def detect_extended_for_loops(self):
for_indices = []
for_stack = Stack()
with open("/opt/lampp/htdocs/Blog/post views/view_post_image_phpcode.php", "r") as source_file:
code = source_file.read()
source = code.replace("\n", " ")
# for_start_indices = [(w.start(0), w.end(0)) for w in re.finditer("while\s*\((.*?)\s*:", source)]
for_start_indices = [f.start(0) for f in re.finditer("for\s*\((.*?)\s*:", source)]
end_start_indices = [e.start(0) for e in re.finditer("endfor;", source)]
for f_index in for_start_indices:
for_indices.append(f_index)
for e_index in end_start_indices:
for_indices.append(e_index)
for_indices.sort(reverse=False)
for idx in for_indices:
if idx in for_start_indices:
for_stack.push(idx)
elif idx in end_start_indices:
if for_stack.size() == 1:
while_start = for_stack.pop()
file = source[while_start:idx]
print(file)
else:
for_stack.pop()
def forward_singlePath(self, modulelist, input, name):
stack = Stack()
k = 0
temp = []
for layers in modulelist:
# use the pop-pull logic, looks like a stack
if k == 0:
temp = layers(input)
else:
# met a pooling layer, take its input
if isinstance(layers, nn.AvgPool2d) or isinstance(
layers, nn.MaxPool2d):
stack.push(temp)
temp = layers(temp)
# met a unpooling layer, take its output
if isinstance(layers, nn.Upsample):
if name == 'offset':
temp = torch.cat(
(temp, stack.pop()), dim=1
) # short cut here, but optical flow should concat instead of add
else:
temp += stack.pop(
) # short cut here, but optical flow should concat instead of add
k += 1
return temp
class HamiltonChecker:
def __init__(self, graph):
self.hamiltonian_flag = False
self.graph = graph
self.visited = [False] * (len(graph.graph_representation) + 1)
self.stack = Stack()
self.hamiltonianPath = []
def check_hamilton(self, vertex):
if not self.hamiltonian_flag:
self.stack.push(vertex)
self.visited[vertex] = True
if self.stack.size() < len(self.graph.graph_representation):
for neighbour in self.graph.graph_representation[vertex]:
if self.visited[neighbour] == False:
self.check_hamilton(neighbour)
if self.stack.size() < len(self.graph.graph_representation):
self.visited[self.stack.pop()] = False
else:
if self.stack.bottom(
) in self.graph.graph_representation[vertex]:
self.hamiltonian_flag = True
self.stack.push(self.stack.bottom())
self.hamiltonianPath = self.stack.getListFromStack()
else:
self.visited[self.stack.pop()] = False
def is_hamiltionian(self):
return (self.hamiltonian_flag, self.hamiltonianPath)
def reset(self):
self.hamiltonian_flag = False
self.visited = [False] * len(graph.graph_representation)
self.stack = Stack()
self.hamiltonianPath = []
def unixpath(self, path: str) -> str:
pathlist = path.split("/")
stack = Stack()
for p in pathlist:
if p != "." and p != "..":
stack.push(p)
if p == "..":
stack.pop()
return "/".join(stack.toList())
def zigzag_level(self, root):
if root is None:
return
curLevel = Stack()
nextLevel = Stack()
curLevel.push(root)
ltr = True # left to right for level 1
while not curLevel.isEmpty():
temp = curLevel.pop()
print(temp.val, end=" ")
if ltr: # left to right
if temp.left:
nextLevel.push(temp.left)
if temp.right:
nextLevel.push(temp.right)
else: # right to left
if temp.right:
nextLevel.push(temp.right)
if temp.left:
nextLevel.push(temp.left)
if curLevel.isEmpty():
ltr = not ltr
curLevel, nextLevel = nextLevel, curLevel
print()
def get_navigation_files_details(self, file_list):
indices = []
ul_stack = Stack()
navigation_files_details = []
for file in file_list:
with open(file, "r") as source_file:
original_src = source_file.read().replace("\n", " ")
original_src = original_src.replace("\t", "")
ul_start_indices = [
w.start(0) for w in re.finditer("<ul", original_src)
]
ul_end_indices = [
e.end(0) for e in re.finditer("</ul>", original_src)
]
for ul_s_index in ul_start_indices:
indices.append(ul_s_index)
for ul_e_index in ul_end_indices:
indices.append(ul_e_index)
ul_segments = []
if indices.__len__() > 0:
indices.sort(reverse=False)
for idx in indices:
if idx in ul_start_indices:
ul_stack.push(idx)
elif idx in ul_end_indices:
if ul_stack.size() == 1:
ul_start = ul_stack.pop()
ul_segments.append(original_src[ul_start:idx])
else:
ul_stack.pop()
# ul_lists = re.findall("<ul(.*?)<\/ul>", original_src)
if ul_segments.__len__() > 0:
navigation_details = []
for ul_segment in ul_segments:
navigators = re.findall("<li>(.*?)</li>", ul_segment)
for nav in navigators:
navigation_details.append(nav)
if navigation_details.__len__() > 0:
navigator = NavigationDO()
navigator.set_nav_file_name(file)
navigator.set_navigations(navigation_details)
navigation_files_details.append(navigator)
return navigation_files_details
def detect_extended_while_loops(self, source, file_name):
indices = []
while_stack = Stack()
dir_maker = FilesDirectoryMaker()
target_php_base = "/home/shan/Developments/Projects/research-devs/python-devs/filehandler/phpSnippets"
# --below commented code is to demonstrate the program from a single file
# with open("/opt/lampp/htdocs/Blog/post views/view_post_image_phpcode.php", "r") as source_file:
# code = source_file.read()
# source = code.replace("\n", " ")
# --
# for_start_indices = [(w.start(0), w.end(0)) for w in re.finditer("while\s*\((.*?)\s*:", source)]
while_start_indices = [w.start(0) for w in re.finditer("while\s*\((.*?)\s*:", source)]
end_start_indices = [e.end(0) for e in re.finditer("endwhile;", source)]
for w_index in while_start_indices:
indices.append(w_index)
for e_index in end_start_indices:
indices.append(e_index)
# --while loop iterator
i = 0
if indices.__len__() > 0:
indices.sort(reverse=False)
for idx in indices:
if idx in while_start_indices:
while_stack.push(idx)
elif idx in end_start_indices:
if while_stack.size() == 1:
i = i + 1
while_start = while_stack.pop()
while_file = source[while_start:idx]
edited_while_file = while_file.replace(">", ">\n")
dir_path = target_php_base + "/" + file_name
dir_maker.create_target_directory(dir_path)
while_file_path = dir_path + "/while_loop_" + i.__str__() + ".php"
with open(while_file_path, "w") as file:
file.write("<?php\n" + edited_while_file + "\n?>")
source = source.replace(while_file, "include \"" + while_file_path + "\";")
else:
while_stack.pop()
return source
def isValid(self, s: str) -> bool:
mapping = {')': '(', '}': '{', ']': '['}
stack = Stack()
for char in s:
if char in mapping:
top = stack.pop() if len(stack) != 0 else '#'
if mapping[char] != top:
return False
else:
stack.push(char)
return len(stack) == 0
# cpp solution
# class Solution {
# public:
# bool isValid(string s) {
# stack<char> stack;
# for(auto c : s) {
# if(c == '(' || c == '{' || c == '[') {
# stack.push(c);
# }
# else if(!stack.empty() &&
# ((c == ')' && stack.top() == '(')
# || (c == '}' && stack.top() == '{')
# || (c == ']' && stack.top() == '['))) {
# stack.pop();
# }
# else {
# return false;
# }
# }
# return stack.empty();
# }
# };
class IdleInterRepr:
def __init__(self):
self.__temporals = Temporal()
self.__operands_stack = Stack()
self.__operators_stack = Stack()
self.__quads = []
self.__temp_quads = []
self.__jump_stack = Stack()
self.__func_calls_stack = Stack()
self.__param_counter_stack = Stack()
@property
def quads(self):
return self.__quads
def constant_quads(self):
const_quads = []
for const_dict in CompilationMemory.CONSTANTS.values():
for name, var in const_dict.items():
const_quads.append(
(OperationCode.ASSIGN, name, None, var.address))
return const_quads
def get_last_var(self):
"""Returns top of operands stack. Expects to be called only when calling function or variable within object."""
return self.__operands_stack.pop()
def add_goto_main(self):
self.quads.append((OperationCode.GOTO, None, None, None))
def set_main(self, main_func: Func):
start = list(self.__quads[0])
start[3] = main_func.func_start
self.__quads[0] = tuple(start)
def add_var(self, var):
self.__operands_stack.push(var)
def add_access_instance_var(self, class_ref: Variable, obj_var: Variable):
temp = self.__temporals.next(obj_var.var_type)
self.__quads.append((OperationCode.ASSIGN, class_ref.address,
obj_var.address, temp.address))
self.__operands_stack.push(temp)
def array_access(self, var):
index_var = self.__operands_stack.pop()
if index_var.var_type != DataType.INT:
return False
result = self.__temporals.next(DataType.POINTER)
result.make_pointer(var.array_type)
self.__quads.append((OperationCode.ARRINDEXCHECK.to_code(), 0,
var.array_size - 1, index_var.address))
self.__quads.append((OperationCode.ARRACCESS.to_code(), var.address,
index_var.address, result.address))
self.__operands_stack.push(result)
self.__temporals.free_up_if_temp(index_var)
return True
def array_sort(self, var, direction):
self.__quads.append((OperationCode.ARRSORT.to_code(),
(0, var.array_size), direction, var.address))
def array_find(self, var):
oper = self.__operands_stack.pop()
result = self.__temporals.next(DataType.INT)
if oper.var_type != var.array_type:
return False
self.__quads.append(
(OperationCode.ARRFIND.to_code(), (0, var.array_size),
(oper.address, var.address), result.address))
self.__operands_stack.push(result)
temp_func = Func('temp')
temp_func.return_type = DataType.INT
self.__func_calls_stack.push(temp_func)
return True
def add_operator(self, operator):
self.__operators_stack.push(OperationCode(operator))
def __resolve_oper(self) -> bool:
right_oper = self.__operands_stack.pop()
left_oper = self.__operands_stack.pop()
operator = self.__operators_stack.pop()
result_type = SemanticCube.check(operator, left_oper.var_type,
right_oper.var_type)
if result_type == DataType.ERROR:
return False
result = self.__temporals.next(result_type)
self.__quads.append((operator.to_code(), left_oper.address,
right_oper.address, result.address))
self.__operands_stack.push(result)
self.__temporals.free_up_if_temp(left_oper)
self.__temporals.free_up_if_temp(right_oper)
return True
def check_addsub(self) -> bool:
if OperationCode.is_add_sub(self.__operators_stack.peek()):
return self.__resolve_oper()
return True
def check_divmult(self) -> bool:
if OperationCode.is_div_mult(self.__operators_stack.peek()):
return self.__resolve_oper()
return True
def check_relop(self) -> bool:
if OperationCode.is_relop(self.__operators_stack.peek()):
return self.__resolve_oper()
return True
def open_parenthesis(self):
self.__operators_stack.push(OperationCode.FAKEBOTTOM)
def close_parenthesis(self):
self.__operators_stack.pop()
def assign(self) -> bool:
oper = self.__operands_stack.pop()
var = self.__operands_stack.pop()
if oper.var_type != var.var_type:
return False
self.__temporals.free_up_if_temp(oper)
self.__quads.append(
(OperationCode.ASSIGN.to_code(), oper.address, None, var.address))
return True
def short_var_decl_assign(self) -> DataType:
oper = self.__operands_stack.pop()
var = self.__operands_stack.pop()
self.__temporals.free_up_if_temp(oper)
self.__quads.append(
(OperationCode.ASSIGN.to_code(), oper.address, None, var.address))
return oper.var_type
def read(self, read_type):
result = self.__temporals.next(read_type)
if read_type == DataType.INT:
self.__quads.append(
(OperationCode.READINT.to_code(), None, None, result.address))
if read_type == DataType.FLOAT:
self.__quads.append((OperationCode.READFLOAT.to_code(), None, None,
result.address))
if read_type == DataType.STRING:
self.__quads.append((OperationCode.READSTRING.to_code(), None,
None, result.address))
self.__operands_stack.push(result)
temp_func = Func('temp')
temp_func.return_type = read_type
self.__func_calls_stack.push(temp_func)
def to_string(self):
oper = self.__operands_stack.pop()
result = self.__temporals.next(DataType.STRING)
self.__quads.append((OperationCode.TOSTRING.to_code(), oper.address,
None, result.address))
self.__operands_stack.push(result)
temp_func = Func('temp')
temp_func.return_type = DataType.STRING
self.__func_calls_stack.push(temp_func)
def print_st(self):
oper = self.__operands_stack.pop()
self.__quads.append(
(OperationCode.PRINT.to_code(), oper.address, None, None))
def start_while(self):
self.__jump_stack.push(len(self.__quads))
def end_while_expr(self) -> bool:
expr_result = self.__operands_stack.pop()
if expr_result.var_type != DataType.BOOL:
return False
self.__quads.append(
(OperationCode.GOTOF.to_code(), expr_result.address, None, None))
self.__jump_stack.push(len(self.__quads) - 1)
return True
def end_while(self):
expr_end = self.__jump_stack.pop()
while_start = self.__jump_stack.pop()
# Add GOTO to loop back to while start
self.__quads.append(
(OperationCode.GOTO.to_code(), None, None, while_start))
# Update GOTOF jump address after expression
if expr_end:
expr_end_quad = list(self.__quads[expr_end])
expr_end_quad[3] = len(self.__quads)
self.__quads[expr_end] = tuple(expr_end_quad)
def start_for_assign(self):
# Save current quad list into temporal space and reset quads
self.__temp_quads = self.__quads
self.__quads = []
def end_for_assign(self):
# Switch quad list with the temporal quads generated from the for assignment
quads = self.__temp_quads
self.__temp_quads = self.__quads
self.__quads = quads
def end_for_block(self):
# Add temporal quads from assignment to end of block
self.__quads.extend(self.__temp_quads)
def end_if_expr(self) -> bool:
expr_result = self.__operands_stack.pop()
if expr_result.var_type != DataType.BOOL:
return False
self.__quads.append(
(OperationCode.GOTOF.to_code(), expr_result.address, None, None))
false_jumps = Stack()
false_jumps.push(len(self.__quads) - 1)
self.__jump_stack.push(false_jumps)
return True
def fill_if_end_jumps(self):
fill_jumps = self.__jump_stack.pop()
while not fill_jumps.isEmpty():
expr_end = fill_jumps.pop()
# Update GOTOF jump address after expression
expr_end_quad = list(self.__quads[expr_end])
expr_end_quad[3] = len(self.__quads)
self.__quads[expr_end] = tuple(expr_end_quad)
def start_else_ifs(self):
goto_end_jumps = Stack()
goto_false_jumps = self.__jump_stack.pop()
self.__jump_stack.push(goto_end_jumps)
self.__jump_stack.push(goto_false_jumps)
def add_else(self):
self.__quads.append((OperationCode.GOTO.to_code(), None, None, None))
false_jumps = self.__jump_stack.pop()
false_jump = false_jumps.pop()
# Add quad to stack of quads that should jump to the end of if
goto_end_jumps = self.__jump_stack.pop()
goto_end_jumps.push(len(self.__quads) - 1)
self.__jump_stack.push(goto_end_jumps)
# Update GOTOF jump address from previous if / else if
expr_false_jump = list(self.__quads[false_jump])
expr_false_jump[3] = len(self.__quads)
self.__quads[false_jump] = tuple(expr_false_jump)
def add_func_era(self, func_called: Func, obj_var: Variable = None):
if obj_var != None:
# If call belongs to object, add object reference to change instance contexts
self.__quads.append((OperationCode.ERA, func_called.func_start,
obj_var.address, None))
elif func_called.name == func_called.return_type:
temp = self.__temporals.next(func_called.return_type)
self.__quads.append((OperationCode.ERA, func_called.func_start,
temp.address, None))
self.__operands_stack.push(temp)
elif func_called.name == "__default_constructor__":
temp = self.__temporals.next(func_called.return_type)
self.__operands_stack.push(temp)
else:
self.__quads.append(
(OperationCode.ERA, func_called.func_start, None, None))
self.__func_calls_stack.push(func_called)
self.__param_counter_stack.push(0)
def add_func_param(self):
func_called = self.__func_calls_stack.peek()
origin_var = self.__operands_stack.pop()
param_counter = self.__param_counter_stack.pop()
self.__param_counter_stack.push(param_counter + 1)
# More arguments given than requested
if param_counter >= len(func_called.arguments):
return (True, None
) # Ignore, later will be caught on add_func_gosub
# Check parameter type matching
destination_var = func_called.arguments[param_counter]
if origin_var.var_type != destination_var.var_type:
return (False, destination_var.address, destination_var.var_type)
if destination_var.is_param_by_ref:
self.__quads.append((OperationCode.PARAMREF, origin_var.address,
None, destination_var.address))
else:
self.__quads.append((OperationCode.PARAM, origin_var.address, None,
destination_var.address))
return (True, None)
def add_func_gosub(self):
func_called = self.__func_calls_stack.peek()
if func_called:
if func_called.name != "__default_constructor__": # Ignore default constructor
# If function has return value, save return in temporal
if func_called.return_type != None:
if func_called.return_type == func_called.name: # Constructor call
self.__quads.append(
(OperationCode.GOSUB, func_called.name, None,
self.__operands_stack.peek().address))
else:
result = self.__temporals.next(func_called.return_type)
self.__quads.append(
(OperationCode.GOSUB, func_called.name, None,
result.address))
self.__operands_stack.push(result)
else:
self.__quads.append(
(OperationCode.GOSUB, func_called.name, None, None))
# Check number of parameters
param_counter = self.__param_counter_stack.pop()
if param_counter != len(func_called.arguments):
return (False, func_called.name, len(func_called.arguments),
param_counter)
return (True, None)
def check_not_void(self, check: bool):
func_called = self.__func_calls_stack.pop()
if check and func_called.return_type == None:
return False
return True
def add_empty_return(self):
self.__quads.append((OperationCode.ENDPROC, None, None, None))
def add_func_return(self, expected_return_type: DataType) -> bool:
return_val = None
return_type = None
if not self.__operands_stack.isEmpty():
return_var = self.__operands_stack.pop()
return_val = return_var.address
return_type = return_var.var_type
if expected_return_type != None:
# Quad appended even on error to avoid also reporting 'missing return statement' on add_endproc
self.__quads.append((OperationCode.RETURN, return_val, None, None))
if return_type != expected_return_type:
return False
return True
def add_endproc(self, current_func: Func) -> bool:
self.__quads.append((OperationCode.ENDPROC, None, None, None))
self.__temporals = Temporal()
# Assumes last quad should be return statement
if current_func.return_type != None:
if current_func.return_type != current_func.name: # Not a constructor
try:
if self.__quads[-2][0] != OperationCode.RETURN:
return False
except IndexError: # Happens when method is blank
return False
return True
class IdleVirtualMachine():
def __init__(self, const_quadruples, quadruples, debug=False):
self.__const_quadruples = const_quadruples
self.__quadruples = quadruples
self.__memory_stack = Stack()
self.__next_class_stack = Stack()
self.__debug = debug
curr_class = ClassMemory()
curr_class.era_func(self.__quadruples[0][3])
curr_class.goto_next_func()
self.__memory_stack.push(curr_class)
if self.__debug:
for i in range(0, (len(self.__quadruples))):
print(i, self.__quadruples[i])
@property
def current_memory(self):
return self.__memory_stack.peek()
def run(self):
"""
Executes all of the quads generated during compilation.
"""
instruction_set = {
OperationCode.GOTO: self.run_goto,
OperationCode.GOTOF: self.run_gotof,
OperationCode.GOTOT: self.run_gotot,
OperationCode.ASSIGN: self.run_assign,
OperationCode.ERA: self.run_era,
OperationCode.PARAM: self.run_param,
OperationCode.PARAMREF: self.run_paramref,
OperationCode.GOSUB: self.run_gosub,
OperationCode.RETURN: self.run_return,
OperationCode.ENDPROC: self.run_endproc,
OperationCode.ADD: self.run_add,
OperationCode.SUB: self.run_sub,
OperationCode.MULT: self.run_mult,
OperationCode.DIV: self.run_div,
OperationCode.GT: self.run_gt,
OperationCode.LT: self.run_lt,
OperationCode.GE: self.run_ge,
OperationCode.LE: self.run_le,
OperationCode.EQUAL: self.run_equal,
OperationCode.NOTEQUAL: self.run_not_equal,
OperationCode.AND: self.run_and,
OperationCode.OR: self.run_or,
OperationCode.PRINT: self.run_print,
OperationCode.READFLOAT: self.run_read_float,
OperationCode.READINT: self.run_read_int,
OperationCode.READSTRING: self.run_read_string,
OperationCode.TOSTRING: self.run_to_string,
OperationCode.ARRACCESS: self.run_arr_access,
OperationCode.ARRINDEXCHECK: self.run_arr_index_check,
OperationCode.ARRSORT: self.run_arr_sort,
OperationCode.ARRFIND: self.run_arr_find
}
# Add variables for constants to memory
self.init_consts()
# Execute all quads
next_quad = self.next_instruction()
while next_quad != None:
instruction = instruction_set[OperationCode(next_quad[0])]
instruction(next_quad)
if self.__debug:
print("===== EXECUTED: " + str(next_quad) + " =========")
print(self.current_memory)
next_quad = self.next_instruction()
def init_consts(self):
temp = Memory()
for quad in self.__const_quadruples:
temp.set_value(quad[1], quad[3])
def next_instruction(self):
"""
Gets the next instruction from memory.
"""
counter = self.current_memory.next_instruction()
if counter != None:
return self.__quadruples[counter]
elif self.__memory_stack.size() > 1:
self.__memory_stack.pop()
return self.next_instruction()
return None
# INSTRUCTION SET FUNCTIONS
def run_goto(self, quad):
self.current_memory.goto(quad[3])
def run_gotof(self, quad):
op1 = self.current_memory.get_value(quad[1])
if not op1:
self.current_memory.goto(quad[3])
def run_gotot(self, quad):
op1 = self.current_memory.get_value(quad[1])
if op1:
self.current_memory.goto(quad[3])
def run_assign(self, quad):
if quad[2] == None: # Regular access
value = self.current_memory.get_value(quad[1])
self.current_memory.set_value(value, quad[3])
else: # Instance var access
obj_instance = self.current_memory.get_value(quad[1])
ref = obj_instance.get_reference(quad[2])
self.current_memory.set_reference(ref, quad[3])
def run_era(self, quad):
if quad[2] != None:
obj = self.current_memory.get_value(quad[2])
obj.era_func(quad[1])
self.__next_class_stack.push(obj)
else:
self.current_memory.era_func(quad[1])
def run_param(self, quad):
value = self.current_memory.get_value(quad[1])
if not self.__next_class_stack.isEmpty():
self.__next_class_stack.peek().send_param(value, quad[3])
else:
self.current_memory.send_param(value, quad[3])
def run_paramref(self, quad):
reference = self.current_memory.get_reference(quad[1])
if not self.__next_class_stack.isEmpty():
self.__next_class_stack.peek().send_param_by_ref(
reference, quad[3])
else:
self.current_memory.send_param_by_ref(reference, quad[3])
def run_gosub(self, quad):
if not self.__next_class_stack.isEmpty():
self.__memory_stack.push(self.__next_class_stack.pop())
self.current_memory.goto_next_func()
def run_return(self, quad):
value = self.current_memory.get_value(quad[1])
# If there is another function in stack, it means it will return to that function within class
if self.current_memory.can_return():
counter = self.current_memory.prev_func_last_instruction()
address = self.__quadruples[counter][3]
self.current_memory.return_value(value, address)
else: # Return of object function call
prev_class = self.__memory_stack.peek_next_to_last()
counter = prev_class.curr_func_last_instruction()
address = self.__quadruples[counter][3]
prev_class.set_value(value, address)
self.run_endproc()
def run_endproc(self, quad=None):
self.current_memory.end_func()
def run_add(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 + op2, quad[3])
def run_sub(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 - op2, quad[3])
def run_mult(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 * op2, quad[3])
def run_div(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
if op2 == 0:
print("Runtime Error: Division by 0.")
exit()
if isinstance(op1, int) and isinstance(op2, int):
self.current_memory.set_value(op1 // op2, quad[3])
else:
self.current_memory.set_value(op1 / op2, quad[3])
def run_gt(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 > op2, quad[3])
def run_lt(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 < op2, quad[3])
def run_equal(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 == op2, quad[3])
def run_ge(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 >= op2, quad[3])
def run_le(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 <= op2, quad[3])
def run_not_equal(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 != op2, quad[3])
def run_and(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 and op2, quad[3])
def run_or(self, quad):
op1 = self.current_memory.get_value(quad[1])
op2 = self.current_memory.get_value(quad[2])
self.current_memory.set_value(op1 or op2, quad[3])
def run_print(self, quad):
op1 = self.current_memory.get_value(quad[1])
if isinstance(op1, bool):
op1 = str(op1).lower()
print(op1)
def run_read_float(self, quad):
op1 = input()
try:
op1 = float(op1)
except ValueError:
print("Runtime Error: Expected float.")
exit()
self.current_memory.set_value(op1, quad[3])
def run_read_int(self, quad):
op1 = input()
try:
op1 = int(op1)
except ValueError:
print("Runtime Error: Expected int.")
exit()
self.current_memory.set_value(op1, quad[3])
def run_read_string(self, quad):
op1 = str(input())
self.current_memory.set_value(op1, quad[3])
def run_to_string(self, quad):
value = self.current_memory.get_value(quad[1])
string_value = str(value)
self.current_memory.set_value(string_value, quad[3])
def run_arr_access(self, quad):
base_address = quad[1]
arr_index = self.current_memory.get_value(quad[2])
address = base_address + arr_index * 100
# RUNTIME ERROR index out of bounds
self.current_memory.set_pointer_address(quad[3], address)
def run_arr_index_check(self, quad):
lower_limit = quad[1]
upper_limit = quad[2]
index = self.current_memory.get_value(quad[3])
if index < lower_limit or index > upper_limit:
print("Runtime Error: Array index out of bounds.")
exit()
def run_arr_sort(self, quad):
base_address = quad[3]
start_address = base_address + quad[1][0] * 100
end_address = base_address + quad[1][1] * 100
array = self.current_memory.get_memory_slice(start_address,
end_address)
array.sort()
if quad[2] == "desc":
array.reverse()
self.current_memory.set_memory_slice(array, start_address, end_address)
def run_arr_find(self, quad):
base_address = quad[2][1]
start_address = base_address + quad[1][0] * 100
end_address = base_address + quad[1][1] * 100
value = self.current_memory.get_value(quad[2][0])
array = self.current_memory.get_memory_slice(start_address,
end_address)
value_index = -1
for index, item in enumerate(array):
if item == value:
value_index = index
break
self.current_memory.set_value(value_index, quad[3])
class ClassMemory(Memory):
def __init__(self):
super().__init__()
self.__func_memory_stack = Stack()
self.__next_func = Stack()
def set_reference(self, reference, address):
if self.get_type(address) == DataType.POINTER:
actual_address = self.__func_memory_stack.peek().get_value(address)
self.set_reference(reference, actual_address)
elif address % 10 == CompilationMemory.INSTANCE_ID:
super().set_reference(reference, address)
else:
self.__func_memory_stack.peek().set_reference(reference, address)
def get_reference(self, address):
if self.get_type(address) == DataType.POINTER:
actual_address = self.__func_memory_stack.peek().get_value(address)
return self.get_reference(actual_address)
elif address % 10 == CompilationMemory.INSTANCE_ID:
return super().get_reference(address)
else:
return self.__func_memory_stack.peek().get_reference(address)
def set_value(self, value, address):
if self.get_type(address) == DataType.POINTER:
actual_address = self.__func_memory_stack.peek().get_value(address)
self.set_value(value, actual_address)
elif address % 10 == CompilationMemory.INSTANCE_ID:
super().set_value(value, address)
else:
self.__func_memory_stack.peek().set_value(value, address)
def get_value(self, address):
if self.get_type(address) == DataType.POINTER:
actual_address = self.__func_memory_stack.peek().get_value(address)
return self.get_value(actual_address)
if address % 10 == CompilationMemory.INSTANCE_ID:
return super().get_value(address)
else:
return self.__func_memory_stack.peek().get_value(address)
def set_pointer_address(self, pointer_address, pointing_address):
self.__func_memory_stack.peek().set_value(pointing_address, pointer_address)
def era_func(self, func_start):
self.__next_func.push(LocalMemory(func_start))
def send_param(self, value, address):
self.__next_func.peek().set_value(value, address)
def send_param_by_ref(self, reference, address):
self.__next_func.peek().set_reference(reference, address)
def can_return(self):
return self.__func_memory_stack.size() > 1
def curr_func_last_instruction(self):
return self.__func_memory_stack.peek().last_instruction
def prev_func_last_instruction(self):
return self.__func_memory_stack.peek_next_to_last().last_instruction
def return_value(self, value, address):
self.__func_memory_stack.peek_next_to_last().set_value(value, address)
def goto_next_func(self):
self.__func_memory_stack.push(self.__next_func.pop())
def end_func(self):
self.__func_memory_stack.pop()
def next_instruction(self):
if self.__func_memory_stack.peek() != None:
return self.__func_memory_stack.peek().next_instruction()
return None
def goto(self, counter):
self.__func_memory_stack.peek().goto(counter)
def __str__(self):
representation = "----------------------\n"
representation += "CLASS MEMORY:\n"
representation += super().__str__() + "\n"
representation += "\nFUNCTION MEMORY:\n"
for fnc in self.__func_memory_stack.items:
representation += fnc.__str__() + "\n"
representation += "\nNEXT FUNCTIONS:\n"
for fnc in self.__next_func.items:
representation += fnc.__str__() + "\n"
representation += "CONSTANTS:\n"
representation += self.CONSTANTS.__str__() + "\n"
representation += "----------------------\n"
return representation
class nintVM:
"""docstring for nintVM"""
def __init__(self, filename: str):
super().__init__()
self.ip = 0 # Instruction pointer
self.quads = []
self.ConstTable = dict()
# Memcounts
self._memcount_temp = 0
self._memcount_global = 0
self._returns_value = False
self._newstack = None
self.load_data(filename)
self._total_quads = len(self.quads)
assert self._memcount_global != 0 and self._memcount_temp != 0, "No data read for global or temp counts from bytecode"
if debug_mode == 'debug':
debug("========== QUADS ===========")
for quad in self.quads:
debug(quad)
debug()
debug()
# TODO: Create memory sections here
self.Temp = Memory(self._memcount_temp)
self._GlobalMemory = Memory(self._memcount_global)
self.CallStack = Stack() # Local memory
self.CallStack.push(self._GlobalMemory)
# Instruction set
self.nintIS = {
# Arithmetic
Operator.ASSIGN: self.assign,
Operator.ADD: self.add,
Operator.SUB: self.sub,
Operator.MULT: self.mult,
Operator.DIV: self.div,
# Relops
Operator.GT: self.gt,
Operator.GTE: self.gte,
Operator.LT: self.lt,
Operator.LTE: self.lte,
Operator.EQUAL: self.equals,
Operator.NEQ: self.neq,
# Boolean comparisons
Operator.AND: self.bool_and,
Operator.OR: self.bool_or,
# GOTOs
Operator.GOTO: self.goto,
Operator.GOTOF: self.gotoF,
Operator.GOTOV: self.gotoV,
# Functions
Operator.GOSUB: self.gosub,
Operator.PARAM: self.param,
Operator.ERA: self.expand_active_record,
Operator.ENDPROC: self.endproc,
Operator.RETURN: self.return_proc,
Operator.PRINT: self._print
}
def load_data(self, filename: str):
'''Read the data into memory'''
with open(filename, 'rb') as f:
data = pickle.load(f)
self.quads = data[0] # quads
# TODO: I need to parse this table and get the actual values with their real types
self.ConstTable = data[1] # consttable
self.FunDir = data[2]
self._memcount_global = data[3]
self._memcount_temp = data[4]
def run(self):
'''Run the actual code'''
quad = self.quads[self.ip]
while quad is not None:
instruction = Operator(quad[0])
method = self.nintIS[instruction]
method(quad)
quad = self.next()
def next(self):
self.ip += 1
if self.ip < self._total_quads:
return self.quads[self.ip]
return None
def set_value(self, address: str, value):
if is_local(address):
self.CallStack.peek().set_value(address, value)
elif is_temp(address):
self.Temp.set_value(address, value)
else:
self.CallStack.peek().set_value(address, value)
def get_value(self, address):
if is_constant(address):
debug(address, "is_constant")
return self.ConstTable[address]
elif is_temp(address):
return self.Temp.get_val(address)
elif is_global(address): # TODO: we could probably remove this now
return self._GlobalMemory.get_val(address)
return self.CallStack.peek().get_val(address)
# return self.mem.get_val(address)
# Operation functions
# ---------------------------------------------------------------
def assign(self, quad):
debug("assign")
debug(quad)
if self._returns_value:
# Second param is function
self._returns_value = False
func = self.FunDir[quad[1]]
assert 'value' in func, "Function should have a value because it is non-void"
value = func['value']
else:
value = self.get_value(quad[1])
assert value is not None
target_address = quad[3]
self.set_value(target_address, value)
debug()
# Relational operators
# -------------------------------------------------
def equals(self, quad):
debug("equals")
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand == right_operand
self.set_value(quad[3], result)
debug()
def neq(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand != right_operand
self.set_value(quad[3], result)
def gt(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand > right_operand
self.set_value(quad[3], result)
def gte(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand >= right_operand
self.set_value(quad[3], result)
def lt(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand < right_operand
self.set_value(quad[3], result)
def lte(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand <= right_operand
self.set_value(quad[3], result)
# Boolean operators
# -------------------------------------------------
def bool_and(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand and right_operand
self.set_value(quad[3], result)
def bool_or(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand or right_operand
self.set_value(quad[3], result)
# Arithmetic
# -------------------------------------------------
def add(self, quad):
debug("add")
debug(quad)
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand + right_operand
self.set_value(quad[3], result)
debug()
def sub(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand - right_operand
self.set_value(quad[3], result)
def mult(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
result = left_operand * right_operand
self.set_value(quad[3], result)
def div(self, quad):
left_operand = self.get_value(quad[1])
right_operand = self.get_value(quad[2])
if right_operand == 0:
raise Exception("Runtime Exception: Division by 0.")
result = left_operand / right_operand
self.set_value(quad[3], result)
# GOTOs
# -------------------------------------------------
def goto(self, quad):
quad_addr = int(quad[3])
self.ip = quad_addr - 1
def gotoF(self, quad):
expr_result = self.get_value(quad[1])
if not expr_result:
self.ip = int(quad[3]) - 1
def gotoV(self, quad):
raise Exception('Not implemented')
# Functions
# ---------------------------------------------------------------
def expand_active_record(self, quad):
debug("ERA")
func_name = quad[1]
assert func_name in self.FunDir, "No function"
size_map = self.FunDir[func_name]
# Create the AR
sf = StackFrame(func_name, size_map)
# Add it to the callstack
# self.CallStack.push(sf)
self._newstack = sf
debug()
def param(self, quad):
debug('param')
current_scope = self.CallStack.peek()
assert current_scope is not None, "No callstack"
param = self.get_value(quad[1])
address = quad[3]
assert self._newstack is not None
self._newstack.set_value(address, param)
debug()
def gosub(self, quad):
debug('gosub')
sf = self._newstack
self.CallStack.push(sf)
sf.set_return_addr(self.ip)
self.ip = int(quad[3]) - 1 # minus 1 because next() adds one
debug()
def endproc(self, quad):
debug('endproc')
current_scope = self.CallStack.pop()
self.ip = current_scope.return_addr
self._newstack = None
del current_scope # vacuous statement but makes me feel good
debug()
def return_proc(self, quad):
is_empty_return = quad[1] is None
if is_empty_return:
return self.endproc(quad)
current_scope = self.CallStack.peek()
fname = current_scope.function_name
retval = self.get_value(quad[1])
self.FunDir[fname]['value'] = retval
self._returns_value = True
return self.endproc(None)
# Special functions
# ---------------------------------------------------------------
def _print(self, quad):
arg = self.get_value(quad[3])
if isinstance(arg, bool):
arg = str(arg).lower()
print(arg)
class nintCompiler:
"""docstring for nintCompiler"""
def __init__(self):
super().__init__()
self.OperatorStack = Stack()
self.OperandStack = Stack()
self.TypeStack = Stack()
self.JumpStack = Stack()
self.GScope = Env(None, MemType.GLOBAL) # Global env?
# Function helpers
self._found_main = False
self._print = False
self._current_func = None
self._call_proc = None
self._func_returned = None # Check if the current function has returned something
self._param_k = None
# Generate the global scope and insert it into the functions directory
# gscope = Function(GLOBAL, None, VOID)
# self.FunDir.insert(gscope) # TODO: are objects passed by reference here?
self.ScopeStack = Stack() # Keep track of the current Scope
self.ScopeStack.push(self.GScope)
# Temporal memory
self._Temporal = Temp()
self._TempStack = Stack()
self._TempStack.push(self._Temporal)
self.quads = []
# Add GOTO main
self.quads.append([Operator.GOTO.value, None, None, None])
def __getattribute__(self, attr):
method = object.__getattribute__(self, attr)
# if not method:
# raise Exception("Method %s not implemented" % attr)
if callable(method):
name = method.__code__.co_name
if name not in no_check and not name.startswith('procedure'):
self.__check_main()
return method
def __check_main(self):
if not self._found_main and self._current_func is None:
self._found_main = True
self.quads[0][3] = len(self.quads)
def serialize(self, filename="out.nint.bytecode"):
'''Serialize the quads and the quads into an intermediate
obj file to be read by the VM.'''
const_map = dict()
for const_dict in Memory.CONST_TABLE.values():
for const, var in const_dict.items():
const_map[var.address] = utils.parseVar(var)
temp_counters = self._Temporal._counters
global_counters = self.GScope.memory._counters
fun_dir = self.functionDirectory()
data = [self.quads, const_map, fun_dir, global_counters, temp_counters]
with open(filename, 'wb') as f:
pickle.dump(data, f, pickle.HIGHEST_PROTOCOL)
def functionDirectory(self):
result = dict()
for func in self.GScope.functions:
result.update({func.name: func.size_map})
return result
def intercode(self):
'''Print the quadruples'''
for i, quad in enumerate(self.quads):
if debug_mode == 'debug':
print("{}) ".format(i), end='')
print('\t'.join(map(printable, quad)))
def add_var_declaration(self, type_str: str, identifier: str):
'''Add variable to the varsTable of the current context'''
debug("add_var_declaration")
current_scope = self.ScopeStack.peek()
# Check if it's not already been defined
if current_scope.exists(identifier):
raise Exception(
'Double declaration. {} has already been declared in this context.'
.format(identifier))
dtype = mapType(type_str)
address = current_scope.memory.next_address(dtype)
var = Variable(identifier, dtype, address)
current_scope.insert(var)
def add_var(self, token: str):
'''Add variable to the operand stack'''
debug("add_var")
current_scope = self.ScopeStack.peek()
variable = current_scope.get(token)
# Check that the variable has already been declared _somewhere_ (could be current, could be upper scopes)
assert variable is not None, "Name {} has not been declared.".format(
token)
debug("add_var: OperandStack.push({})".format(variable.name))
debug("add_var: TypeStack.push({})".format(variable.dtype))
self.OperandStack.push(variable)
self.TypeStack.push(variable.dtype)
debug()
def add_constant(self, token, dtype: DType):
'''Adds a constant to the operand stack'''
debug("add_constant")
debug("Operand.push({})".format(token))
debug("TypeStack.push({})".format(dtype))
debug()
self.OperandStack.push(Memory.constant(
dtype, token)) # TODO: should we parse?
self.TypeStack.push(dtype)
debug()
def add_operator(self, op: str):
''' Adds operator op to the OperatorStack'''
debug("add_operator")
debug("Operator.push({})".format(op))
operator = Operator(op)
self.OperatorStack.push(operator) # TODO: change this to an enum
debug()
# TODO: refactor the check_* functions
def check_relop(self):
debug("check_relop")
top = self.OperatorStack.peek()
debug('top: {}'.format(top))
if top not in RELOPS:
return
right_operand = self.OperandStack.pop()
right_type = self.TypeStack.pop()
left_operand = self.OperandStack.pop()
left_type = self.TypeStack.pop()
operator = self.OperatorStack.pop()
debug((operator, left_type, right_type))
result_type = SemanticCube.check(operator, left_type, right_type)
# Relational operators *always* return a boolean
assert result_type is DType.BOOL
result = self._TempStack.peek().next(result_type)
debug("Adds quad")
self.quads.append((operator.value, left_operand.address,
right_operand.address, result.address))
self.OperandStack.push(result)
self.TypeStack.push(result_type)
debug()
def check_and(self):
debug("check_and")
top = self.OperatorStack.peek()
debug('top: {}'.format(top))
if top is not Operator.AND:
return
right_operand = self.OperandStack.pop()
right_type = self.TypeStack.pop()
left_operand = self.OperandStack.pop()
left_type = self.TypeStack.pop()
operator = self.OperatorStack.pop()
debug((operator, left_type, right_type))
result_type = SemanticCube.check(operator, left_type, right_type)
# Relational operators *always* return a boolean
assert result_type is DType.BOOL
result = self._TempStack.peek().next(result_type)
debug("Adds quad")
self.quads.append((operator.value, left_operand.address,
right_operand.address, result.address))
self.OperandStack.push(result)
self.TypeStack.push(result_type)
debug()
def check_or(self):
debug("check_or")
top = self.OperatorStack.peek()
debug('top: {}'.format(top))
if top is not Operator.OR:
return
right_operand = self.OperandStack.pop()
right_type = self.TypeStack.pop()
left_operand = self.OperandStack.pop()
left_type = self.TypeStack.pop()
operator = self.OperatorStack.pop()
debug((operator, left_type, right_type))
result_type = SemanticCube.check(operator, left_type, right_type)
# Relational operators *always* return a boolean
assert result_type is DType.BOOL
result = self._TempStack.peek().next(result_type)
debug("Adds quad")
self.quads.append((operator.value, left_operand.address,
right_operand.address, result.address))
self.OperandStack.push(result)
self.TypeStack.push(result_type)
debug()
def check_eqop(self):
debug("check_eqop")
# TODO: implement this
top = self.OperatorStack.peek()
if top is not Operator.EQUAL and top is not Operator.NEQ:
return
right_operand = self.OperandStack.pop()
right_type = self.TypeStack.pop()
left_operand = self.OperandStack.pop()
left_type = self.TypeStack.pop()
operator = self.OperatorStack.pop()
debug((operator, left_type, right_type))
result_type = DType.BOOL
# result_type = SemanticCube.check(operator, left_type, right_type)
# TODO: rn we allow comparison of everything vs everything, is this correct?
# TODO: what if we compare a function name to a variable? (e.g. uno == 2)
result = self._TempStack.peek().next(result_type)
debug("Adds quad")
self.quads.append((operator.value, left_operand.address,
right_operand.address, result.address))
self.OperandStack.push(result)
self.TypeStack.push(result_type)
debug()
def check_addsub(self):
debug('check_addsub')
top = self.OperatorStack.peek()
if not (top == Operator.ADD or top == Operator.SUB):
return
right_operand = self.OperandStack.pop()
right_type = self.TypeStack.pop()
left_operand = self.OperandStack.pop()
left_type = self.TypeStack.pop()
operator = self.OperatorStack.pop()
debug((operator, left_operand.name, right_operand.name))
result_type = SemanticCube.check(operator, left_type, right_type)
result = self._TempStack.peek().next(result_type)
self.OperandStack.push(result)
self.TypeStack.push(result_type)
debug("Adds quad")
self.quads.append((operator.value, left_operand.address,
right_operand.address, result.address))
debug()
def check_multdiv(self):
debug('check_multdiv')
top = self.OperatorStack.peek()
if not (top == Operator.MULT or top == Operator.DIV):
return
right_operand = self.OperandStack.pop()
right_type = self.TypeStack.pop()
left_operand = self.OperandStack.pop()
left_type = self.TypeStack.pop()
operator = self.OperatorStack.pop()
debug((operator, left_type, right_type))
result_type = SemanticCube.check(operator, left_type, right_type)
result = self._TempStack.peek().next(result_type)
self.OperandStack.push(result)
self.TypeStack.push(result_type)
debug("Adds quad")
self.quads.append((operator.value, left_operand.address,
right_operand.address, result.address))
debug()
# If-Else
# --------------------------------------------
def ifelse_start_jump(self):
debug("ifelse_start_jump")
expression_type = self.TypeStack.pop()
if expression_type != DType.BOOL:
raise Exception(
"Type mismatch on line {}".format('SOMELINE TODO FIX THIS'))
# TODO: maybe make a static function for this?
result = self.OperandStack.pop()
self.quads.append([Operator.GOTOF.value, result.address, None, None])
self.JumpStack.push(
len(self.quads) - 1
) # TODO: definitely change this. There has to be a better way to do this
debug()
def ifelse_end_jump(self):
debug("ifelse_end_jump")
counter = len(self.quads) # TODO: change this
debug('counter: {}'.format(counter))
self.fill(self.JumpStack.pop(), counter)
debug()
def fill(self, pending_jump_pos, jump_location):
debug("fill")
self.quads[pending_jump_pos][
3] = jump_location # TODO: definitely make a class for this
def ifelse_start_else(self):
debug("ifelse_start_else")
debug("ADD ELSE QUAD GOTO")
self.quads.append([Operator.GOTO.value, None, None, None])
# Fill the false condition jump of the `if`
if_false_jump = self.JumpStack.pop()
counter = len(self.quads) # TODO: counter
self.JumpStack.push(counter - 1)
self.fill(if_false_jump, counter)
def assignment_quad(self):
debug("assignment_quad")
operator = self.OperatorStack.pop()
assert operator == Operator.ASSIGN
right_operand = self.OperandStack.pop()
right_type = self.TypeStack.pop()
left_operand = self.OperandStack.pop()
left_type = self.TypeStack.pop()
debug("<{}> = <{}>".format(left_type, right_type))
# TODO: probably change this
# TODO: these don't need to be *exactly* the same, they just need to be compatible
# example: float a = 10
assert right_type == left_type, "Type mismatch: assignment does not match"
self.quads.append((operator.value, right_operand.address, None,
left_operand.address))
debug()
# While
# --------------------------------------------
def while_condition_start(self):
debug("while_condition_start")
counter = len(self.quads) # TODO: counter
self.JumpStack.push(counter)
def while_block_start(self):
debug("while_block_start")
expression_type = self.TypeStack.pop()
if expression_type != DType.BOOL:
raise Exception(
"Type mismatch on line {}".format("SOMELINE FIX THIS TODO"))
result = self.OperandStack.pop()
debug("ADD QUAD: while block_start GOTOF")
self.quads.append([Operator.GOTOF.value, result.address, None, None])
counter = len(self.quads)
self.JumpStack.push(counter - 1) # TODO: counter
def while_end(self):
debug("while_end")
pending_while_end_jump = self.JumpStack.pop()
return_pos = self.JumpStack.pop()
debug("ADD QUAD: while_end GOTO return")
self.quads.append([Operator.GOTO.value, None, None, return_pos])
counter = len(self.quads) # TODO: change this
self.fill(pending_while_end_jump, counter)
# Function definitions
# --------------------------------------------
def procedure_start(self, name: str):
'''Insert procedure name into dirfunc table, verify semantics'''
debug('procedure_start')
current_scope = self.ScopeStack.peek()
# Check that it's not already defined in the **current** scope
if current_scope.exists(name) or name in special_functions:
raise Exception('The name {} is already defined'.format(name))
func = Function(name, current_scope)
current_scope.insert(func)
self._current_func = func
self._func_returned = False
self.ScopeStack.push(func.varsTable)
self._TempStack.push(func.varsTable.memory)
def procedure_add_params(self, params):
'''Add the total params to the current function'''
debug('procedure_add_params')
for param in params:
self.procedure_add_param(param['type'], param['id'])
def procedure_add_param(self, type_str: str, pname: str):
'''Call function.add_param()'''
debug('procedure_add_param')
assert self._current_func is not None
current_scope = self.ScopeStack.peek()
if current_scope.exists(pname):
raise Exception(
'Redefinition of parameter {} in function signature'.format(
pname))
data_type = mapType(type_str)
address = current_scope.memory.next_address(data_type)
var = Variable(pname, data_type, address)
self._current_func.add_param(var)
def procedure_mark_start(self):
'''Mark the current quadruple counter as the start of this function'''
debug('procedure_mark_start')
self._current_func.start_pos = len(self.quads)
def procedure_set_type(self, type_str: str):
'''Set the return type of this function'''
self._current_func.update_type(mapType(type_str))
def procedure_update_size(self):
'''Once we know the number of temps, and local variables defined, we can update the size'''
# TODO: define this
debug('procedure_update_size')
def procedure_return(self, returns_expresion=False):
'''Generate a RETURN command'''
debug('procedure_return')
retval = None
if returns_expresion:
retval = self.OperandStack.pop()
retval_type = self.TypeStack.pop()
assert self._current_func.dtype == retval_type, 'Type mismatch: value returned does not match function signature.'
self._func_returned = True
retval = retval.address
else:
assert self._current_func.is_void, 'Type mismatch: no value returned in non-void function.'
self.quads.append((Operator.RETURN.value, retval, None, None))
debug()
def procedure_end(self):
'''Generate an ENDPROC'''
debug('procedure_end')
# TODO: release the current vartable?
# TODO: resolve any ERAs here
# self.procedure_update_size()
# if function is non-void, it returned something
if not self._current_func.is_void and not self._func_returned:
raise Exception("Non-void function must return a valid value.")
self.quads.append((Operator.ENDPROC.value, None, None, None))
debug(('FUNCTION TYPE:', self._current_func.dtype))
self._current_func = None
self.ScopeStack.pop()
self._TempStack.pop()
debug()
# Function calls
# --------------------------------------------
def method_call_start(self, method_name):
'''Verify that the procedure exists in DirFunc'''
debug('method_call_start')
if not self.GScope.exists(method_name):
raise Exception(
'Method {} has not been defined'.format(method_name))
call_proc = self.GScope.find(
method_name
) # Assumes all functions are defined in the global scope
assert call_proc is not None
self._call_proc = call_proc
debug()
def method_call_param_start(self):
'''Start reading parameters for function call'''
debug('method_call_param_start')
debug("Start param k counter at 0")
self._param_k = 0
fname = self._call_proc.name
# TODO: add stack/list to keep track of these
self.quads.append([Operator.ERA.value, fname, None,
None]) # ActivationRecord expansion
debug()
def method_call_param(self):
'''Get the kth parameter for the function call and perform semantic validations'''
param = self.OperandStack.pop()
param_type = self.TypeStack.pop()
assert self._param_k is not None
assert self._param_k < len(self._call_proc.param_list)
kth_param = self._call_proc.param_list[self._param_k]
kth_param_type = kth_param.dtype
# Check param_type
# TODO: estos no **tienen** que ser iguales, solo compatibles
assert param_type == kth_param_type # TODO: Aqui es donde entra el cubo semantico
self.quads.append(
(Operator.PARAM.value, param.address, None, kth_param.address))
def method_call_param_end(self):
'''Verify the last parameter points to null'''
# i.e. we consumed all of the parameters
# i.e. the parameter call matches the function definition
# NOTE: when the argument list ends, the k pointer should be pointing at the last elem (len-1)
arglength = len(self._call_proc.param_list)
if arglength == 0:
assert self._param_k == 0, "Parameter count mismatch."
else:
assert self._param_k == arglength - 1, "Parameter count mismatch."
def method_call_end(self):
'''Generate a GOSUB to take control flow the procedure'''
debug('method_call_end')
func = self._call_proc
name = func.name
init_address = func.start_pos
is_void = func.is_void
return_type = func.dtype
self._call_proc = None
self._param_k = None
self.quads.append((
Operator.GOSUB.value, name, None,
init_address)) # TODO: migaja de pan pa saber donde voy a regresar
# If the function returned something, we should assign it to a local temporary var
if not is_void:
result = self._TempStack.peek().next(return_type)
self.OperandStack.push(result)
self.TypeStack.push(return_type)
self.quads.append(('=', name, None, result.address))
else: # TODO: test this thoroughly, not sure if this is going to work
assert self.OperatorStack.peek(
) is not Operator.ASSIGN, 'Void function does not return anything. Cannot assign void value.'
debug()
def print_start(self):
self._print = True
def print_end(self):
self._print = False
def print_expression(self):
debug("print_expression")
assert self._print
op = self.OperandStack.pop()
self.TypeStack.pop()
self.quads.append((Operator.PRINT.value, None, None, op.address))
debug()
def paren_open(self):
self.OperatorStack.push(Operator.FAKE)
def paren_close(self):
self.OperatorStack.pop()
