def tocode(self):
flatname = util.toFlatname(self.name)
scope = self.getScope(self.name)
code = ''
if self.isTopmodule(scope):
if signaltype.isInput(self.termtype): code += 'input '
elif signaltype.isInout(self.termtype): code += 'inout '
elif signaltype.isOutput(self.termtype): code += 'output '
else:
if signaltype.isInput(self.termtype): code += 'wire '
elif signaltype.isInout(self.termtype): code += 'wire '
elif signaltype.isOutput(self.termtype) and not signaltype.isReg(self.termtype): code += 'wire '
if signaltype.isReg(self.termtype): code += 'reg '
if signaltype.isRegArray(self.termtype): code += 'reg '
if signaltype.isWire(self.termtype): code += 'wire '
if signaltype.isWireArray(self.termtype): code += 'wire '
if signaltype.isInteger(self.termtype): code += 'integer '
if signaltype.isFunction(self.termtype): code += 'wire '
if signaltype.isRename(self.termtype): code += 'wire '
if (not signaltype.isInteger(self.termtype) and
self.msb is not None and self.lsb is not None):
code += '[' + self.msb.tocode(None) + ':' + self.lsb.tocode(None) + '] '
code += flatname # signal name
if self.lenmsb is not None and self.lenlsb is not None:
code += ' [' + self.lenmsb.tocode() + ':' + self.lenlsb.tocode(flatname) + ']'
code += ';\n'
return code
def getAssignType(self, termname, bind):
termtype = self.getTermtype(termname)
if signaltype.isWire(termtype):
return 'assign'
if signaltype.isWireArray(termtype):
return 'assign'
if signaltype.isReg(termtype):
if bind.isClockEdge(): return 'clockedge'
return 'combination'
if signaltype.isRegArray(termtype):
if bind.isClockEdge(): return 'clockedge'
return 'combination'
if signaltype.isInteger(termtype):
if bind.isClockEdge(): return 'clockedge'
return 'combination'
if signaltype.isParameter(termtype):
return 'parameter'
if signaltype.isLocalparam(termtype):
return 'localparam'
if signaltype.isOutput(termtype):
return 'assign'
if signaltype.isInput(termtype):
return 'assign'
if signaltype.isFunction(termtype):
return 'assign'
if signaltype.isRename(termtype):
return 'assign'
if signaltype.isGenvar(termtype):
return 'genvar'
raise verror.DefinitionError('Unexpected Assignment Type: %s : %s' % (str(termname), str(termtype)))
def getAssignType(self, termname, bind):
termtype = self.getTermtype(termname)
if signaltype.isWire(termtype):
return 'assign'
if signaltype.isWireArray(termtype):
return 'assign'
if signaltype.isReg(termtype):
if bind.isClockEdge(): return 'clockedge'
return 'combination'
if signaltype.isRegArray(termtype):
if bind.isClockEdge(): return 'clockedge'
return 'combination'
if signaltype.isInteger(termtype):
if bind.isClockEdge(): return 'clockedge'
return 'combination'
if signaltype.isParameter(termtype):
return 'parameter'
if signaltype.isLocalparam(termtype):
return 'localparam'
if signaltype.isOutput(termtype):
return 'assign'
if signaltype.isInput(termtype):
return 'assign'
if signaltype.isFunction(termtype):
return 'assign'
if signaltype.isRename(termtype):
return 'assign'
if signaltype.isGenvar(termtype):
return 'genvar'
raise verror.DefinitionError('Unexpected Assignment Type: %s : %s' %
(str(termname), str(termtype)))
def createSignalList(analyzer, designterm_list, idx, sigdiffScope_Ref0,
sigStr_Type):
instances = analyzer.getInstances()
print('Instance: ')
for module, instname in sorted(instances, key=lambda x: str(x[1])):
print((module, instname))
term = analyzer.getTerms()
#designterm_list[idx] = term
designterm_list.append(term)
#calculate the bitnum
for tk, tv in term.items():
tv.bitwidth = tv.msb.eval() - tv.lsb.eval() + 1
#print(tv.bitwidth, tk)
if idx > 0:
#check the diff in port no. between signals, the bitwidth in design0 is set as ref :D
for tk, tv in term.items():
preterm = designterm_list[idx - 1][tk]
#if the bitwidth is the same, you still need to check if any of the previous signal is diff
if preterm.bitwidth == tv.bitwidth:
if tk in sigdiffScope_Ref0:
sigdiffScope_Ref0[tk][idx] = sigdiffScope_Ref0[tk][idx - 1]
else:
if tk in sigdiffScope_Ref0:
sigdiffScope_Ref0[tk][idx] = tv.bitwidth - (
preterm.bitwidth - sigdiffScope_Ref0[tk][idx - 1])
else:
for i in xrange(0, idx):
if i == 0:
sigdiffScope_Ref0[tk] = []
#sigdiffScope_Ref0[tk][i] = preterm.bitwidth
sigdiffScope_Ref0[tk].append(preterm.bitwidth)
else:
#sigdiffScope_Ref0[tk][i] = 0
sigdiffScope_Ref0[tk].append(0)
sigdiffScope_Ref0[tk].append(tv.bitwidth -
preterm.bitwidth)
sigStr_Type[str(tk)] = copy.deepcopy(tv.termtype)
if signaltype.isReg(sigStr_Type[str(tk)]):
sigStr_Type[str(tk)].remove('Reg')
print('Term:')
for tk, tv in term.items():
print(tk, tv.tostr())
print(' ')
def walkTree(self,
tree,
visited=set([]),
step=0,
delay=False,
msb=None,
lsb=None,
ptr=None):
if tree is None:
return DFUndefined(32)
if isinstance(tree, DFUndefined):
return tree
if isinstance(tree, DFHighImpedance):
return tree
if isinstance(tree, DFConstant):
return tree
if isinstance(tree, DFEvalValue):
return tree
if isinstance(tree, DFTerminal):
scope = util.getScope(tree.name)
termname = tree.name
if termname in visited: return tree
termtype = self.getTermtype(termname)
if util.isTopmodule(scope) and signaltype.isInput(termtype):
return tree
nptr = None
if signaltype.isRegArray(termtype) or signaltype.isWireArray(
termtype):
if ptr is None:
raise verror.FormatError(
'Array variable requires an pointer.')
if msb is not None and lsb is not None: return tree
nptr = ptr
nextstep = step
if signaltype.isReg(termtype) or signaltype.isRegArray(termtype):
if (not self.isCombination(termname)
and not signaltype.isRename(termtype)
and nextstep == 0):
return tree
if (not self.isCombination(termname)
and not signaltype.isRename(termtype)):
nextstep -= 1
return self.walkTree(self.getTree(termname, nptr), visited | set([
termname,
]), nextstep, delay)
if isinstance(tree, DFBranch):
condnode = self.walkTree(tree.condnode, visited, step, delay)
truenode = self.walkTree(tree.truenode, visited, step, delay)
falsenode = self.walkTree(tree.falsenode, visited, step, delay)
return DFBranch(condnode, truenode, falsenode)
if isinstance(tree, DFOperator):
nextnodes = []
for n in tree.nextnodes:
nextnodes.append(self.walkTree(n, visited, step, delay))
return DFOperator(tuple(nextnodes), tree.operator)
if isinstance(tree, DFPartselect):
msb = self.walkTree(tree.msb, visited, step, delay)
lsb = self.walkTree(tree.lsb, visited, step, delay)
var = self.walkTree(tree.var,
visited,
step,
delay,
msb=msb,
lsb=lsb)
return DFPartselect(var, msb, lsb)
if isinstance(tree, DFPointer):
ptr = self.walkTree(tree.ptr, visited, step, delay)
var = self.walkTree(tree.var, visited, step, delay, ptr=ptr)
if isinstance(tree.var, DFTerminal):
termtype = self.getTermtype(tree.var.name)
if ((signaltype.isRegArray(termtype)
or signaltype.isWireArray(termtype))
and not (isinstance(var, DFTerminal)
and var.name == tree.var.name)):
return var
return DFPointer(var, ptr)
if isinstance(tree, DFConcat):
nextnodes = []
for n in tree.nextnodes:
nextnodes.append(self.walkTree(n, visited, step, delay))
return DFConcat(tuple(nextnodes))
raise verror.DefinitionError('Undefined Node Type: %s : %s' %
(str(type(tree)), str(tree)))
def walkTree(self, tree, visited=set([]), step=0, delay=False, msb=None, lsb=None, ptr=None):
if tree is None:
return DFUndefined(32)
if isinstance(tree, DFUndefined):
return tree
if isinstance(tree, DFHighImpedance):
return tree
if isinstance(tree, DFConstant):
return tree
if isinstance(tree, DFEvalValue):
return tree
if isinstance(tree, DFTerminal):
scope = util.getScope(tree.name)
termname = tree.name
if termname in visited:
return tree
termtype = self.getTermtype(termname)
if util.isTopmodule(scope) and signaltype.isInput(termtype):
return tree
nptr = None
if signaltype.isRegArray(termtype) or signaltype.isWireArray(termtype):
if ptr is None:
raise verror.FormatError("Array variable requires an pointer.")
if msb is not None and lsb is not None:
return tree
nptr = ptr
nextstep = step
if signaltype.isReg(termtype) or signaltype.isRegArray(termtype):
if not self.isCombination(termname) and not signaltype.isRename(termtype) and nextstep == 0:
return tree
if not self.isCombination(termname) and not signaltype.isRename(termtype):
nextstep -= 1
return self.walkTree(self.getTree(termname, nptr), visited | set([termname]), nextstep, delay)
if isinstance(tree, DFBranch):
condnode = self.walkTree(tree.condnode, visited, step, delay)
truenode = self.walkTree(tree.truenode, visited, step, delay)
falsenode = self.walkTree(tree.falsenode, visited, step, delay)
return DFBranch(condnode, truenode, falsenode)
if isinstance(tree, DFOperator):
nextnodes = []
for n in tree.nextnodes:
nextnodes.append(self.walkTree(n, visited, step, delay))
return DFOperator(tuple(nextnodes), tree.operator)
if isinstance(tree, DFPartselect):
msb = self.walkTree(tree.msb, visited, step, delay)
lsb = self.walkTree(tree.lsb, visited, step, delay)
var = self.walkTree(tree.var, visited, step, delay, msb=msb, lsb=lsb)
if isinstance(var, DFPartselect):
child_lsb = self.getTerm(str(tree.var)).lsb.eval()
return DFPartselect(
var.var,
DFIntConst(str(msb.eval() + var.lsb.eval() - child_lsb)),
DFIntConst(str(lsb.eval() + var.lsb.eval() - child_lsb)),
)
return DFPartselect(var, msb, lsb)
if isinstance(tree, DFPointer):
ptr = self.walkTree(tree.ptr, visited, step, delay)
var = self.walkTree(tree.var, visited, step, delay, ptr=ptr)
if isinstance(tree.var, DFTerminal):
termtype = self.getTermtype(tree.var.name)
if (signaltype.isRegArray(termtype) or signaltype.isWireArray(termtype)) and not (
isinstance(var, DFTerminal) and var.name == tree.var.name
):
return var
return DFPointer(var, ptr)
if isinstance(tree, DFConcat):
nextnodes = []
for n in tree.nextnodes:
nextnodes.append(self.walkTree(n, visited, step, delay))
return DFConcat(tuple(nextnodes))
raise verror.DefinitionError("Undefined Node Type: %s : %s" % (str(type(tree)), str(tree)))
