#!/usr/bin/python import sys import struct option_ptrsize = struct.calcsize("P") option_intsize = struct.calcsize("l") option_floatsize = struct.calcsize("f") option_inttype = "long" option_floattype = "float" class node: def __init__(self): self.values = [] self.children = [] self.parent = 0 def name(self): if len(self.values): return self.values[0] return "" def debug_print(self, level): print (" "*level) + " ".join(self.values), if len(self.children): print "{" for c in self.children: c.debug_print(level+1) print (" "*level)+"}" else: print "" def debug_root(self): for c in self.children: c.debug_print(0) # TODO: should return list of items in the tree, def gather(self, str): def recurse(parts, path, node): if not len(parts): r = {} path = path + "." + node.values[0] r = [node] #print "found", path return r l = [] for c in node.children: if parts[0] == "*" or c.values[0] == parts[0]: if len(node.values): if len(path): l += recurse(parts[1:], path+"."+node.values[0], c) else: l += recurse(parts[1:], node.values[0], c) else: l += recurse(parts[1:], path, c) return l parts = str.split(".") return recurse(parts, "", self) def find_node(self, str): parts = str.split(".") node = self for part in parts: if len(part) == 0: continue if part == "parent": node = node.parent else: found = 0 for c in node.children: if part == c.values[0]: node = c found = 1 break if node == self: return return node def get_single(self, str): parts = str.split("@") index = -1 if len(parts) == 2: index = int(parts[1]) node = self if len(parts[0]): node = self.find_node(parts[0]) if not node: print "failed to get", str return Null if index == -1: return node.get_path()[1:] return node.values[index] def get_path(self): if self.parent == 0: return "" return self.parent.get_path() + "." + self.values[0] def get_single_name(self, str): return self.get_path()[1:] + "." + str class parser: lines = [] def parse_node(self, this_node): while len(self.lines): line = self.lines.pop(0) # grab line fields = line.strip().split() # TODO: improve this to handle strings with spaces if not len(fields): continue if fields[-1] == '{': new_node = node() new_node.parent = this_node new_node.values = fields[:-1] this_node.children += [new_node] self.parse_node(new_node) elif fields[-1] == '}': break else: new_node = node() new_node.parent = this_node new_node.values = fields this_node.children += [new_node] def parse_file(self, filename): self.lines = file(filename).readlines() n = node() self.parse_node(n) return n def parse_file(filename): return parser().parse_file(filename) class pointer: def __init__(self, index, target): self.index = index self.target = target class data_constructor: def __init__(self): self.data = "" self.trans = 0 self.pointers = [] self.targets = {} self.enums = {} def get_type(self, s): return self.trans.types[s] def allocate(self, size): index = len(self.data) self.data += "\0"*size return index def add_pointer(self, index, target): self.pointers += [pointer(index, target)] def add_enum(self, name, value): self.enums[name] = value def get_enum_value(self, name): if not name in self.enums: print "ERROR: couldn't find enum '%s'" % (name) return self.enums[name] def add_target(self, target, index): # TODO: warn about duplicates #print "add_target(target='%s' index=%d)" % (target, index) self.targets[target] = index def write(self, index, size, data): try: self.data = self.data[:index] + data + self.data[index+size:] except: print "write error:" print "\tself.data =", self.data print "\tdata =", data def patch_pointers(self): for p in self.pointers: if p.target in self.targets: i = self.targets[p.target] #print "ptr @ %d -> %s -> %d" % (p.index, p.target, i) data = struct.pack("P", i) self.write(p.index, len(data), data) else: print "ERROR: couldn't find target '%s' for pointer at %d" % (p.target, p.index) class type: def __init__(self): self.name = "" def size(self): pass class structure: def __init__(self): self.name = "" self.members = [] def size(self): s = 0 for m in self.members: s += m.size() return s def emit_header_code(self, out): print >>out, "struct", self.name print >>out, "{" for m in self.members: for l in m.get_code(): print >>out, "\t" + l print >>out, "};" print >>out, "" def emit_source_code(self, out): print >>out, "static void patch_ptr_%s(%s *self, char *base)" % (self.name, self.name) print >>out, "{" for m in self.members: for l in m.get_patch_code("self", "base"): print >>out, "\t" + l print >>out, "}" print >>out, "" def emit_data(self, cons, index, src_data): #print self.name+":" member_index = index for m in self.members: #print "\t" + m.name m.emit_data(cons, member_index, src_data) member_index += m.size() class variable: def __init__(self): self.expr = "" self.type = "" self.subtype = "" def get_code(self): return [] def get_patch_code(self, ptrname, basename): return [] def emit_data(self, cons, index, src_data): pass class variable_int(variable): def get_code(self): return ["%s %s;" % (option_inttype, self.name)] def size(self): return option_intsize def emit_data(self, cons, index, src_data): try: value = int(self.expr) except: value = int(src_data.get_single(self.expr)) #print "int", self.name, "=", value, "@", index data = struct.pack("l", value) cons.write(index, len(data), data) class variable_float(variable): def get_code(self): return ["%s %s;" % (option_floattype, self.name)] def size(self): return option_floatsize def emit_data(self, cons, index, src_data): try: value = float(self.expr) except: value = float(src_data.get_single(self.expr)) #print "int", self.name, "=", value, "@", index data = struct.pack("f", value) cons.write(index, len(data), data) class variable_string(variable): def get_code(self): return ["char *%s;" % (self.name)] def get_patch_code(self, ptrname, basename): return ["patch_ptr((char **)&(%s->%s), %s);" % (ptrname, self.name, basename)] def size(self): return option_ptrsize def emit_data(self, cons, index, src_data): string = src_data.get_single(self.expr) string = string.strip()[1:-1] # skip " and " string_index = cons.allocate(len(string)+1) cons.write(string_index, len(string), string) data = struct.pack("P", string_index) # TODO: solve this cons.write(index, len(data), data) class variable_ptr(variable): def get_code(self): return ["%s *%s;" % (self.subtype, self.name)] def get_patch_code(self, ptrname, basename): return ["patch_ptr((char**)&(%s->%s), %s);" % (ptrname, self.name, basename)] def size(self): return option_ptrsize def emit_data(self, cons, index, src_data): target = src_data.get_single(self.expr) cons.add_pointer(index, target) class variable_enum(variable): def get_code(self): return ["long *%s;" % (self.name)] def size(self): return option_intsize def emit_data(self, cons, index, src_data): target = src_data.get_single(self.expr) data = struct.pack("l", cons.get_enum_value(target)) cons.write(index, len(data), data) class variable_instance(variable): def get_code(self): return ["%s %s;" % (self.subtype, self.name)] def get_patch_code(self, ptrname, basename): return ["patch_ptr_%s(&(%s->%s), %s);" % (self.subtype, ptrname, self.name, basename)] def size(self): return self.translator.types[self.subtype].size() def emit_data(self, cons, index, src_data): target = src_data.find_node(self.expr) translator.types[self.subtype].emit_data(cons, index, target) #target = #cons.add_pointer(index, target) class variable_array(variable): def get_code(self): return ["long num_%s;" % self.name, "%s *%s;" % (self.subtype, self.name)] def get_patch_code(self, ptrname, baseptr): code = [] code += ["patch_ptr((char**)&(%s->%s), %s);" % (ptrname, self.name, baseptr)] code += ["for(int i = 0; i < %s->num_%s; i++)" % (ptrname, self.name)] code += ["\tpatch_ptr_%s(%s->%s+i, %s);" % (self.subtype, ptrname, self.name, baseptr)] return code def emit_data(self, cons, index, src_data): array_data = src_data.gather(self.expr) array_type = cons.get_type(self.subtype) size = array_type.size()*len(array_data) #print "packing array", self.name #print "\ttype =", array_type.name #print "\tsize =", array_type.size() array_index = cons.allocate(size) data = struct.pack("lP", len(array_data), array_index) # TODO: solve this cons.write(index, len(data), data) member_index = array_index for node in array_data: cons.add_target(node.get_path()[1:], member_index) array_type.emit_data(cons, member_index, node) member_index += array_type.size() #print "array", member_index def size(self): return option_ptrsize+option_intsize class const_arrayint: def __init__(self): self.name = "" self.values = [] def emit_header_code(self, out): print >>out, "enum" print >>out, "{" for i in xrange(0, len(self.values)): print >>out, "\t%s_%s = %d," % (self.name.upper(), self.values[i].upper(), i) print >>out, "\tNUM_%sS = %d" % (self.name.upper(), len(self.values)) print >>out, "};" print >>out, "" class translator: def __init__(self): self.types = {} self.structs = [] self.constants = [] self.data = 0 self.srcdata = 0 self.types["int"] = variable_int() self.types["float"] = variable_float() self.types["string"] = variable_string() self.types["ptr"] = variable_ptr() self.types["array"] = variable_array() def parse_variable(self, node): if len(node.values) != 4: print node.values raise "error parsing variable" type = node.values[0] subtype = "" if type == "int": v = variable_int() elif type == "enum": v = variable_enum() elif type == "float": v = variable_float() elif type == "string": v = variable_string() else: # complex type parts = type.split(":") if len(parts) != 2: raise "can't emit code for variable %s of type %s" % (self.name, self.type) elif parts[0] == "ptr": subtype = parts[1] v = variable_ptr() elif parts[0] == "instance": subtype = parts[1] v = variable_instance() elif parts[0] == "array": subtype = parts[1] v = variable_array() else: raise "can't emit code for variable %s of type %s" % (self.name, self.type) v.translator = self v.type = node.values[0] v.subtype = subtype v.name = node.values[1] assignment = node.values[2] v.expr = node.values[3] if assignment != "=": raise "error parsing variable. expected =" return v def parse_struct(self, node): if len(node.values) != 2: raise "error parsing struct" s = structure() s.name = node.values[1] for statement in node.children: s.members += [self.parse_variable(statement)] return s def parse_constant(self, node): if len(node.values) != 5: print node.values raise "error parsing constant" type = node.values[1] name = node.values[2] assignment = node.values[3] expression = node.values[4] if assignment != "=": print node.values raise "error parsing constant" ints = const_arrayint() ints.name = name items = self.srcdata.gather(expression) for c in items: ints.values += [c.name()] self.constants += [ints] def parse(self, script, srcdata): self.srcdata = srcdata for statement in script.children: if statement.values[0] == "struct": s = self.parse_struct(statement) self.structs += [s] self.types[s.name] = s elif statement.values[0] == "const": self.parse_constant(statement) else: raise "unknown statement:" + statement def emit_header_code(self, out): for c in self.constants: c.emit_header_code(out) for s in self.structs: s.emit_header_code(out) print >>out, "" print >>out, "data_container *load_data_from_file(const char *filename);" print >>out, "data_container *load_data_from_memory(unsigned char *filename);" print >>out, "" def emit_source_code(self, out): print >>out, ''' #include "../data.h" #include #include static void patch_ptr(char **ptr, char *base) { *ptr = base+(size_t)(*ptr); } ''' for s in self.structs: s.emit_source_code(out) print >>out, ''' data_container *load_data_from_memory(unsigned char *mem) { /* patch all pointers */ data_container *con = (data_container*)mem; patch_ptr_data_container(con, (char *)con); return con; } data_container *load_data_from_file(const char *filename) { unsigned char *data = 0; int size; /* open file */ FILE *f = fopen(filename, "rb"); /* get size */ fseek(f, 0, SEEK_END); size = ftell(f); fseek(f, 0, SEEK_SET); /* allocate, read data and close file */ data = (unsigned char *)malloc(size); fread(data, 1, size, f); fclose(f); return load_data_from_memory(data); } ''' def emit_data(self): for s in self.structs: if s.name == "data_container": #print "found data_container" cons = data_constructor() cons.trans = self i = cons.allocate(s.size()) s.emit_data(cons, i, self.srcdata) cons.patch_pointers() return cons.data def create_translator(script, srcdata): t = translator() t.parse(script, srcdata) return t def validate(script, validator): def validate_values(values, check): if not len(check) or check[0] == "*": print "too many values" return p = check[0].split(":") type = p[0] name = p[1] # TODO: check type and stuff # recurse if len(values) > 1: if not len(check): print "unexpected value" validate_values(values[1:], check[1:]) else: if len(check) > 1 and check[1] != "*": print "to few values" if len(script.values): validate_values(script.values, validator.values) for child in script.children: tag = child.values[0] n = validator.find_node("tag:"+tag) if not n: found = 0 for vc in validator.children: if "ident:" in vc.values[0]: validate(child, vc) print vc.values[0] found = 1 break if not found: print "error:", tag, "not found" else: print "tag:"+tag validate(child, n) input_filename = sys.argv[1] script_filename = sys.argv[2] output_filename = 0 coutput_filename = 0 header_filename = 0 source_filename = 0 if sys.argv[3] == '-h': header_filename = sys.argv[4] elif sys.argv[3] == '-s': source_filename = sys.argv[4] elif sys.argv[3] == '-d': output_filename = sys.argv[4] elif sys.argv[3] == '-c': coutput_filename = sys.argv[4] srcdata = parse_file(input_filename) script = parse_file(script_filename) translator = create_translator(script, srcdata) if header_filename: translator.emit_header_code(file(header_filename, "w")) if source_filename: translator.emit_source_code(file(source_filename, "w")) if output_filename: rawdata = translator.emit_data() file(output_filename, "wb").write(rawdata) if coutput_filename: i = 0 rawdata = translator.emit_data() f = file(coutput_filename, "w") print >>f,"unsigned char internal_data[] = {" print >>f,str(ord(rawdata[0])), for d in rawdata[1:]: s = ","+str(ord(d)) print >>f,s, i += len(s)+1 if i >= 70: print >>f,"" i = 0 print >>f,"" print >>f,"};" print >>f,"" f.close()