#!/usr/bin/env python3 import argparse import tempfile import struct import copy import sys import re import os from collections import namedtuple from io import StringIO MAX_FN_SIZE = 100 SLOW_CHECKS = False EI_NIDENT = 16 EI_CLASS = 4 EI_DATA = 5 EI_VERSION = 6 EI_OSABI = 7 EI_ABIVERSION = 8 STN_UNDEF = 0 SHN_UNDEF = 0 SHN_ABS = 0xfff1 SHN_COMMON = 0xfff2 SHN_XINDEX = 0xffff SHN_LORESERVE = 0xff00 STT_NOTYPE = 0 STT_OBJECT = 1 STT_FUNC = 2 STT_SECTION = 3 STT_FILE = 4 STT_COMMON = 5 STT_TLS = 6 STB_LOCAL = 0 STB_GLOBAL = 1 STB_WEAK = 2 STV_DEFAULT = 0 STV_INTERNAL = 1 STV_HIDDEN = 2 STV_PROTECTED = 3 SHT_NULL = 0 SHT_PROGBITS = 1 SHT_SYMTAB = 2 SHT_STRTAB = 3 SHT_RELA = 4 SHT_HASH = 5 SHT_DYNAMIC = 6 SHT_NOTE = 7 SHT_NOBITS = 8 SHT_REL = 9 SHT_SHLIB = 10 SHT_DYNSYM = 11 SHT_INIT_ARRAY = 14 SHT_FINI_ARRAY = 15 SHT_PREINIT_ARRAY = 16 SHT_GROUP = 17 SHT_SYMTAB_SHNDX = 18 SHT_MIPS_GPTAB = 0x70000003 SHT_MIPS_DEBUG = 0x70000005 SHT_MIPS_REGINFO = 0x70000006 SHT_MIPS_OPTIONS = 0x7000000d SHF_WRITE = 0x1 SHF_ALLOC = 0x2 SHF_EXECINSTR = 0x4 SHF_MERGE = 0x10 SHF_STRINGS = 0x20 SHF_INFO_LINK = 0x40 SHF_LINK_ORDER = 0x80 SHF_OS_NONCONFORMING = 0x100 SHF_GROUP = 0x200 SHF_TLS = 0x400 R_MIPS_32 = 2 R_MIPS_26 = 4 R_MIPS_HI16 = 5 R_MIPS_LO16 = 6 class ElfHeader: """ typedef struct { unsigned char e_ident[EI_NIDENT]; Elf32_Half e_type; Elf32_Half e_machine; Elf32_Word e_version; Elf32_Addr e_entry; Elf32_Off e_phoff; Elf32_Off e_shoff; Elf32_Word e_flags; Elf32_Half e_ehsize; Elf32_Half e_phentsize; Elf32_Half e_phnum; Elf32_Half e_shentsize; Elf32_Half e_shnum; Elf32_Half e_shstrndx; } Elf32_Ehdr; """ def __init__(self, data): self.e_ident = data[:EI_NIDENT] self.e_type, self.e_machine, self.e_version, self.e_entry, self.e_phoff, self.e_shoff, self.e_flags, self.e_ehsize, self.e_phentsize, self.e_phnum, self.e_shentsize, self.e_shnum, self.e_shstrndx = struct.unpack('>HHIIIIIHHHHHH', data[EI_NIDENT:]) assert self.e_ident[EI_CLASS] == 1 # 32-bit assert self.e_ident[EI_DATA] == 2 # big-endian assert self.e_type == 1 # relocatable assert self.e_machine == 8 # MIPS I Architecture assert self.e_phoff == 0 # no program header assert self.e_shoff != 0 # section header assert self.e_shstrndx != SHN_UNDEF def to_bin(self): return self.e_ident + struct.pack('>HHIIIIIHHHHHH', self.e_type, self.e_machine, self.e_version, self.e_entry, self.e_phoff, self.e_shoff, self.e_flags, self.e_ehsize, self.e_phentsize, self.e_phnum, self.e_shentsize, self.e_shnum, self.e_shstrndx) class Symbol: """ typedef struct { Elf32_Word st_name; Elf32_Addr st_value; Elf32_Word st_size; unsigned char st_info; unsigned char st_other; Elf32_Half st_shndx; } Elf32_Sym; """ def __init__(self, data, strtab): self.st_name, self.st_value, self.st_size, st_info, self.st_other, self.st_shndx = struct.unpack('>IIIBBH', data) assert self.st_shndx != SHN_XINDEX, "too many sections (SHN_XINDEX not supported)" self.bind = st_info >> 4 self.type = st_info & 15 self.name = strtab.lookup_str(self.st_name) self.visibility = self.st_other & 3 def to_bin(self): st_info = (self.bind << 4) | self.type return struct.pack('>IIIBBH', self.st_name, self.st_value, self.st_size, st_info, self.st_other, self.st_shndx) class Relocation: def __init__(self, data, sh_type): self.sh_type = sh_type if sh_type == SHT_REL: self.r_offset, self.r_info = struct.unpack('>II', data) else: self.r_offset, self.r_info, self.r_addend = struct.unpack('>III', data) self.sym_index = self.r_info >> 8 self.rel_type = self.r_info & 0xff def to_bin(self): self.r_info = (self.sym_index << 8) | self.rel_type if self.sh_type == SHT_REL: return struct.pack('>II', self.r_offset, self.r_info) else: return struct.pack('>III', self.r_offset, self.r_info, self.r_addend) class Section: """ typedef struct { Elf32_Word sh_name; Elf32_Word sh_type; Elf32_Word sh_flags; Elf32_Addr sh_addr; Elf32_Off sh_offset; Elf32_Word sh_size; Elf32_Word sh_link; Elf32_Word sh_info; Elf32_Word sh_addralign; Elf32_Word sh_entsize; } Elf32_Shdr; """ def __init__(self, header, data, index): self.sh_name, self.sh_type, self.sh_flags, self.sh_addr, self.sh_offset, self.sh_size, self.sh_link, self.sh_info, self.sh_addralign, self.sh_entsize = struct.unpack('>IIIIIIIIII', header) assert not self.sh_flags & SHF_LINK_ORDER if self.sh_entsize != 0: assert self.sh_size % self.sh_entsize == 0 if self.sh_type == SHT_NOBITS: self.data = b'' else: self.data = data[self.sh_offset:self.sh_offset + self.sh_size] self.index = index self.relocated_by = [] @staticmethod def from_parts(sh_name, sh_type, sh_flags, sh_link, sh_info, sh_addralign, sh_entsize, data, index): header = struct.pack('>IIIIIIIIII', sh_name, sh_type, sh_flags, 0, 0, len(data), sh_link, sh_info, sh_addralign, sh_entsize) return Section(header, data, index) def lookup_str(self, index): assert self.sh_type == SHT_STRTAB to = self.data.find(b'\0', index) assert to != -1 return self.data[index:to].decode('latin1') def add_str(self, string): assert self.sh_type == SHT_STRTAB ret = len(self.data) self.data += string.encode('latin1') + b'\0' return ret def is_rel(self): return self.sh_type == SHT_REL or self.sh_type == SHT_RELA def header_to_bin(self): if self.sh_type != SHT_NOBITS: self.sh_size = len(self.data) return struct.pack('>IIIIIIIIII', self.sh_name, self.sh_type, self.sh_flags, self.sh_addr, self.sh_offset, self.sh_size, self.sh_link, self.sh_info, self.sh_addralign, self.sh_entsize) def late_init(self, sections): if self.sh_type == SHT_SYMTAB: self.init_symbols(sections) elif self.is_rel(): self.rel_target = sections[self.sh_info] self.rel_target.relocated_by.append(self) self.init_relocs() def find_symbol(self, name): assert self.sh_type == SHT_SYMTAB for s in self.symbol_entries: if s.name == name: return (s.st_shndx, s.st_value) return None def find_symbol_in_section(self, name, section): pos = self.find_symbol(name) assert pos is not None assert pos[0] == section.index return pos[1] def init_symbols(self, sections): assert self.sh_type == SHT_SYMTAB assert self.sh_entsize == 16 self.strtab = sections[self.sh_link] entries = [] for i in range(0, self.sh_size, self.sh_entsize): entries.append(Symbol(self.data[i:i+self.sh_entsize], self.strtab)) self.symbol_entries = entries def init_relocs(self): assert self.is_rel() entries = [] for i in range(0, self.sh_size, self.sh_entsize): entries.append(Relocation(self.data[i:i+self.sh_entsize], self.sh_type)) self.relocations = entries def local_symbols(self): assert self.sh_type == SHT_SYMTAB return self.symbol_entries[:self.sh_info] def global_symbols(self): assert self.sh_type == SHT_SYMTAB return self.symbol_entries[self.sh_info:] class ElfFile: def __init__(self, data): self.data = data assert data[:4] == b'\x7fELF', "not an ELF file" self.elf_header = ElfHeader(data[0:52]) offset, size = self.elf_header.e_shoff, self.elf_header.e_shentsize null_section = Section(data[offset:offset + size], data, 0) num_sections = self.elf_header.e_shnum or null_section.sh_size self.sections = [null_section] for i in range(1, num_sections): ind = offset + i * size self.sections.append(Section(data[ind:ind + size], data, i)) symtab = None for s in self.sections: if s.sh_type == SHT_SYMTAB: assert not symtab symtab = s assert symtab is not None self.symtab = symtab shstr = self.sections[self.elf_header.e_shstrndx] for s in self.sections: s.name = shstr.lookup_str(s.sh_name) s.late_init(self.sections) def find_section(self, name): for s in self.sections: if s.name == name: return s return None def add_section(self, name, sh_type, sh_flags, sh_link, sh_info, sh_addralign, sh_entsize, data): shstr = self.sections[self.elf_header.e_shstrndx] sh_name = shstr.add_str(name) s = Section.from_parts(sh_name=sh_name, sh_type=sh_type, sh_flags=sh_flags, sh_link=sh_link, sh_info=sh_info, sh_addralign=sh_addralign, sh_entsize=sh_entsize, data=data, index=len(self.sections)) self.sections.append(s) s.name = name s.late_init(self.sections) return s def drop_irrelevant_sections(self): # We can only drop sections at the end, since otherwise section # references might be wrong. Luckily, these sections typically are. while self.sections[-1].sh_type in [SHT_MIPS_DEBUG, SHT_MIPS_GPTAB]: self.sections.pop() def write(self, filename): outfile = open(filename, 'wb') outidx = 0 def write_out(data): nonlocal outidx outfile.write(data) outidx += len(data) def pad_out(align): if align and outidx % align: write_out(b'\0' * (align - outidx % align)) self.elf_header.e_shnum = len(self.sections) write_out(self.elf_header.to_bin()) for s in self.sections: if s.sh_type != SHT_NOBITS and s.sh_type != SHT_NULL: pad_out(s.sh_addralign) s.sh_offset = outidx write_out(s.data) pad_out(4) self.elf_header.e_shoff = outidx for s in self.sections: write_out(s.header_to_bin()) outfile.seek(0) outfile.write(self.elf_header.to_bin()) outfile.close() def is_temp_name(name): return name.startswith('_asmpp_') # https://stackoverflow.com/a/241506 def re_comment_replacer(match): s = match.group(0) if s[0] in "/#": return " " else: return s re_comment_or_string = re.compile( r'#.*|/\*.*?\*/|"(?:\\.|[^\\"])*"' ) class Failure(Exception): def __init__(self, message): self.message = message def __str__(self): return self.message class GlobalState: def __init__(self, min_instr_count, skip_instr_count, use_jtbl_for_rodata): # A value that hopefully never appears as a 32-bit rodata constant (or we # miscompile late rodata). Increases by 1 in each step. self.late_rodata_hex = 0xE0123456 self.namectr = 0 self.min_instr_count = min_instr_count self.skip_instr_count = skip_instr_count self.use_jtbl_for_rodata = use_jtbl_for_rodata def next_late_rodata_hex(self): dummy_bytes = struct.pack('>I', self.late_rodata_hex) if (self.late_rodata_hex & 0xffff) == 0: # Avoid lui self.late_rodata_hex += 1 self.late_rodata_hex += 1 return dummy_bytes def make_name(self, cat): self.namectr += 1 return '_asmpp_{}{}'.format(cat, self.namectr) Function = namedtuple('Function', ['text_glabels', 'asm_conts', 'late_rodata_dummy_bytes', 'jtbl_rodata_size', 'late_rodata_asm_conts', 'fn_desc', 'data']) class GlobalAsmBlock: def __init__(self, fn_desc): self.fn_desc = fn_desc self.cur_section = '.text' self.asm_conts = [] self.late_rodata_asm_conts = [] self.late_rodata_alignment = 0 self.late_rodata_alignment_from_content = False self.text_glabels = [] self.fn_section_sizes = { '.text': 0, '.data': 0, '.bss': 0, '.rodata': 0, '.late_rodata': 0, } self.fn_ins_inds = [] self.glued_line = '' self.num_lines = 0 def fail(self, message, line=None): context = self.fn_desc if line: context += ", at line \"" + line + "\"" raise Failure(message + "\nwithin " + context) def count_quoted_size(self, line, z, real_line, output_enc): line = line.encode(output_enc).decode('latin1') in_quote = False num_parts = 0 ret = 0 i = 0 digits = "0123456789" # 0-7 would be more sane, but this matches GNU as while i < len(line): c = line[i] i += 1 if not in_quote: if c == '"': in_quote = True num_parts += 1 else: if c == '"': in_quote = False continue ret += 1 if c != '\\': continue if i == len(line): self.fail("backslash at end of line not supported", real_line) c = line[i] i += 1 # (if c is in "bfnrtv", we have a real escaped literal) if c == 'x': # hex literal, consume any number of hex chars, possibly none while i < len(line) and line[i] in digits + "abcdefABCDEF": i += 1 elif c in digits: # octal literal, consume up to two more digits it = 0 while i < len(line) and line[i] in digits and it < 2: i += 1 it += 1 if in_quote: self.fail("unterminated string literal", real_line) if num_parts == 0: self.fail(".ascii with no string", real_line) return ret + num_parts if z else ret def align2(self): while self.fn_section_sizes[self.cur_section] % 2 != 0: self.fn_section_sizes[self.cur_section] += 1 def align4(self): while self.fn_section_sizes[self.cur_section] % 4 != 0: self.fn_section_sizes[self.cur_section] += 1 def add_sized(self, size, line): if self.cur_section in ['.text', '.late_rodata']: if size % 4 != 0: self.fail("size must be a multiple of 4", line) if size < 0: self.fail("size cannot be negative", line) self.fn_section_sizes[self.cur_section] += size if self.cur_section == '.text': if not self.text_glabels: self.fail(".text block without an initial glabel", line) self.fn_ins_inds.append((self.num_lines - 1, size // 4)) def process_line(self, line, output_enc): self.num_lines += 1 if line.endswith('\\'): self.glued_line += line[:-1] return line = self.glued_line + line self.glued_line = '' real_line = line line = re.sub(re_comment_or_string, re_comment_replacer, line) line = line.strip() line = re.sub(r'^[a-zA-Z0-9_]+:\s*', '', line) changed_section = False emitting_double = False if line.startswith('glabel ') and self.cur_section == '.text': self.text_glabels.append(line.split()[1]) if not line: pass # empty line elif line.startswith('glabel ') or (' ' not in line and line.endswith(':')): pass # label elif line.startswith('.section') or line in ['.text', '.data', '.rdata', '.rodata', '.bss', '.late_rodata']: # section change self.cur_section = '.rodata' if line == '.rdata' else line.split(',')[0].split()[-1] if self.cur_section not in ['.data', '.text', '.rodata', '.late_rodata', '.bss']: self.fail("unrecognized .section directive", real_line) changed_section = True elif line.startswith('.late_rodata_alignment'): if self.cur_section != '.late_rodata': self.fail(".late_rodata_alignment must occur within .late_rodata section", real_line) value = int(line.split()[1]) if value not in [4, 8]: self.fail(".late_rodata_alignment argument must be 4 or 8", real_line) if self.late_rodata_alignment and self.late_rodata_alignment != value: self.fail(".late_rodata_alignment alignment assumption conflicts with earlier .double directive. Make sure to provide explicit alignment padding.") self.late_rodata_alignment = value changed_section = True elif line.startswith('.incbin'): self.add_sized(int(line.split(',')[-1].strip(), 0), real_line) elif line.startswith('.word') or line.startswith('.float'): self.align4() self.add_sized(4 * len(line.split(',')), real_line) elif line.startswith('.double'): self.align4() if self.cur_section == '.late_rodata': align8 = self.fn_section_sizes[self.cur_section] % 8 # Automatically set late_rodata_alignment, so the generated C code uses doubles. # This gives us correct alignment for the transferred doubles even when the # late_rodata_alignment is wrong, e.g. for non-matching compilation. if not self.late_rodata_alignment: self.late_rodata_alignment = 8 - align8 self.late_rodata_alignment_from_content = True elif self.late_rodata_alignment != 8 - align8: if self.late_rodata_alignment_from_content: self.fail("found two .double directives with different start addresses mod 8. Make sure to provide explicit alignment padding.", real_line) else: self.fail(".double at address that is not 0 mod 8 (based on .late_rodata_alignment assumption). Make sure to provide explicit alignment padding.", real_line) self.add_sized(8 * len(line.split(',')), real_line) emitting_double = True elif line.startswith('.space'): self.add_sized(int(line.split()[1], 0), real_line) elif line.startswith('.balign') or line.startswith('.align'): align = int(line.split()[1]) if align != 4: self.fail("only .balign 4 is supported", real_line) self.align4() elif line.startswith('.asci'): z = (line.startswith('.asciz') or line.startswith('.asciiz')) self.add_sized(self.count_quoted_size(line, z, real_line, output_enc), real_line) elif line.startswith('.byte'): self.add_sized(len(line.split(',')), real_line) elif line.startswith('.half'): self.align2() self.add_sized(2*len(line.split(',')), real_line) elif line.startswith('.'): # .macro, ... self.fail("asm directive not supported", real_line) else: # Unfortunately, macros are hard to support for .rodata -- # we don't know how how space they will expand to before # running the assembler, but we need that information to # construct the C code. So if we need that we'll either # need to run the assembler twice (at least in some rare # cases), or change how this program is invoked. # Similarly, we can't currently deal with pseudo-instructions # that expand to several real instructions. if self.cur_section != '.text': self.fail("instruction or macro call in non-.text section? not supported", real_line) self.add_sized(4, real_line) if self.cur_section == '.late_rodata': if not changed_section: if emitting_double: self.late_rodata_asm_conts.append(".align 0") self.late_rodata_asm_conts.append(real_line) if emitting_double: self.late_rodata_asm_conts.append(".align 2") else: self.asm_conts.append(real_line) def finish(self, state): src = [''] * (self.num_lines + 1) late_rodata_dummy_bytes = [] jtbl_rodata_size = 0 late_rodata_fn_output = [] num_instr = self.fn_section_sizes['.text'] // 4 if self.fn_section_sizes['.late_rodata'] > 0: # Generate late rodata by emitting unique float constants. # This requires 3 instructions for each 4 bytes of rodata. # If we know alignment, we can use doubles, which give 3 # instructions for 8 bytes of rodata. size = self.fn_section_sizes['.late_rodata'] // 4 skip_next = False needs_double = (self.late_rodata_alignment != 0) for i in range(size): if skip_next: skip_next = False continue # Jump tables give 9 instructions for >= 5 words of rodata, and should be # emitted when: # - -O2 or -O2 -g3 are used, which give the right codegen # - we have emitted our first .float/.double (to ensure that we find the # created rodata in the binary) # - we have emitted our first .double, if any (to ensure alignment of doubles # in shifted rodata sections) # - we have at least 5 words of rodata left to emit (otherwise IDO does not # generate a jump table) # - we have at least 10 more instructions to go in this function (otherwise our # function size computation will be wrong since the delay slot goes unused) if (not needs_double and state.use_jtbl_for_rodata and i >= 1 and size - i >= 5 and num_instr - len(late_rodata_fn_output) >= 10): cases = " ".join("case {}:".format(case) for case in range(size - i)) late_rodata_fn_output.append("switch (*(volatile int*)0) { " + cases + " ; }") late_rodata_fn_output.extend([""] * 8) jtbl_rodata_size = (size - i) * 4 break dummy_bytes = state.next_late_rodata_hex() late_rodata_dummy_bytes.append(dummy_bytes) if self.late_rodata_alignment == 4 * ((i + 1) % 2 + 1) and i + 1 < size: dummy_bytes2 = state.next_late_rodata_hex() late_rodata_dummy_bytes.append(dummy_bytes2) fval, = struct.unpack('>d', dummy_bytes + dummy_bytes2) late_rodata_fn_output.append('*(volatile double*)0 = {};'.format(fval)) skip_next = True needs_double = True else: fval, = struct.unpack('>f', dummy_bytes) late_rodata_fn_output.append('*(volatile float*)0 = {}f;'.format(fval)) late_rodata_fn_output.append('') late_rodata_fn_output.append('') text_name = None if self.fn_section_sizes['.text'] > 0 or late_rodata_fn_output: text_name = state.make_name('func') src[0] = 'void {}(void) {{'.format(text_name) src[self.num_lines] = '}' instr_count = self.fn_section_sizes['.text'] // 4 if instr_count < state.min_instr_count: self.fail("too short .text block") tot_emitted = 0 tot_skipped = 0 fn_emitted = 0 fn_skipped = 0 rodata_stack = late_rodata_fn_output[::-1] for (line, count) in self.fn_ins_inds: for _ in range(count): if (fn_emitted > MAX_FN_SIZE and instr_count - tot_emitted > state.min_instr_count and (not rodata_stack or rodata_stack[-1])): # Don't let functions become too large. When a function reaches 284 # instructions, and -O2 -framepointer flags are passed, the IRIX # compiler decides it is a great idea to start optimizing more. fn_emitted = 0 fn_skipped = 0 src[line] += ' }} void {}(void) {{ '.format(state.make_name('large_func')) if fn_skipped < state.skip_instr_count: fn_skipped += 1 tot_skipped += 1 elif rodata_stack: src[line] += rodata_stack.pop() else: src[line] += '*(volatile int*)0 = 0;' tot_emitted += 1 fn_emitted += 1 if rodata_stack: size = len(late_rodata_fn_output) // 3 available = instr_count - tot_skipped self.fail( "late rodata to text ratio is too high: {} / {} must be <= 1/3\n" "add .late_rodata_alignment (4|8) to the .late_rodata " "block to double the allowed ratio." .format(size, available)) rodata_name = None if self.fn_section_sizes['.rodata'] > 0: rodata_name = state.make_name('rodata') src[self.num_lines] += ' const char {}[{}] = {{1}};'.format(rodata_name, self.fn_section_sizes['.rodata']) data_name = None if self.fn_section_sizes['.data'] > 0: data_name = state.make_name('data') src[self.num_lines] += ' char {}[{}] = {{1}};'.format(data_name, self.fn_section_sizes['.data']) bss_name = None if self.fn_section_sizes['.bss'] > 0: bss_name = state.make_name('bss') src[self.num_lines] += ' char {}[{}];'.format(bss_name, self.fn_section_sizes['.bss']) fn = Function( text_glabels=self.text_glabels, asm_conts=self.asm_conts, late_rodata_dummy_bytes=late_rodata_dummy_bytes, jtbl_rodata_size=jtbl_rodata_size, late_rodata_asm_conts=self.late_rodata_asm_conts, fn_desc=self.fn_desc, data={ '.text': (text_name, self.fn_section_sizes['.text']), '.data': (data_name, self.fn_section_sizes['.data']), '.rodata': (rodata_name, self.fn_section_sizes['.rodata']), '.bss': (bss_name, self.fn_section_sizes['.bss']), }) return src, fn cutscene_data_regexpr = re.compile(r"CutsceneData (.|\n)*\[\] = {") float_regexpr = re.compile(r"[-+]?[0-9]*\.?[0-9]+([eE][-+]?[0-9]+)?f") def repl_float_hex(m): return str(struct.unpack(">I", struct.pack(">f", float(m.group(0).strip().rstrip("f"))))[0]) def parse_source(f, opt, framepointer, input_enc, output_enc, print_source=None): if opt in ['O2', 'O1']: if framepointer: min_instr_count = 6 skip_instr_count = 5 else: min_instr_count = 2 skip_instr_count = 1 elif opt == 'g': if framepointer: min_instr_count = 7 skip_instr_count = 7 else: min_instr_count = 4 skip_instr_count = 4 else: if opt != 'g3': raise Failure("must pass one of -g, -O1, -O2, -O2 -g3") if framepointer: min_instr_count = 4 skip_instr_count = 4 else: min_instr_count = 2 skip_instr_count = 2 use_jtbl_for_rodata = False if opt in ['O2', 'g3'] and not framepointer: use_jtbl_for_rodata = True state = GlobalState(min_instr_count, skip_instr_count, use_jtbl_for_rodata) global_asm = None asm_functions = [] output_lines = [] is_cutscene_data = False for line_no, raw_line in enumerate(f, 1): raw_line = raw_line.rstrip() line = raw_line.lstrip() # Print exactly one output line per source line, to make compiler # errors have correct line numbers. These will be overridden with # reasonable content further down. output_lines.append('') if global_asm is not None: if line.startswith(')'): src, fn = global_asm.finish(state) for i, line2 in enumerate(src): output_lines[start_index + i] = line2 asm_functions.append(fn) global_asm = None else: global_asm.process_line(raw_line, output_enc) else: if line in ['GLOBAL_ASM(', '#pragma GLOBAL_ASM(']: global_asm = GlobalAsmBlock("GLOBAL_ASM block at line " + str(line_no)) start_index = len(output_lines) elif ((line.startswith('GLOBAL_ASM("') or line.startswith('#pragma GLOBAL_ASM("')) and line.endswith('")')): fname = line[line.index('(') + 2 : -2] global_asm = GlobalAsmBlock(fname) with open(fname, encoding=input_enc) as f: for line2 in f: global_asm.process_line(line2.rstrip(), output_enc) src, fn = global_asm.finish(state) output_lines[-1] = ''.join(src) asm_functions.append(fn) global_asm = None elif line.startswith('#include "') and line.endswith('" EARLY'): # C includes qualified with EARLY (i.e. #include "file.c" EARLY) will be # processed recursively when encountered fpath = os.path.dirname(f.name) fname = line[line.index(' ') + 2 : -7] include_src = StringIO() with open(fpath + os.path.sep + fname, encoding=input_enc) as include_file: parse_source(include_file, opt, framepointer, input_enc, output_enc, include_src) output_lines[-1] = include_src.getvalue() include_src.write('#line ' + str(line_no) + '\n') include_src.close() else: # This is a hack to replace all floating-point numbers in an array of a particular type # (in this case CutsceneData) with their corresponding IEEE-754 hexadecimal representation if cutscene_data_regexpr.search(line) is not None: is_cutscene_data = True elif line.endswith("};"): is_cutscene_data = False if is_cutscene_data: raw_line = re.sub(float_regexpr, repl_float_hex, raw_line) output_lines[-1] = raw_line if print_source: if isinstance(print_source, StringIO): for line in output_lines: print_source.write(line + '\n') else: for line in output_lines: print_source.write(line.encode(output_enc) + b'\n') print_source.flush() if print_source != sys.stdout.buffer: print_source.close() return asm_functions def fixup_objfile(objfile_name, functions, asm_prelude, assembler, output_enc): SECTIONS = ['.data', '.text', '.rodata', '.bss'] with open(objfile_name, 'rb') as f: objfile = ElfFile(f.read()) prev_locs = { '.text': 0, '.data': 0, '.rodata': 0, '.bss': 0, } to_copy = { '.text': [], '.data': [], '.rodata': [], '.bss': [], } asm = [] all_late_rodata_dummy_bytes = [] all_jtbl_rodata_size = [] late_rodata_asm = [] late_rodata_source_name_start = None late_rodata_source_name_end = None # Generate an assembly file with all the assembly we need to fill in. For # simplicity we pad with nops/.space so that addresses match exactly, so we # don't have to fix up relocations/symbol references. all_text_glabels = set() for function in functions: ifdefed = False for sectype, (temp_name, size) in function.data.items(): if temp_name is None: continue assert size > 0 loc = objfile.symtab.find_symbol(temp_name) if loc is None: ifdefed = True break loc = loc[1] prev_loc = prev_locs[sectype] if loc < prev_loc: raise Failure("Wrongly computed size for section {} (diff {}). This is an asm-processor bug!".format(sectype, prev_loc- loc)) if loc != prev_loc: asm.append('.section ' + sectype) if sectype == '.text': for i in range((loc - prev_loc) // 4): asm.append('nop') else: asm.append('.space {}'.format(loc - prev_loc)) to_copy[sectype].append((loc, size, temp_name, function.fn_desc)) prev_locs[sectype] = loc + size if not ifdefed: all_text_glabels.update(function.text_glabels) all_late_rodata_dummy_bytes.append(function.late_rodata_dummy_bytes) all_jtbl_rodata_size.append(function.jtbl_rodata_size) late_rodata_asm.append(function.late_rodata_asm_conts) for sectype, (temp_name, size) in function.data.items(): if temp_name is not None: asm.append('.section ' + sectype) asm.append('glabel ' + temp_name + '_asm_start') asm.append('.text') for line in function.asm_conts: asm.append(line) for sectype, (temp_name, size) in function.data.items(): if temp_name is not None: asm.append('.section ' + sectype) asm.append('glabel ' + temp_name + '_asm_end') if any(late_rodata_asm): late_rodata_source_name_start = '_asmpp_late_rodata_start' late_rodata_source_name_end = '_asmpp_late_rodata_end' asm.append('.rdata') asm.append('glabel {}'.format(late_rodata_source_name_start)) for conts in late_rodata_asm: asm.extend(conts) asm.append('glabel {}'.format(late_rodata_source_name_end)) o_file = tempfile.NamedTemporaryFile(prefix='asm-processor', suffix='.o', delete=False) o_name = o_file.name o_file.close() s_file = tempfile.NamedTemporaryFile(prefix='asm-processor', suffix='.s', delete=False) s_name = s_file.name try: s_file.write(asm_prelude + b'\n') for line in asm: s_file.write(line.encode(output_enc) + b'\n') s_file.close() ret = os.system(assembler + " " + s_name + " -o " + o_name) if ret != 0: raise Failure("failed to assemble") with open(o_name, 'rb') as f: asm_objfile = ElfFile(f.read()) # Remove some clutter from objdump output objfile.drop_irrelevant_sections() # Unify reginfo sections target_reginfo = objfile.find_section('.reginfo') source_reginfo_data = list(asm_objfile.find_section('.reginfo').data) data = list(target_reginfo.data) for i in range(20): data[i] |= source_reginfo_data[i] target_reginfo.data = bytes(data) # Move over section contents modified_text_positions = set() jtbl_rodata_positions = set() last_rodata_pos = 0 for sectype in SECTIONS: if not to_copy[sectype]: continue source = asm_objfile.find_section(sectype) assert source is not None, "didn't find source section: " + sectype for (pos, count, temp_name, fn_desc) in to_copy[sectype]: loc1 = asm_objfile.symtab.find_symbol_in_section(temp_name + '_asm_start', source) loc2 = asm_objfile.symtab.find_symbol_in_section(temp_name + '_asm_end', source) assert loc1 == pos, "assembly and C files don't line up for section " + sectype + ", " + fn_desc if loc2 - loc1 != count: raise Failure("incorrectly computed size for section " + sectype + ", " + fn_desc + ". If using .double, make sure to provide explicit alignment padding.") if sectype == '.bss': continue target = objfile.find_section(sectype) assert target is not None, "missing target section of type " + sectype data = list(target.data) for (pos, count, _, _) in to_copy[sectype]: data[pos:pos + count] = source.data[pos:pos + count] if sectype == '.text': assert count % 4 == 0 assert pos % 4 == 0 for i in range(count // 4): modified_text_positions.add(pos + 4 * i) elif sectype == '.rodata': last_rodata_pos = pos + count target.data = bytes(data) # Move over late rodata. This is heuristic, sadly, since I can't think # of another way of doing it. moved_late_rodata = {} if any(all_late_rodata_dummy_bytes) or any(all_jtbl_rodata_size): source = asm_objfile.find_section('.rodata') target = objfile.find_section('.rodata') source_pos = asm_objfile.symtab.find_symbol_in_section(late_rodata_source_name_start, source) source_end = asm_objfile.symtab.find_symbol_in_section(late_rodata_source_name_end, source) if source_end - source_pos != sum(map(len, all_late_rodata_dummy_bytes)) * 4 + sum(all_jtbl_rodata_size): raise Failure("computed wrong size of .late_rodata") new_data = list(target.data) for dummy_bytes_list, jtbl_rodata_size in zip(all_late_rodata_dummy_bytes, all_jtbl_rodata_size): for index, dummy_bytes in enumerate(dummy_bytes_list): pos = target.data.index(dummy_bytes, last_rodata_pos) # This check is nice, but makes time complexity worse for large files: if SLOW_CHECKS and target.data.find(dummy_bytes, pos + 4) != -1: raise Failure("multiple occurrences of late_rodata hex magic. Change asm-processor to use something better than 0xE0123456!") if index == 0 and len(dummy_bytes_list) > 1 and target.data[pos+4:pos+8] == b'\0\0\0\0': # Ugly hack to handle double alignment for non-matching builds. # We were told by .late_rodata_alignment (or deduced from a .double) # that a function's late_rodata started out 4 (mod 8), and emitted # a float and then a double. But it was actually 0 (mod 8), so our # double was moved by 4 bytes. To make them adjacent to keep jump # tables correct, move the float by 4 bytes as well. new_data[pos:pos+4] = b'\0\0\0\0' pos += 4 new_data[pos:pos+4] = source.data[source_pos:source_pos+4] moved_late_rodata[source_pos] = pos last_rodata_pos = pos + 4 source_pos += 4 if jtbl_rodata_size > 0: assert dummy_bytes_list, "should always have dummy bytes before jtbl data" pos = last_rodata_pos new_data[pos : pos + jtbl_rodata_size] = \ source.data[source_pos : source_pos + jtbl_rodata_size] for i in range(0, jtbl_rodata_size, 4): moved_late_rodata[source_pos + i] = pos + i jtbl_rodata_positions.add(pos + i) last_rodata_pos += jtbl_rodata_size source_pos += jtbl_rodata_size target.data = bytes(new_data) # Merge strtab data. strtab_adj = len(objfile.symtab.strtab.data) objfile.symtab.strtab.data += asm_objfile.symtab.strtab.data # Find relocated symbols relocated_symbols = set() for sectype in SECTIONS: for obj in [asm_objfile, objfile]: sec = obj.find_section(sectype) if sec is None: continue for reltab in sec.relocated_by: for rel in reltab.relocations: relocated_symbols.add(obj.symtab.symbol_entries[rel.sym_index]) # Move over symbols, deleting the temporary function labels. # Sometimes this naive procedure results in duplicate symbols, or UNDEF # symbols that are also defined the same .o file. Hopefully that's fine. # Skip over local symbols that aren't used relocated against, to avoid # conflicts. new_local_syms = [s for s in objfile.symtab.local_symbols() if not is_temp_name(s.name)] new_global_syms = [s for s in objfile.symtab.global_symbols() if not is_temp_name(s.name)] for i, s in enumerate(asm_objfile.symtab.symbol_entries): is_local = (i < asm_objfile.symtab.sh_info) if is_local and s not in relocated_symbols: continue if is_temp_name(s.name): continue if s.st_shndx not in [SHN_UNDEF, SHN_ABS]: section_name = asm_objfile.sections[s.st_shndx].name if section_name not in SECTIONS: raise Failure("generated assembly .o must only have symbols for .text, .data, .rodata, ABS and UNDEF, but found " + section_name) s.st_shndx = objfile.find_section(section_name).index # glabel's aren't marked as functions, making objdump output confusing. Fix that. if s.name in all_text_glabels: s.type = STT_FUNC if objfile.sections[s.st_shndx].name == '.rodata' and s.st_value in moved_late_rodata: s.st_value = moved_late_rodata[s.st_value] s.st_name += strtab_adj if is_local: new_local_syms.append(s) else: new_global_syms.append(s) new_syms = new_local_syms + new_global_syms for i, s in enumerate(new_syms): s.new_index = i objfile.symtab.data = b''.join(s.to_bin() for s in new_syms) objfile.symtab.sh_info = len(new_local_syms) # Move over relocations for sectype in SECTIONS: source = asm_objfile.find_section(sectype) target = objfile.find_section(sectype) if target is not None: # fixup relocation symbol indices, since we butchered them above for reltab in target.relocated_by: nrels = [] for rel in reltab.relocations: if (sectype == '.text' and rel.r_offset in modified_text_positions or sectype == '.rodata' and rel.r_offset in jtbl_rodata_positions): # don't include relocations for late_rodata dummy code continue # hopefully we don't have relocations for local or # temporary symbols, so new_index exists rel.sym_index = objfile.symtab.symbol_entries[rel.sym_index].new_index nrels.append(rel) reltab.relocations = nrels reltab.data = b''.join(rel.to_bin() for rel in nrels) if not source: continue target_reltab = objfile.find_section('.rel' + sectype) target_reltaba = objfile.find_section('.rela' + sectype) for reltab in source.relocated_by: for rel in reltab.relocations: rel.sym_index = asm_objfile.symtab.symbol_entries[rel.sym_index].new_index if sectype == '.rodata' and rel.r_offset in moved_late_rodata: rel.r_offset = moved_late_rodata[rel.r_offset] new_data = b''.join(rel.to_bin() for rel in reltab.relocations) if reltab.sh_type == SHT_REL: if not target_reltab: target_reltab = objfile.add_section('.rel' + sectype, sh_type=SHT_REL, sh_flags=0, sh_link=objfile.symtab.index, sh_info=target.index, sh_addralign=4, sh_entsize=8, data=b'') target_reltab.data += new_data else: if not target_reltaba: target_reltaba = objfile.add_section('.rela' + sectype, sh_type=SHT_RELA, sh_flags=0, sh_link=objfile.symtab.index, sh_info=target.index, sh_addralign=4, sh_entsize=12, data=b'') target_reltaba.data += new_data objfile.write(objfile_name) finally: s_file.close() os.remove(s_name) try: os.remove(o_name) except: pass def run_wrapped(argv, outfile, functions): parser = argparse.ArgumentParser(description="Pre-process .c files and post-process .o files to enable embedding assembly into C.") parser.add_argument('filename', help="path to .c code") parser.add_argument('--post-process', dest='objfile', help="path to .o file to post-process") parser.add_argument('--assembler', dest='assembler', help="assembler command (e.g. \"mips-linux-gnu-as -march=vr4300 -mabi=32\")") parser.add_argument('--asm-prelude', dest='asm_prelude', help="path to a file containing a prelude to the assembly file (with .set and .macro directives, e.g.)") parser.add_argument('--input-enc', default='latin1', help="Input encoding (default: latin1)") parser.add_argument('--output-enc', default='latin1', help="Output encoding (default: latin1)") parser.add_argument('-framepointer', dest='framepointer', action='store_true') parser.add_argument('-g3', dest='g3', action='store_true') group = parser.add_mutually_exclusive_group(required=True) group.add_argument('-O1', dest='opt', action='store_const', const='O1') group.add_argument('-O2', dest='opt', action='store_const', const='O2') group.add_argument('-g', dest='opt', action='store_const', const='g') args = parser.parse_args(argv) opt = args.opt if args.g3: if opt != 'O2': raise Failure("-g3 is only supported together with -O2") opt = 'g3' if args.objfile is None: with open(args.filename, encoding=args.input_enc) as f: return parse_source(f, opt=opt, framepointer=args.framepointer, input_enc=args.input_enc, output_enc=args.output_enc, print_source=outfile) else: if args.assembler is None: raise Failure("must pass assembler command") if functions is None: with open(args.filename, encoding=args.input_enc) as f: functions = parse_source(f, opt=opt, framepointer=args.framepointer, input_enc=args.input_enc, output_enc=args.output_enc) if not functions: return asm_prelude = b'' if args.asm_prelude: with open(args.asm_prelude, 'rb') as f: asm_prelude = f.read() fixup_objfile(args.objfile, functions, asm_prelude, args.assembler, args.output_enc) def run(argv, outfile=sys.stdout.buffer, functions=None): try: return run_wrapped(argv, outfile, functions) except Failure as e: print("Error:", e, file=sys.stderr) sys.exit(1) if __name__ == "__main__": run(sys.argv[1:])