
if val1 == prevTempReg: equationReg = val1
else: availableTempRegIdx += 1
# Parse the operation
parsedOperation = operations.unaryOperation(
item, reg1, equationReg, limitedProps)
resultLines += parsedOperation['lines']
equationStack.pop()
typeStack.pop()
asAddressStack.pop()
equationStack.append(parsedOperation['reg'])
typeStack.append(val1Type)
asAddressStack.append(False)
# Handle expressions without operators
elif i == len(splitExp) - 1:
if outputReg == 'any':
if val1 == '0': val1 = '$0'
if utils.isRegister(val1): targetReg = val1
parsed = parseSingleRHS(val1, limitedProps, targetReg, val1Type,
val1AsAddress)
resultLines += parsed['lines']
val1Type, val1Addr = parsed['type'], parsed['address']
resultAddr = val1Addr
equationStack.append(targetReg)
typeStack.append(val1Type)
asAddressStack.append(False)
# Add to stack
elif item != 'as' and item != 'of':
equationStack.append(item)
if utils.isInt(item): typeStack.append('number')
elif utils.isChar(item): typeStack.append('char')
else: typeStack.append('any')
asAddressStack.append(False)
return {
'lines': resultLines,
'type': typeStack[-1],
'reg': equationStack[-1],
'address': resultAddr
}
def parseSingleRHS(expression,
props,
outputReg,
inferredType='any',
loadAsAddress=False):
resultLines = []
resultAddr = None
resultType = inferredType
if loadAsAddress and (utils.isRegister(expression)
or utils.isSysFunc(expression)):
raise utils.CompileException('Can\'t get address of register')
# System functions
if utils.isSysFunc(expression):
resultLines += functions.parseSysFunc(expression, props, True)
resultType = definitions.updateType(resultType, 'number')
if outputReg != '$v0':
resultLines.append(general.loadRegister('$v0', outputReg, props))
# Array
elif addresses.isArray(expression):
parsedAddr = addresses.parseArray(expression, props, outputReg)
outerInner = (parsedAddr['outer'], parsedAddr['inner'])
resultLines += parsedAddr['lines']
if loadAsAddress:
resultType = definitions.updateType('address', resultType)
if parsedAddr['reg'] != outputReg:
resultLines.append(
general.loadAsAddress(parsedAddr['address'], outputReg,
props, outerInner))
if parsedAddr['reg'] == None: resultAddr = parsedAddr['address']
else:
loadType = definitions.updateType(resultType,
parsedAddr['elemtype'])
resultLines.append(
general.loadFromAddress(parsedAddr['address'], loadType,
outputReg, props, outerInner))
resultType = definitions.updateType(loadType, resultType)
# Register
elif utils.isRegister(expression):
if general.isRegHiLo(expression):
resultLines.append(
general.loadRegHiLo(expression, outputReg, props))
elif utils.getRegister(expression) != utils.getRegister(outputReg):
resultLines.append(
general.loadRegister(expression, outputReg, props))
# Variable
elif expression in props['variables']:
varName, varType = props['variables'][expression]['name'], props[
'variables'][expression]['type']
if definitions.getSupertype(varType) == 'address' or loadAsAddress:
resultLines.append(general.loadAsAddress(varName, outputReg,
props))
resultType = definitions.updateType(varType, resultType)
resultAddr = varName
else:
resultLines.append(
general.loadFromAddress(varName, varType, outputReg, props))
resultType = definitions.updateType(varType, resultType)
# Integer or char literal
elif utils.isIntOrChar(expression):
resultType = definitions.updateType(
resultType, 'char' if utils.isChar(expression) else 'number')
resultLines.append(general.loadIntOrChar(expression, outputReg, props))
# Address
elif addresses.isAddress(expression, props):
resultType = definitions.updateType('address', resultType)
if definitions.getSupertype(resultType) == 'address':
resultLines.append(
general.loadAsAddress(expression, outputReg, props))
else:
resultLines.append(
general.loadFromAddress(expression, resultType, outputReg,
props))
resultAddr = expression
return {
'lines': resultLines,
'type': resultType,
'reg': outputReg,
'address': resultAddr
}
def parseArray(expression, props, addressReg='any'):
resultLines = []
resultReg = None
resultType = 'address'
elemType = 'any'
resultAddress = 'none'
outer, inner = None, None
outerAddr = expression[:expression.index('[')]
innerExpr = expression[expression.index('[') + 1:-1].strip()
if outerAddr in props['variables'] and 'elemtype' in props['variables'][
outerAddr]:
resultType = definitions.updateType(
props['variables'][outerAddr]['type'], 'address')
if 'elemtype' in props['variables'][outerAddr]:
elemType = props['variables'][outerAddr]['elemtype']
# Optimize offset literals
if utils.isIntOrChar(innerExpr):
value = utils.getIntOrChar(innerExpr)
if utils.isRegister(outerAddr):
if value == 0:
resultAddress = '({})'.format(utils.getRegister(outerAddr))
else:
resultAddress = '{}({})'.format(value,
utils.getRegister(outerAddr))
else:
if value == 0: resultAddress = outerAddr
else: resultAddress = '{}+{}'.format(outerAddr, value)
outer, inner = outerAddr, value
else:
# Parse inner expression
exprReg = None
if utils.isRegister(innerExpr): exprReg = innerExpr
else:
parsedExpr = expressions.parseRHS(innerExpr, props, 'any',
'number')
resultLines += parsedExpr['lines']
exprReg = parsedExpr['reg']
limitedProps = utils.propsWithTempRegExcl(props, [exprReg])
resultReg = addressReg
if resultReg is 'any' or resultReg == exprReg:
resultReg = utils.getTempRegister(limitedProps['tempRegisters'], 0)
newAddress = outerAddr
if utils.isRegister(outerAddr):
newAddress = '({})'.format(utils.getRegister(outerAddr))
resultLines.append(
general.loadAsAddress(newAddress, resultReg, props,
(outerAddr, '0')))
addOperation = operations.binaryOperation('+', resultReg, exprReg,
resultReg, limitedProps)
resultLines += addOperation['lines']
resultAddress = '({})'.format(utils.getRegister(resultReg))
outer, inner = resultReg, '0'
return {
'lines': resultLines,
'type': resultType,
'elemtype': elemType,
'reg': resultReg,
'address': resultAddress,
'outer': outer,
'inner': inner
}
def parseGotoConditional(line, props):
resultLines = []
gotoFunc = line.split()[0]
branchOperators = ['==', '!=', '<', '<=', '>', '>=']
branchFuncs = {
'==': 'beq',
'!=': 'bne',
'<': 'blt',
'<=': 'ble',
'>': 'bgt',
'>=': 'bge'
}
branchFuncsWith0 = {'<': 'bltz', '<=': 'blez', '>': 'bgtz', '>=': 'bgez'}
branchFuncsWith0Link = {'<': 'bltzal', '>=': 'bgezal'}
condition = line.split(' if ')[1].strip()
location = line.split(' if ')[0][len(gotoFunc):].strip()
address = expressions.parseRHS(location, props, 'any',
'address')['address']
if address == None:
raise utils.CompileException('Direct label is required')
conditionLeft, conditionRight, conditionOperator = '', '', None
splitCondition = parser.splitExpression(condition)
rpnCondition = parser.infixToPostfix(splitCondition)
if rpnCondition[-1] not in branchOperators:
conditionLeft = '({})'.format(condition)
conditionRight = '0'
conditionOperator = '>'
else:
splitIdxCondition = [(item, idx)
for idx, item in enumerate(splitCondition)]
rpnIdxCondition = parser.infixToPostfix(splitIdxCondition,
lambda item: item[0])
conditionOperator = rpnIdxCondition[-1][0]
operatorIdx = rpnIdxCondition[-1][1]
conditionLeft = ' '.join(splitCondition[:operatorIdx])
conditionRight = ' '.join(splitCondition[operatorIdx + 1:])
branchFunc = branchFuncs[conditionOperator]
singleParam = False
reg1, reg2 = 'any', 'any'
if utils.isRegister(conditionLeft):
reg1 = utils.getRegister(conditionLeft)
else:
parsed = expressions.parseRHS(conditionLeft, props, 'any', 'number')
resultLines += parsed['lines']
reg1 = parsed['reg']
limitedProps = utils.propsWithTempRegExcl(props, [reg1])
if gotoFunc == 'gotolink':
if conditionRight == '0' and conditionOperator in branchFuncsWith0Link:
branchFunc = branchFuncsWith0Link[conditionOperator]
singleParam = True
else:
raise utils.CompileException(
'Conditional gotolink only supports < 0 and >= 0 conditions')
elif conditionRight == '0' and conditionOperator in branchFuncsWith0:
branchFunc = branchFuncsWith0[conditionOperator]
singleParam = True
elif utils.isRegister(conditionRight):
reg2 = utils.getRegister(conditionRight)
else:
parsed = expressions.parseRHS(conditionRight, limitedProps, 'any',
'number')
resultLines += parsed['lines']
reg2 = parsed['reg']
comment = utils.formatComment(line, props)
if singleParam:
resultLines.append('{} {}, {}{}'.format(branchFunc, reg1, address,
comment))
else:
resultLines.append('{} {}, {}, {}{}'.format(branchFunc, reg1, reg2,
address, comment))
return resultLines
