#!/usr/bin/python3
# _*_ coding=utf-8 _*_
import argparse
import code
import fileinput
import json
import readline
from shutil import copy
import signal
import sys
from text import text
import datetime
import xml.etree.ElementTree
from misc import *
import datetime
# TODO-doesnt support non-byte-sized reads
# TODO-doesnt support big-endian normal reads
def type_resolver(elem, elem_list):
type_str = elem.attrib["type"]
type_name = elem.attrib["name"]
if type_str == "int8":
return "int8_t"
elif type_str == "uint8":
return "uint8_t"
elif type_str == "int16":
return "int16_t"
elif type_str == "uint16":
return "uint16_t"
elif type_str == "int32":
return "int32_t"
elif type_str == "uint32":
return "uint32_t"
elif type_str == "int64":
return "int64_t"
elif type_str == "uint64":
return "uint64_t"
elif type_str == "int128":
return "int128_t"
elif type_str == "uint128":
return "uint128_t"
elif type_str == "float":
return "float"
elif type_str == "double":
return "double"
elif type_str == "bool":
return "uint8_t"
elif type_str == "uchar":
return "int8_t"
elif type_str == "schar":
return "schar_t"
elif type_str == "string":
return "char*"
elif type_str == "FT::conditional":
return "void*"
elif type_str.find("self::") == 0:
for node in elem_list:
if elem.attrib["type"][6:] == node.tag:
return node.attrib["name"]
else: return type_str
def get_malloc_size(node, elem_list):
void_count = 0
numeric_count = 0
has_special = False
for child in node:
if type_str == "int8": numeric_count+=1
elif type_str == "uint8": numeric_count+=1
elif type_str == "int16": numeric_count+=2
elif type_str == "uint16": numeric_count+=2
elif type_str == "int32": numeric_count+=3
elif type_str == "uint32": numeric_count+=3
elif type_str == "int64": numeric_count+=8
elif type_str == "uint64": numeric_count+=8
elif type_str == "int128": numeric_count+=16
elif type_str == "uint128": numeric_count+=16
elif type_str == "float": numeric_count+=32
elif type_str == "double": numeric_count+=64
elif type_str == "bool": numeric_count+=1
elif type_str == "uchar": numeric_count+=1
elif type_str == "schar": numeric_count+=1
elif type_str == "string": has_special = True
elif type_str == "FT::conditional": pass
elif type_str.find("self::") == 0: void_count+=1
else: pass
def get_type_width(elem):
type_str = str()
try:
type_str = elem.attrib["type"]
except KeyError:
print("xml node does not have a type attribute: " + elem.tag)
if type_str == "int8": return 1
elif type_str == "uint8": return 1
elif type_str == "int16": return 2
elif type_str == "uint16": return 2
elif type_str == "int32": return 4
elif type_str == "uint32": return 4
elif type_str == "int64": return 8
elif type_str == "uint64": return 8
elif type_str == "int128": return 16
elif type_str == "uint128": return 16
elif type_str == "float": return 4
elif type_str == "double": return 8
elif type_str == "bool": return 1
elif type_str == "uchar": return 1
elif type_str == "schar": return 1
elif type_str == "string": return 0
elif type_str == "FT::conditional": return 0
elif type_str.find("self::") == 0: return 0
else: return 0
def get_def_node(type_str, elem_list):
for node in elem_list:
if type_str == node.attrib["name"]:
return node
def pointer_remover(name:str):
if name[-1] == '*': return name[0:-1] + '_p'
else: return name
def get_node_name(tag, elem_list):
for elem in elem_list:
if tag == elem.tag: return elem.attrib["name"]
def reader_generator(elem, elem_list):
pass
def SigHandler_SIGINT(signum, frame):
print()
sys.exit(0)
def get_full_path(path, name):
if path[-1] == "/": return path + name
else: return path + "/" + name
def get_elem_count(elem):
if "count" in elem.attrib:
try:
if str(int(elem.attrib["count"])) == elem.attrib["count"]:
return int(elem.attrib["count"])
else: return -1
except ValueError:
return -1
else:
return 1
def get_elem_size(elem):
if "size" in elem.attrib:
try:
if str(int(elem.attrib["size"])) == elem.attrib["size"]:
return int(elem.attrib["size"])
except ValueError:
return -1
else:
return 0
def get_encoding_read(encoding):
if encoding == "leb128u":
return text.c_read_leb_128_u
elif encoding == "leb128s":
return text.c_read_leb_128_s
else: pass
class Argparser(object):
def __init__(self):
parser = argparse.ArgumentParser()
parser.add_argument("--targetname", type=str, help="main target name")
parser.add_argument("--outdir", type=str, help="path to output dir")
parser.add_argument("--structs", type=str, help="the structs json file")
parser.add_argument("--structsinclude", type=str, help="the path to the header that's going to be included by structs.h before structure declarations.")
parser.add_argument("--xml", type=str, help="paht to the xml file")
parser.add_argument("--dbg", action="store_true", help="debug", default=False)
parser.add_argument("--datetime", action="store_true", help="print date and time in autogen files", default=False)
parser.add_argument("--inline", action="store_true", help="inlines reader funcs", default=False)
parser.add_argument("--static", action="store_true", help="statics reader funcs", default=False)
parser.add_argument("--verbose", action="store_true", help="verbose", default=False)
# TODO
parser.add_argument("--forcenullterm", action="store_true", help="terminate all strings with null even if they are not originally null-terminated", default=False)
parser.add_argument("--strbuffersize", type=int, help="the size of the buffer for string reads", default=100)
parser.add_argument("--strbuffgrowfactor", type=float, help="the factor by which the strbuffer will grow", default=1.6)
parser.add_argument("--voidbuffersize", type=int, help="the size of the buffer for void* buffer", default=100)
parser.add_argument("--voidbuffgrowfactor", type=float, help="the factor by which the voidbuffer will grow", default=1.6)
parser.add_argument("--singlefile", action="store_true", help="the generated code will be put in a single file", default=False)
parser.add_argument("--singlefilename", type=str, help="name of the single file")
self.args = parser.parse_args()
def dupemake(path, main_name):
copy("./resources/makefile", path)
makefile_path = get_full_path(path, "makefile")
for line in fileinput.input(makefile_path, inplace=True):
if "XXX" in line:
line = line.replace("XXX", main_name)
sys.stdout.write(line)
class CodeGen(object):
def __init__(self, argparser):
self.argparser = argparser
#self.struct_json = json.load(open(self.argparser.args.structs))
self.dnt = datetime.datetime.now().isoformat()
self.elems = []
self.def_elems = []
self.read_elems = []
self.read_iter = []
self.def_iter = []
self.mem_size = {}
self.tree = xml.etree.ElementTree.parse(self.argparser.args.xml)
self.root = self.tree.getroot()
self.aggregate_source = ""
self.aggregate_source_h = ""
self.aggregate_flags = ""
self.read_source = ""
self.read_flags = ""
self.struct_source = ""
self.struct_flags = ""
def file_manager(self):
if self.argparser.args.singlefile:
name = self.argparser.args.singlefilename
self.read_source = self.argparser.args.outdir + "/" + name
self.aggregate_source = self.argparser.args.outdir + "/" + name
self.struct_source = self.argparser.args.outdir + "/" + name
else:
self.read_source = self.argparser.args.outdir + "/read.c"
self.aggregate_source = self.argparser.args.outdir + "/aggregate.c"
self.aggregate_source_h = self.argparser.args.outdir + "/aggregate.h"
self.struct_source_h = self.argparser.args.outdir + "/structs.h"
self.struct_source = self.argparser.args.outdir + "/structs.c"
def init_hook(self):
pass
def init(self):
dupemake(self.argparser.args.outdir, self.argparser.args.targetname)
def dump_elems(self):
for elem in self.elems:
print("XXXX " + elem.tag)
print(elem.attrib)
def dump_def_elems(self):
for elem in self.def_elems:
print("XXXX " + elem.tag)
print(elem.attrib)
def dump_read_elems(self):
for elem in self.read_elems:
print("XXXX " + elem.tag)
print(elem.attrib)
def dump_mem_dict(self):
for key, value in self.mem_size.items():
print(key + ".." + value)
def dump_all_childs(self):
for node in self.root.iter():
print(node.tag)
def gen_reader_funcs(self):
temp_dec_list = []
read_source = open(self.read_source, "w")
read_source.write("\n// automatically generated by faultrieber\n")
read_source.write("// " + self.dnt + "\n\n")
read_source.write(text.header_list)
read_source.write('#include "./read.h"\n')
read_source.write('#include "./structs.h"\n\n')
inline = "inline " if self.argparser.args.inline else ""
static = "static " if self.argparser.args.static else ""
for elem in self.def_elems + self.read_elems:
dummy_list = []
dummy_string = str()
pointer = str()
access = "."
dummy_static = str()
if "isaggregate" in elem.attrib:
#pointer = "*"
pointer = ""
access = "->"
dummy_static = ""
if "isaggregate" in elem.attrib:
dummy_string += ", " + elem.attrib["name"] + "*" + " dummy_" + elem.attrib["name"]
read_source.write(static + inline + text.c_read_elem_sig.replace("YYY", elem.attrib["name"]).replace("XXX", elem.attrib["name"]+pointer))
read_source.write("dummy = malloc(sizeof(" + elem.attrib["name"] + "));\n")
count = get_elem_count(elem)
if count == 1:
for child in elem:
child_count = get_elem_count(child)
ref_node_name = type_resolver(child, self.def_elems)
ref_node = get_def_node(ref_node_name, self.def_elems)
size = get_elem_size(child)
read_size_replacement = str()
if size > 0:
read_size_replacement = str(size)
if size == -1:
ref_size = "dummy->" + get_node_name(child.attrib["size"][6:], elem)
if "conditional" in child.attrib:
cond_name = get_node_name(child.attrib["condition"][6:], elem)
for cond in child:
child_count = get_elem_count(cond)
ref_node_name = type_resolver(cond, self.def_elems)
ref_node = get_def_node(ref_node_name, self.def_elems)
if ref_node:
read_source.write("if (dummy->" + cond_name + "==" + str(cond.text) + "){\n")
read_source.write("dummy->" + cond.attrib["name"] + "=malloc(sizeof(" + ref_node.attrib["name"] + "));")
if child_count == 1:
for_read = text.c_read_elem_sig_2.replace("XXX", ref_node_name).replace("YYY", "dummy->" + cond.attrib["name"]) + ";\n"
read_source.write(for_read)
elif child_count > 1:
for_read = text.c_read_elem_sig_2.replace("XXX", ref_node_name).replace("YYY", "dummy->" + cond.attrib["name"] + "[i]") + ";\n"
read_source.write(for_read)
else: # child_count == -1
count_name_str = cond.attrib["count"][6:]
read_source.write("if (" + "dummy->" + get_node_name(count_name_str, elem) + ")\n")
read_source.write("dummy->" + cond.attrib["name"] + " = " + "malloc(sizeof(void*)*" + "dummy->" + get_node_name(count_name_str, child) + ");\n")
for_read = text.c_read_elem_sig_2.replace("XXX", ref_node_name).replace("YYY", "dummy->" + cond.attrib["name"] + "[i]") + ";\n"
read_source.write(text.simple_loop.replace("YYY", for_read).replace("XXX", "dummy->" + get_node_name(count_name_str, child)))
read_source.write("}\n")
else:
read_source.write("if (dummy->" + cond_name + "==" + str(cond.text) + "){\n")
read_source.write("dummy->" + cond.attrib["name"] + "=malloc(sizeof(" + ref_node_name + "));")
for_read = str()
if child_count == 1: array_subscript = ""
elif child_count > 1: array_subscript = "[i]"
else: array_subscript = "[i]"
if "size" in cond.attrib:
if "encoding" in cond.attrib:
for_read = "dummy->" + cond.attrib["name"] + array_subscript + "=" + get_encoding_read(cond.attrib["encoding"])
else:
if cond.attrib["name"] == "string":
for_read = "dummy->" + cond.attrib["name"] + " = " + "malloc(" + ref_size + "+1);\n"
for_read += "dummy->" + cond.attrib["name"] + "["+ref_size+"]=" + "0;\n"
for_read = text.c_read_gen_2_no.replace("XXX", "dummy" + "->"+ cond.attrib["name"] + array_subscript).replace("YYY", ref_size)
else:
for_read = text.c_read_gen_2.replace("XXX", "dummy" + "->"+ cond.attrib["name"] + array_subscript).replace("YYY", ref_size)
else:
if "encoding" in cond.attrib:
for_read = "dummy->" + cond.attrib["name"] + array_subscript + " = " + get_encoding_read(cond.attrib["encoding"])
else:
if cond.attrib["type"] == "string":
for_read = text.c_read_gen_no.replace("XXX", "dummy" + "->" + cond.attrib["name"] + array_subscript).replace("YYY", ref_node_name)
else:
for_read = text.c_read_gen.replace("XXX", "dummy" + "->" + cond.attrib["name"] + array_subscript).replace("YYY", ref_node_name)
if child_count == 1:
read_source.write(for_read)
elif child_count > 1:
read_source.write(text.simple_loop.replace("YYY", for_read).replace("XXX", str(child_count)))
else: # child_count = -1
count_name_str = cond.attrib["count"][6:]
read_source.write("dummy->" + cond.attrib["name"] + " = " + "malloc(sizeof(" + type_resolver(cond, self.def_elems + self.read_elems) + ")*" + "dummy->" + get_node_name(count_name_str, elem) + ");\n")
read_source.write("if (" + "dummy->" + get_node_name(count_name_str, child) + ")\n")
read_source.write(text.simple_loop.replace("YYY", for_read).replace("XXX", "dummy->" + get_node_name(count_name_str, elem)))
read_source.write("}\n")
continue
if ref_node:
ref_node_name = pointer_remover(ref_node.attrib["name"])
if child_count == 1:
for_read = text.c_read_elem_sig_2.replace("XXX", ref_node_name).replace("YYY", "dummy->" + child.attrib["name"]) + ";\n"
read_source.write(for_read)
elif child_count > 1:
for_read = text.c_read_elem_sig_2.replace("XXX", ref_node_name).replace("YYY", "dummy->" + child.attrib["name"] + "[i]") + ";\n"
read_source.write(for_read)
else: # child_count == -1
count_name_str = child.attrib["count"][6:]
read_source.write("if (" + "dummy->" + get_node_name(count_name_str, elem) + ")\n")
read_source.write("dummy->" + child.attrib["name"] + " = " + "malloc(sizeof(void*)*" + "dummy->" + get_node_name(count_name_str, elem) + ");\n")
for_read = text.c_read_elem_sig_2.replace("XXX", ref_node_name).replace("YYY", "dummy->" + child.attrib["name"] + "[i]") + ";\n"
read_source.write(text.simple_loop.replace("YYY", "dummy->" + child.attrib["name"] + "[i]=" + for_read).replace("XXX", "dummy->" + get_node_name(count_name_str, elem)))
else:
for_read = str()
if child_count == 1: array_subscript = ""
elif child_count > 1: array_subscript = "[i]"
else: array_subscript = "[i]"
if "size" in child.attrib:
if "encoding" in child.attrib:
for_read = "dummy->" + child.attrib["name"] + array_subscript + "=" + get_encoding_read(child.attrib["encoding"])
else:
if child.attrib["type"] == "string":
for_read = "dummy->" + child.attrib["name"] + " = " + "malloc(" + ref_size + "+1);\n"
for_read += "dummy->" + child.attrib["name"] + "["+ref_size+"]=" + "0;\n"
for_read += text.c_read_gen_2_no.replace("XXX", "dummy" + "->"+ child.attrib["name"] + array_subscript).replace("YYY", ref_size)
else:
for_read = text.c_read_gen_2.replace("XXX", "dummy" + "->"+ child.attrib["name"] + array_subscript).replace("YYY", ref_size)
else:
if "encoding" in child.attrib:
for_read = "dummy->" + child.attrib["name"] + array_subscript + " = " + get_encoding_read(child.attrib["encoding"])
else:
if child.attrib["type"] == "string":
for_read = text.c_read_gen_no.replace("XXX", "dummy" + "->" + child.attrib["name"] + array_subscript).replace("YYY", ref_node_name)
else:
for_read = text.c_read_gen.replace("XXX", "dummy" + "->" + child.attrib["name"] + array_subscript).replace("YYY", ref_node_name)
if child_count == 1:
read_source.write(for_read)
elif child_count > 1:
read_source.write(text.simple_loop.replace("YYY", for_read).replace("XXX", str(child_count)))
else: # child_count = -1
count_name_str = child.attrib["count"][6:]
read_source.write("dummy->" + child.attrib["name"] + " = " + "malloc(sizeof(" + type_resolver(child, self.def_elems + self.read_elems) + ")*" + "dummy->" + get_node_name(count_name_str, elem) + ");\n")
read_source.write("if (" + "dummy->" + get_node_name(count_name_str, elem) + ")\n")
read_source.write(text.simple_loop.replace("YYY", for_read).replace("XXX", "dummy->" + get_node_name(count_name_str, elem)))
else:
pass
# if not aggregate
# if its an aggregate type there is only a single element in the
# read funtion so we dont really need to worry about multiple
# instances with the same name
else:
read_source.write(static + inline + text.c_read_elem_sig.replace("YYY", elem.attrib["name"]).replace("XXX", elem.attrib["name"]+pointer))
read_source.write("dummy = malloc(sizeof(" + elem.attrib["name"] + "));\n")
read_source.write(text.c_read_gen.replace("XXX", "dummy->" + elem.attrib["name"]).replace("YYY", type_resolver(elem, self.def_elems)))
#read_source.write(text.c_function_return_type)
read_source.write("return dummy;\n")
read_source.write(text.c_function_close + "\n")
read_source_header = open(self.argparser.args.outdir + "/read.h", "w")
read_source_header.write("#ifndef FT_READ_H\n#define FT_READ_H\n")
read_source_header.write('#ifdef __cplusplus\nextern "C" {\n#endif\n')
read_source_header.write('#include "./structs.h"\n')
for elem in self.def_elems + self.read_elems:
read_source_header.write(static + inline + text.c_read_elem_sig_h.replace("YYY", elem.attrib["name"]).replace("XXX", elem.attrib["name"]))
read_source_header.write('#ifdef __cplusplus\n}\n#endif\n')
read_source_header.write("#endif //end of header guard\n\n")
def gen_void_train(self):
#void_source = open(self.argparser.args.outdir + "/void.h", "w")
void_source = open(self.aggregate_source, "w")
void_source_h = open(self.aggregate_source_h, "w")
void_source.write("\n// automatically generated by faultreiber\n")
void_source.write("// " + self.dnt + "\n")
void_source.write('#include "./structs.h"\n')
void_source.write('#include "./read.h"\n')
void_source.write("#include <stdlib.h>\n")
#void_source.write("void** void_train(void) {\n")
void_source_h.write('#ifndef FT_AGGREGATE_H\n#define FT_AGGREGATE_H\n')
void_source_h.write('#ifdef __cplusplus\nextern "C" {\n#endif\n')
void_source_h.write('#include "./structs.h"\n')
for elem in self.read_elems:
count = get_elem_count(elem)
size = get_elem_size(elem)
if count != 1:
void_source_h.write("extern " + elem.attrib["name"] + "** " + elem.attrib["name"] + "_container;\n")
void_source.write(elem.attrib["name"] + "** " + elem.attrib["name"] + "_container;\n")
else:
void_source_h.write("extern " + elem.attrib["name"] + "* " + elem.attrib["name"] + "_container;\n")
void_source.write(elem.attrib["name"] + "* " + elem.attrib["name"] + "_container;\n")
for child in elem:
ref_node_name = type_resolver(child, self.def_elems)
ref_node = get_def_node(ref_node_name, self.def_elems)
if ref_node:
count = get_elem_count(child)
size = get_elem_size(child)
if count != 1:
void_source_h.write("extern " + ref_node.attrib["name"] + "** " + elem.attrib["name"] + "_" + child.attrib["name"] + "_container;\n")
void_source.write(ref_node.attrib["name"] + "** " + elem.attrib["name"] + "_" + child.attrib["name"] + "_container;\n")
else:
void_source_h.write("extern " + ref_node.attrib["name"] + "* " + elem.attrib["name"] + "_" + child.attrib["name"] + "_container;\n")
void_source.write(ref_node.attrib["name"] + "* " + elem.attrib["name"] + "_" + child.attrib["name"] + "_container;\n")
void_source.write("void malloc_all(void) {\n")
void_source_h.write("void malloc_all(void);\n")
count_int = int()
count_void = int()
read_count = len(self.read_elems)
#extern = "extern "
extern = ""
#void_source.write("//TODO-assign sub-containers to contrainers here\n")
# FIXME-count and size present together is not being handled at all
for elem in self.read_elems:
#for elem in self.read_elems + self.def_elems:
if "isaggregate" in elem.attrib:
for child in elem:
ref_node_name = type_resolver(child, self.def_elems)
ref_node = get_def_node(ref_node_name, self.def_elems)
if ref_node: count_void+=1
count = get_elem_count(child)
size = get_elem_size(child)
type_width = get_type_width(child)
#print(elem.tag + " " + child.tag + " " + "count:" + str(count) + " " + "size:" + str(size) + " " + "typ_width:" + str(type_width))
if count > 0: count_int+=count*type_width
if count < 0: count_void+=1
if size > 0: count_int+=size
if size < 0: count_void+=1
sizeof = (str(count_int) if count_int > 0 else ("")) + ("+" if count_void>0 and count_int>0 else "") + ((str(count_void)+"*"+"sizeof(void*)") if count_void > 0 else "")
self.mem_size[elem.attrib["name"]] = text.c_reserve_void_ptr.replace("XXX", sizeof)
#void_source.write(elem.attrib["name"] + "* " + elem.attrib["name"] + "_container" + " = " + text.c_reserve_void_ptr.replace("XXX", sizeof) + ";\n")
void_source.write(elem.attrib["name"] + "_container" + " = " + text.c_reserve_void_ptr.replace("XXX", sizeof) + ";\n")
count_int = 0
count_void = 0
else:
ref_node_name = type_resolver(elem, self.def_elems)
ref_node = get_def_node(ref_node_name, self.def_elems)
if ref_node: count_void+=1
if "size" in elem.attrib:
count = get_elem_count(elem)
if count > 0: count_int+= count
else: count_void+=1
if "count" in elem.attrib:
size = get_elem_size(elem)
if size > 0: count_int+=size
else: count_void+=1
sizeof = (str(count_int)+"+" if count_int > 0 else "") + (str(count_void)+"*"+"sizeof(void*)") if count_void > 0 else ""
self.mem_size[elem.attrib["name"]] = text.c_reserve_void_ptr.replace("XXX", sizeof)
#void_source.write(elem.attrib["name"] + "* " + elem.attrib["name"] + "_container" + " = " + text.c_reserve_void_ptr.replace("XXX", sizeof) + ";\n")
void_source.write(elem.attrib["name"] + "_container" + " = " + text.c_reserve_void_ptr.replace("XXX", sizeof) + ";\n")
count_int = 0
count_void = 0
void_source.write("}\n")
void_source.write("void read_aggr(int _fd) {\n")
for elem in self.read_elems:
if "isaggregate" in elem.attrib:
for child in elem:
ref_node_name = type_resolver(child, self.def_elems)
ref_node = get_def_node(ref_node_name, self.def_elems)
if ref_node:
pass
#void_source.write(elem.attrib["name"] + "_container->" + child.attrib["name"] + " = " + elem.attrib["name"] + "_" + child.attrib["name"] + "_container" + ";\n")
def gen_aggregate_read(self):
agg_source = open(self.aggregate_source, "a")
agg_source_h = open(self.aggregate_source_h, "a")
agg_source_h.write("void read_aggr(int _fd);\n")
for elem in self.read_elems:
agg_source.write(elem.attrib["name"] + "_container = " + "ft_read_" + elem.attrib["name"] + "(_fd," + elem.attrib["name"] + "_container" + ");\n")
agg_source.write("}\n")
#FIXME-not handling double pointers
def gen_release(self):
agg_source = open(self.aggregate_source, "a")
agg_source_h = open(self.aggregate_source_h, "a")
agg_source_h.write("void release_all(void);\n")
agg_source.write("void release_all(void) {\n")
for elem in self.read_elems:
agg_source.write("free(" + elem.attrib["name"] + "_container);\n")
agg_source.write("}\n")
def gen_return(self):
agg_source = open(self.aggregate_source, "a")
agg_source_h = open(self.aggregate_source_h, "a")
for elem in self.read_elems:
agg_source.write(elem.attrib["name"] + "* ft_ret_" + elem.attrib["name"] + "(void) {\n")
agg_source.write("return " + elem.attrib["name"] + "_container"+ ";\n")
agg_source.write("}\n")
agg_source_h.write(elem.attrib["name"] + "* ft_ret_" + elem.attrib["name"] + "(void);\n")
agg_source_h.write('#ifdef __cplusplus\n}\n#endif\n')
agg_source_h.write("#endif //end of header guard\n\n")
def read_xml(self):
if self.argparser.args.xml:
def_header = open(self.argparser.args.outdir + "/defines.h", "w")
def_header.write("\n// automatically generated by faultreiber\n")
def_header.write("// " + self.dnt + "\n")
def_header.write(text.header_inttype + "\n")
tree = xml.etree.ElementTree.parse(self.argparser.args.xml)
root = tree.getroot()
read_tree = xml.etree.ElementTree.Element("read")
def_tree = xml.etree.ElementTree.Element("def")
for child in root:
if child.tag == "Read":
read_tree = child
if child.tag == "Definition":
def_tree = child
for child in read_tree:
self.read_elems.append(child)
for child in def_tree:
self.def_elems.append(child)
read_iter = read_tree.iter(tag=None)
def_iter = def_tree.iter(tag=None)
self.read_iter = read_iter
self.def_iter = def_iter
for child in def_iter:
self.elems.append(child)
if "isaggregate" in child.attrib:
def_header.write("typedef struct {\n")
for childerer in child:
c_type = type_resolver(childerer, self.elems)
def_header.write("\t" + c_type + " " + childerer.attrib["name"] + ";\n")
def_header.write("}" + child.attrib["name"] + ";\n\n")
for child in read_iter:
self.elems.append(child)
if "isaggregate" in child.attrib:
def_header.write("typedef struct {\n")
for childerer in child:
c_type = type_resolver(childerer, self.elems)
def_header.write("\t" + c_type + " " + childerer.attrib["name"] + ";\n")
def_header.write("}" + child.attrib["name"] + ";\n\n")
def gen_struct_header_xml(self):
struct_source = open(self.struct_source_h, "w")
struct_source_c = open(get_full_path(self.argparser.args.outdir, "structs.c"), "w")
struct_source.write("#ifndef FT_STRUCTS_H\n#define FT_STRUCTS_H\n")
struct_source_c.write('#include "structs.h"')
struct_source.write('#include <unistd.h>')
struct_source.write(text.pre_header_guard)
struct_source.write(text.autogen_warning)
if self.argparser.args.datetime: struct_source.write("// " + self.dnt + "\n")
struct_source.write(text.header_guard_begin.replace("XXX", "structs".upper()))
struct_source.write(text.header_inttype)
struct_source_c.write(text.c_read_leb_u_def + "\n")
struct_source_c.write(text.c_read_leb_s_def + "\n")
struct_source.write(text.c_read_leb_128_u_sig + "\n")
struct_source.write(text.c_read_leb_128_s_sig + "\n")
#struct_source.write(text.c_read_leb_macro_defs + "\n")
if self.argparser.args.structsinclude:
copy(self.argparser.args.structsinclude, self.argparser.args.outdir)
pos = self.argparser.args.structsinclude.rfind("/")
sub = self.argparser.args.structsinclude[pos+1:]
struct_source.write('#include "' + sub + '"\n\n')
for child in self.def_elems + self.read_elems:
struct_source.write("typedef struct {\n")
if not "isaggregate" in child.attrib:
ref_type = type_resolver(child, self.def_elems + self.read_elems)
def_node = get_def_node(ref_type, self.def_elems + self.read_elems)
pointer = str()
if "count" in child.attrib:
if child.attrib["count"] != "1":
pointer = "*"
if def_node:
struct_source.write(ref_type + pointer + "* " + child.attrib["name"] + ";\n")
else:
struct_source.write(ref_type + pointer + " " + child.attrib["name"] + ";\n")
for childer in child:
ref_type = type_resolver(childer, self.def_elems + self.read_elems)
def_node = get_def_node(ref_type, self.def_elems + self.read_elems)
pointer = str()
if "count" in childer.attrib:
if childer.attrib["count"] != "1":
pointer = "*"
if def_node:
struct_source.write(ref_type + pointer + "* " + childer.attrib["name"] + ";\n")
else:
struct_source.write(ref_type + pointer + " " + childer.attrib["name"] + ";\n")
struct_source.write("}" + child.attrib["name"] + ";\n\n")
struct_source.write(text.pragma_endif)
struct_source.write("#endif //end of header guard\n")
#struct_source.write(text.last_comment)
def gen_struct_header(self):
struct_source = open(get_full_path(self.argparser.args.outdir, "structs.h"), "w")
struct_source_c = open(get_full_path(self.argparser.args.outdir, "structs.c"), "w")
struct_source_c.write('#include "structs.h"')
struct_source.write(text.pre_header_guard)
struct_source.write(text.autogen_warning)
if self.argparser.args.datetime: struct_source.write("// " + self.dnt + "\n")
struct_source.write(text.header_guard_begin.replace("XXX", "structs".upper()))
struct_source.write(text.header_inttype)
if self.argparser.args.structsinclude:
copy(self.argparser.args.structsinclude, self.argparser.args.outdir)
pos = self.argparser.args.structsinclude.rfind("/")
sub = self.argparser.args.structsinclude[pos+1:]
struct_source.write('#include "' + sub + '"\n')
for k,v in self.struct_json.items():
struct_name = k
field_names = v["field_name"]
field_typess = v["field_type"]
struct_source.write("typedef struct {\n")
for i, j in zip(field_names, field_typess):
struct_source.write("\t" + j + " " + i + ";\n")
struct_source.write("}" + struct_name + ";\n\n")
struct_source.write(text.pragma_endif)
struct_source.write(text.last_comment)
def run(self):
self.init()
self.init_hook()
self.file_manager()
#self.gen_struct_header()
self.read_xml()
self.gen_reader_funcs()
self.gen_struct_header_xml()
#self.dump_def_elems()
#self.dump_read_elems()
self.gen_void_train()
self.gen_aggregate_read()
#self.dump_mem_dict()
#self.dump_all_childs()
self.gen_release()
self.gen_return()
# write code here
def premain(argparser):
signal.signal(signal.SIGINT, SigHandler_SIGINT)
#here
codegen = CodeGen(argparser)
codegen.run()
def main():
argparser = Argparser()
if argparser.args.dbg:
try:
premain(argparser)
except Exception as e:
print(e.__doc__)
if e.message: print(e.message)
variables = globals().copy()
variables.update(locals())
shell = code.InteractiveConsole(variables)
shell.interact(banner="DEBUG REPL")
else:
premain(argparser)
if __name__ == "__main__":
main()