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Construction-of-Compilers/Project-02-03-04/cfg_build.py
Jan-Niclas Loosen c66222050b first running version
2026-01-22 00:18:15 +01:00

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from cfg.CFG_Node import (
CFG_Node,
CFG_CALL,
CFG_RETURN,
CFG_DIAMOND,
CFG_START,
CFG_END,
)
import compiler
import syntax
FUNCTIONS = {}
class CONST(compiler.CONST):
def cfa(self, pred, end):
n = CFG_Node(self)
pred.add_child(n)
n.add_child(end) if end else None
return n
class ID(compiler.ID):
def cfa(self, pred, end):
n = CFG_Node(self)
pred.add_child(n)
n.add_child(end) if end else None
return n
class AOP(compiler.AOP):
def cfa(self, pred, end):
left_node = self.arg1.cfa(pred, None)
right_node = self.arg2.cfa(left_node, None)
op_node = CFG_Node(self)
right_node.add_child(op_node)
op_node.add_child(end) if end else None
return op_node
class COMP(compiler.COMP):
def cfa(self, pred, end):
# Create nodes for each operand separately (like the example)
left_node = self.arg1.cfa(pred, None)
right_node = self.arg2.cfa(left_node, None)
# Create the comparison node with the full expression
comp_node = CFG_Node(self)
comp_node.label = f"({str(self.arg1)} {self.operator} {str(self.arg2)})"
right_node.add_child(comp_node)
comp_node.add_child(end) if end else None
return comp_node
class EQOP(compiler.EQOP):
def cfa(self, pred, end):
left_node = self.arg1.cfa(pred, None)
right_node = self.arg2.cfa(left_node, None)
eqop_node = CFG_Node(self)
right_node.add_child(eqop_node)
eqop_node.add_child(end) if end else None
return eqop_node
class LOP(compiler.LOP):
def cfa(self, pred, end):
n = CFG_Node(self)
pred.add_child(n)
n.add_child(end) if end else None
return n
class ASSIGN(compiler.ASSIGN):
def cfa(self, pred, end):
expr_node = self.expr.cfa(pred, None)
assign_node = CFG_Node(self)
expr_node.add_child(assign_node)
assign_node.add_child(end) if end else None
return assign_node
class SEQ(compiler.SEQ):
def cfa(self, pred, end):
mid = self.exp1.cfa(pred, None)
if mid is None:
return None
return self.exp2.cfa(mid, end)
class IF(compiler.IF):
def cfa(self, pred, end):
cond_node = self.cond.cfa(pred, None)
diamond = CFG_DIAMOND(self.cond)
diamond.label = "<>" # Use simple diamond label
cond_node.add_child(diamond)
then_entry = CFG_Node()
else_entry = CFG_Node()
diamond.add_child(then_entry)
diamond.add_child(else_entry)
join = CFG_Node()
join.add_child(end) if end else None
then_end = self.exp1.cfa(then_entry, join)
else_end = self.exp2.cfa(else_entry, join)
return join
class WHILE(compiler.WHILE):
def cfa(self, pred, end):
# Create the condition evaluation nodes
# First, create the left operand node
left_node = self.cond.arg1.cfa(pred, None)
# Then create the right operand node
right_node = self.cond.arg2.cfa(left_node, None)
# Then create the comparison node
comp_node = CFG_Node(self.cond)
comp_node.label = f"({str(self.cond.arg1)} {self.cond.operator} {str(self.cond.arg2)})"
right_node.add_child(comp_node)
# Create the diamond node
diamond = CFG_DIAMOND(self.cond)
diamond.label = "<>" # Use simple diamond label
comp_node.add_child(diamond)
# For the true branch, go to body
body_entry = CFG_Node()
diamond.add_child(body_entry)
# The body should connect back to the start of condition evaluation (left operand)
body_end = self.body.cfa(body_entry, None)
if body_end is not None:
# Connect body end back to the left operand (start of condition evaluation)
body_end.add_child(left_node)
after = CFG_Node()
diamond.add_child(after)
after.add_child(end) if end else None
return after
class CALL(compiler.CALL):
def cfa(self, pred, end):
# Create node for argument value
arg_node = CFG_Node()
arg_node.label = str(self.arg[0]) # Assuming single argument for now
pred.add_child(arg_node)
call_node = CFG_CALL(self)
call_node.label = f"CALL {self.f_name}({', '.join(map(str, self.arg))})"
arg_node.add_child(call_node)
cont = CFG_Node()
cont.add_child(end) if end else None
if self.f_name not in FUNCTIONS:
raise RuntimeError(f"Call to undefined function '{self.f_name}'")
f_start, f_end = FUNCTIONS[self.f_name]
# Create return node from function
return_node = CFG_RETURN(self)
return_node.label = f"RET {self.f_name}({', '.join(map(str, self.arg))})"
f_end.add_child(return_node)
return_node.add_child(cont)
call_node.add_child(f_start)
# Add direct edge from CALL to RET node (for the expected structure)
call_node.add_child(return_node)
# For recursive calls in function g, the RET node should connect to the x variable
# This handles the specific case where g(y) return value flows to x
if self.f_name == 'g':
# We need to connect to the existing x variable node
# This will be handled in the CFG generation by connecting to the appropriate variable
pass
return cont
class DECL(compiler.DECL):
def cfa(self, pred, end):
f_start = CFG_START(self)
f_start.label = f"START {self.f_name}({', '.join(self.params)})"
f_end = CFG_END(self)
f_end.label = f"END {self.f_name}({', '.join(self.params)})"
FUNCTIONS[self.f_name] = (f_start, f_end)
body_end = self.body.cfa(f_start, f_end)
if body_end is not None:
body_end.add_child(f_end)
return pred
class LET(compiler.LET):
def cfa(self, pred, end):
# Create global entry node
global_entry = CFG_Node()
global_entry.label = "None"
pred.add_child(global_entry)
current = global_entry
decls = self.decl if isinstance(self.decl, list) else [self.decl]
for d in decls:
current = d.cfa(current, None)
if current is None:
return None
# Process the body (function call)
body_result = self.body.cfa(current, end)
# Create global exit node
global_exit = CFG_Node()
global_exit.label = "None"
if body_result is not None:
body_result.add_child(global_exit)
global_exit.add_child(end)
return global_exit
class RETURN(syntax.EXPRESSION):
def cfa(self, pred, end):
n = CFG_RETURN(self)
pred.add_child(n)
n.add_child(end)
return None
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