#!/usr/bin/env python3 # # This file is part of the MicroPython project, http://micropython.org/ # # The MIT License (MIT) # # Copyright (c) 2019 Damien P. George # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the "Software"), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN # THE SOFTWARE. """ Link .o files to .mpy """ import sys, os, struct, re from elftools.elf import elffile sys.path.append(os.path.dirname(__file__) + '/../py') import makeqstrdata as qstrutil # MicroPython constants MPY_VERSION = 5 MP_NATIVE_ARCH_X86 = 1 MP_NATIVE_ARCH_X64 = 2 MP_NATIVE_ARCH_ARMV7M = 5 MP_NATIVE_ARCH_ARMV7EMSP = 7 MP_NATIVE_ARCH_ARMV7EMDP = 8 MP_NATIVE_ARCH_XTENSA = 9 MP_NATIVE_ARCH_XTENSAWIN = 10 MP_CODE_BYTECODE = 2 MP_CODE_NATIVE_VIPER = 4 MP_SCOPE_FLAG_VIPERRELOC = 0x10 MP_SCOPE_FLAG_VIPERRODATA = 0x20 MP_SCOPE_FLAG_VIPERBSS = 0x40 MICROPY_OPT_CACHE_MAP_LOOKUP_IN_BYTECODE = 1 MICROPY_PY_BUILTINS_STR_UNICODE = 2 MP_SMALL_INT_BITS = 31 QSTR_WINDOW_SIZE = 32 # ELF constants R_386_32 = 1 R_X86_64_64 = 1 R_XTENSA_32 = 1 R_386_PC32 = 2 R_X86_64_PC32 = 2 R_ARM_ABS32 = 2 R_386_GOT32 = 3 R_ARM_REL32 = 3 R_386_PLT32 = 4 R_X86_64_PLT32 = 4 R_XTENSA_PLT = 6 R_386_GOTOFF = 9 R_386_GOTPC = 10 R_ARM_THM_CALL = 10 R_XTENSA_DIFF32 = 19 R_XTENSA_SLOT0_OP = 20 R_ARM_BASE_PREL = 25 # aka R_ARM_GOTPC R_ARM_GOT_BREL = 26 # aka R_ARM_GOT32 R_ARM_THM_JUMP24 = 30 R_X86_64_REX_GOTPCRELX = 42 R_386_GOT32X = 43 ################################################################################ # Architecture configuration def asm_jump_x86(entry): return struct.pack('> 11 == 0 or b_off >> 11 == -1: # Signed value fits in 12 bits b0 = 0xe000 | (b_off >> 1 & 0x07ff) b1 = 0 else: # Use large jump b0 = 0xf000 | (b_off >> 12 & 0x07ff) b1 = 0xb800 | (b_off >> 1 & 0x7ff) return struct.pack('> 8) class ArchData: def __init__(self, name, mpy_feature, qstr_entry_size, word_size, arch_got, asm_jump): self.name = name self.mpy_feature = mpy_feature self.qstr_entry_size = qstr_entry_size self.word_size = word_size self.arch_got = arch_got self.asm_jump = asm_jump self.separate_rodata = name == 'EM_XTENSA' and qstr_entry_size == 4 ARCH_DATA = { 'x86': ArchData( 'EM_386', MP_NATIVE_ARCH_X86 << 2 | MICROPY_PY_BUILTINS_STR_UNICODE | MICROPY_OPT_CACHE_MAP_LOOKUP_IN_BYTECODE, 2, 4, (R_386_PC32, R_386_GOT32, R_386_GOT32X), asm_jump_x86, ), 'x64': ArchData( 'EM_X86_64', MP_NATIVE_ARCH_X64 << 2 | MICROPY_PY_BUILTINS_STR_UNICODE | MICROPY_OPT_CACHE_MAP_LOOKUP_IN_BYTECODE, 2, 8, (R_X86_64_REX_GOTPCRELX,), asm_jump_x86, ), 'armv7m': ArchData( 'EM_ARM', MP_NATIVE_ARCH_ARMV7M << 2 | MICROPY_PY_BUILTINS_STR_UNICODE, 2, 4, (R_ARM_GOT_BREL,), asm_jump_arm, ), 'armv7emsp': ArchData( 'EM_ARM', MP_NATIVE_ARCH_ARMV7EMSP << 2 | MICROPY_PY_BUILTINS_STR_UNICODE, 2, 4, (R_ARM_GOT_BREL,), asm_jump_arm, ), 'armv7emdp': ArchData( 'EM_ARM', MP_NATIVE_ARCH_ARMV7EMDP << 2 | MICROPY_PY_BUILTINS_STR_UNICODE, 2, 4, (R_ARM_GOT_BREL,), asm_jump_arm, ), 'xtensa': ArchData( 'EM_XTENSA', MP_NATIVE_ARCH_XTENSA << 2 | MICROPY_PY_BUILTINS_STR_UNICODE, 2, 4, (R_XTENSA_32, R_XTENSA_PLT), asm_jump_xtensa, ), 'xtensawin': ArchData( 'EM_XTENSA', MP_NATIVE_ARCH_XTENSAWIN << 2 | MICROPY_PY_BUILTINS_STR_UNICODE, 4, 4, (R_XTENSA_32, R_XTENSA_PLT), asm_jump_xtensa, ), } ################################################################################ # Helper functions def align_to(value, align): return (value + align - 1) & ~(align - 1) def unpack_u24le(data, offset): return data[offset] | data[offset + 1] << 8 | data[offset + 2] << 16 def pack_u24le(data, offset, value): data[offset] = value & 0xff data[offset + 1] = value >> 8 & 0xff data[offset + 2] = value >> 16 & 0xff def xxd(text): for i in range(0, len(text), 16): print('{:08x}:'.format(i), end='') for j in range(4): off = i + j * 4 if off < len(text): d = int.from_bytes(text[off:off + 4], 'little') print(' {:08x}'.format(d), end='') print() # Smaller numbers are enabled first LOG_LEVEL_1 = 1 LOG_LEVEL_2 = 2 LOG_LEVEL_3 = 3 log_level = LOG_LEVEL_1 def log(level, msg): if level <= log_level: print(msg) ################################################################################ # Qstr extraction def extract_qstrs(source_files): def read_qstrs(f): with open(f) as f: vals = set() objs = set() for line in f: while line: m = re.search(r'MP_OBJ_NEW_QSTR\((MP_QSTR_[A-Za-z0-9_]*)\)', line) if m: objs.add(m.group(1)) else: m = re.search(r'MP_QSTR_[A-Za-z0-9_]*', line) if m: vals.add(m.group()) if m: s = m.span() line = line[:s[0]] + line[s[1]:] else: line = '' return vals, objs static_qstrs = ['MP_QSTR_' + qstrutil.qstr_escape(q) for q in qstrutil.static_qstr_list] qstr_vals = set() qstr_objs = set() for f in source_files: vals, objs = read_qstrs(f) qstr_vals.update(vals) qstr_objs.update(objs) qstr_vals.difference_update(static_qstrs) return static_qstrs, qstr_vals, qstr_objs ################################################################################ # Linker class LinkError(Exception): pass class Section: def __init__(self, name, data, alignment, filename=None): self.filename = filename self.name = name self.data = data self.alignment = alignment self.addr = 0 self.reloc = [] @staticmethod def from_elfsec(elfsec, filename): assert elfsec.header.sh_addr == 0 return Section(elfsec.name, elfsec.data(), elfsec.data_alignment, filename) class GOTEntry: def __init__(self, name, sym, link_addr=0): self.name = name self.sym = sym self.offset = None self.link_addr = link_addr def isexternal(self): return self.sec_name.startswith('.external') def istext(self): return self.sec_name.startswith('.text') def isrodata(self): return self.sec_name.startswith(('.rodata', '.data.rel.ro')) def isbss(self): return self.sec_name.startswith('.bss') class LiteralEntry: def __init__(self, value, offset): self.value = value self.offset = offset class LinkEnv: def __init__(self, arch): self.arch = ARCH_DATA[arch] self.sections = [] # list of sections in order of output self.literal_sections = [] # list of literal sections (xtensa only) self.known_syms = {} # dict of symbols that are defined self.unresolved_syms = [] # list of unresolved symbols self.mpy_relocs = [] # list of relocations needed in the output .mpy file def check_arch(self, arch_name): if arch_name != self.arch.name: raise LinkError('incompatible arch') def print_sections(self): log(LOG_LEVEL_2, 'sections:') for sec in self.sections: log(LOG_LEVEL_2, ' {:08x} {} size={}'.format(sec.addr, sec.name, len(sec.data))) def find_addr(self, name): if name in self.known_syms: s = self.known_syms[name] return s.section.addr + s['st_value'] raise LinkError('unknown symbol: {}'.format(name)) def build_got_generic(env): env.got_entries = {} for sec in env.sections: for r in sec.reloc: s = r.sym if not (s.entry['st_info']['bind'] == 'STB_GLOBAL' and r['r_info_type'] in env.arch.arch_got): continue s_type = s.entry['st_info']['type'] assert s_type in ('STT_NOTYPE', 'STT_FUNC', 'STT_OBJECT'), s_type assert s.name if s.name in env.got_entries: continue env.got_entries[s.name] = GOTEntry(s.name, s) def build_got_xtensa(env): env.got_entries = {} env.lit_entries = {} env.xt_literals = {} # Extract the values from the literal table for sec in env.literal_sections: assert len(sec.data) % env.arch.word_size == 0 # Look through literal relocations to find any global pointers that should be GOT entries for r in sec.reloc: s = r.sym s_type = s.entry['st_info']['type'] assert s_type in ('STT_NOTYPE', 'STT_FUNC', 'STT_OBJECT', 'STT_SECTION'), s_type assert r['r_info_type'] in env.arch.arch_got assert r['r_offset'] % env.arch.word_size == 0 # This entry is a global pointer existing = struct.unpack_from(' {}+{:08x}'.format(g.offset, g.name, g.sec_name, g.link_addr)) def populate_lit(env): log(LOG_LEVEL_2, 'LIT: {:08x}'.format(env.lit_section.addr)) for lit_entry in env.lit_entries.values(): value = lit_entry.value log(LOG_LEVEL_2, ' {:08x} = {:08x}'.format(lit_entry.offset, value)) o = env.lit_section.addr + lit_entry.offset env.full_text[o:o + env.arch.word_size] = value.to_bytes(env.arch.word_size, 'little') def do_relocation_text(env, text_addr, r): # Extract relevant info about symbol that's being relocated s = r.sym s_bind = s.entry['st_info']['bind'] s_shndx = s.entry['st_shndx'] s_type = s.entry['st_info']['type'] r_offset = r['r_offset'] + text_addr r_info_type = r['r_info_type'] try: # only for RELA sections r_addend = r['r_addend'] except KeyError: r_addend = 0 # Default relocation type and name for logging reloc_type = 'le32' log_name = None if (env.arch.name == 'EM_386' and r_info_type in (R_386_PC32, R_386_PLT32) or env.arch.name == 'EM_X86_64' and r_info_type in (R_X86_64_PC32, R_X86_64_PLT32) or env.arch.name == 'EM_ARM' and r_info_type in (R_ARM_REL32, R_ARM_THM_CALL, R_ARM_THM_JUMP24) or s_bind == 'STB_LOCAL' and env.arch.name == 'EM_XTENSA' and r_info_type == R_XTENSA_32 # not GOT ): # Standard relocation to fixed location within text/rodata if hasattr(s, 'resolved'): s = s.resolved sec = s.section if env.arch.separate_rodata and sec.name.startswith('.rodata'): raise LinkError('fixed relocation to rodata with rodata referenced via GOT') if sec.name.startswith('.bss'): raise LinkError('{}: fixed relocation to bss (bss variables can\'t be static)'.format(s.filename)) if sec.name.startswith('.external'): raise LinkError('{}: fixed relocation to external symbol: {}'.format(s.filename, s.name)) addr = sec.addr + s['st_value'] reloc = addr - r_offset + r_addend if r_info_type in (R_ARM_THM_CALL, R_ARM_THM_JUMP24): # Both relocations have the same bit pattern to rewrite: # R_ARM_THM_CALL: bl # R_ARM_THM_JUMP24: b.w reloc_type = 'thumb_b' elif (env.arch.name == 'EM_386' and r_info_type == R_386_GOTPC or env.arch.name == 'EM_ARM' and r_info_type == R_ARM_BASE_PREL ): # Relocation to GOT address itself assert s.name == '_GLOBAL_OFFSET_TABLE_' addr = env.got_section.addr reloc = addr - r_offset + r_addend elif (env.arch.name == 'EM_386' and r_info_type in (R_386_GOT32, R_386_GOT32X) or env.arch.name == 'EM_ARM' and r_info_type == R_ARM_GOT_BREL ): # Relcation pointing to GOT reloc = addr = env.got_entries[s.name].offset elif env.arch.name == 'EM_X86_64' and r_info_type == R_X86_64_REX_GOTPCRELX: # Relcation pointing to GOT got_entry = env.got_entries[s.name] addr = env.got_section.addr + got_entry.offset reloc = addr - r_offset + r_addend elif env.arch.name == 'EM_386' and r_info_type == R_386_GOTOFF: # Relocation relative to GOT addr = s.section.addr + s['st_value'] reloc = addr - env.got_section.addr + r_addend elif env.arch.name == 'EM_XTENSA' and r_info_type == R_XTENSA_SLOT0_OP: # Relocation pointing to GOT, xtensa specific sec = s.section if sec.name.startswith('.text'): # it looks like R_XTENSA_SLOT0_OP into .text is already correctly relocated return assert sec.name.startswith('.literal'), sec.name lit_idx = '{}+0x{:x}'.format(sec.filename, r_addend) lit_ptr = env.xt_literals[lit_idx] if isinstance(lit_ptr, str): addr = env.got_section.addr + env.got_entries[lit_ptr].offset log_name = 'GOT {}'.format(lit_ptr) else: addr = env.lit_section.addr + env.lit_entries[lit_ptr].offset log_name = 'LIT' reloc = addr - r_offset reloc_type = 'xtensa_l32r' elif env.arch.name == 'EM_XTENSA' and r_info_type == R_XTENSA_DIFF32: if s.section.name.startswith('.text'): # it looks like R_XTENSA_DIFF32 into .text is already correctly relocated return assert 0 else: # Unknown/unsupported relocation assert 0, r_info_type # Write relocation if reloc_type == 'le32': existing, = struct.unpack_from('= 0x400000: # 2's complement existing -= 0x800000 new = existing + reloc b_h = (b_h & 0xf800) | (new >> 12) & 0x7ff b_l = (b_l & 0xf800) | (new >> 1) & 0x7ff struct.pack_into('> 8 l32r_imm16 = (l32r_imm16 + reloc >> 2) & 0xffff l32r = l32r & 0xff | l32r_imm16 << 8 pack_u24le(env.full_text, r_offset, l32r) else: assert 0, reloc_type # Log information about relocation if log_name is None: if s_type == 'STT_SECTION': log_name = s.section.name else: log_name = s.name log(LOG_LEVEL_3, ' {:08x} {} -> {:08x}'.format(r_offset, log_name, addr)) def do_relocation_data(env, text_addr, r): s = r.sym s_type = s.entry['st_info']['type'] r_offset = r['r_offset'] + text_addr r_info_type = r['r_info_type'] try: # only for RELA sections r_addend = r['r_addend'] except KeyError: r_addend = 0 if (env.arch.name == 'EM_386' and r_info_type == R_386_32 or env.arch.name == 'EM_X86_64' and r_info_type == R_X86_64_64 or env.arch.name == 'EM_ARM' and r_info_type == R_ARM_ABS32 or env.arch.name == 'EM_XTENSA' and r_info_type == R_XTENSA_32): # Relocation in data.rel.ro to internal/external symbol if env.arch.word_size == 4: struct_type = ' {} {:08x}'.format(r_offset, log_name, addr)) if env.arch.separate_rodata: data = env.full_rodata else: data = env.full_text existing, = struct.unpack_from(struct_type, data, r_offset) if sec.name.startswith(('.text', '.rodata', '.data.rel.ro', '.bss')): struct.pack_into(struct_type, data, r_offset, existing + addr) kind = sec.name elif sec.name == '.external.mp_fun_table': assert addr == 0 kind = s.mp_fun_table_offset else: assert 0, sec.name if env.arch.separate_rodata: base = '.rodata' else: base = '.text' env.mpy_relocs.append((base, r_offset, kind)) else: # Unknown/unsupported relocation assert 0, r_info_type def load_object_file(env, felf): with open(felf, 'rb') as f: elf = elffile.ELFFile(f) env.check_arch(elf['e_machine']) # Get symbol table symtab = list(elf.get_section_by_name('.symtab').iter_symbols()) # Load needed sections from ELF file sections_shndx = {} # maps elf shndx to Section object for idx, s in enumerate(elf.iter_sections()): if s.header.sh_type in ('SHT_PROGBITS', 'SHT_NOBITS'): if s.data_size == 0: # Ignore empty sections pass elif s.name.startswith(('.literal', '.text', '.rodata', '.data.rel.ro', '.bss')): sec = Section.from_elfsec(s, felf) sections_shndx[idx] = sec if s.name.startswith('.literal'): env.literal_sections.append(sec) else: env.sections.append(sec) elif s.name.startswith('.data'): raise LinkError('{}: {} non-empty'.format(felf, s.name)) else: # Ignore section pass elif s.header.sh_type in ('SHT_REL', 'SHT_RELA'): shndx = s.header.sh_info if shndx in sections_shndx: sec = sections_shndx[shndx] sec.reloc_name = s.name sec.reloc = list(s.iter_relocations()) for r in sec.reloc: r.sym = symtab[r['r_info_sym']] # Link symbols to their sections, and update known and unresolved symbols for sym in symtab: sym.filename = felf shndx = sym.entry['st_shndx'] if shndx in sections_shndx: # Symbol with associated section sym.section = sections_shndx[shndx] if sym['st_info']['bind'] == 'STB_GLOBAL': # Defined global symbol if sym.name in env.known_syms and not sym.name.startswith('__x86.get_pc_thunk.'): raise LinkError('duplicate symbol: {}'.format(sym.name)) env.known_syms[sym.name] = sym elif sym.entry['st_shndx'] == 'SHN_UNDEF' and sym['st_info']['bind'] == 'STB_GLOBAL': # Undefined global symbol, needs resolving env.unresolved_syms.append(sym) def link_objects(env, native_qstr_vals_len, native_qstr_objs_len): # Build GOT information if env.arch.name == 'EM_XTENSA': build_got_xtensa(env) else: build_got_generic(env) # Creat GOT section got_size = len(env.got_entries) * env.arch.word_size env.got_section = Section('GOT', bytearray(got_size), env.arch.word_size) if env.arch.name == 'EM_XTENSA': env.sections.insert(0, env.got_section) else: env.sections.append(env.got_section) # Create optional literal section if env.arch.name == 'EM_XTENSA': lit_size = len(env.lit_entries) * env.arch.word_size env.lit_section = Section('LIT', bytearray(lit_size), env.arch.word_size) env.sections.insert(1, env.lit_section) # Create section to contain mp_native_qstr_val_table env.qstr_val_section = Section('.text.QSTR_VAL', bytearray(native_qstr_vals_len * env.arch.qstr_entry_size), env.arch.qstr_entry_size) env.sections.append(env.qstr_val_section) # Create section to contain mp_native_qstr_obj_table env.qstr_obj_section = Section('.text.QSTR_OBJ', bytearray(native_qstr_objs_len * env.arch.word_size), env.arch.word_size) env.sections.append(env.qstr_obj_section) # Resolve unknown symbols mp_fun_table_sec = Section('.external.mp_fun_table', b'', 0) fun_table = {key: 67 + idx for idx, key in enumerate([ 'mp_type_type', 'mp_type_str', 'mp_type_list', 'mp_type_dict', 'mp_type_fun_builtin_0', 'mp_type_fun_builtin_1', 'mp_type_fun_builtin_2', 'mp_type_fun_builtin_3', 'mp_type_fun_builtin_var', 'mp_stream_read_obj', 'mp_stream_readinto_obj', 'mp_stream_unbuffered_readline_obj', 'mp_stream_write_obj', ]) } for sym in env.unresolved_syms: assert sym['st_value'] == 0 if sym.name == '_GLOBAL_OFFSET_TABLE_': pass elif sym.name == 'mp_fun_table': sym.section = Section('.external', b'', 0) elif sym.name == 'mp_native_qstr_val_table': sym.section = env.qstr_val_section elif sym.name == 'mp_native_qstr_obj_table': sym.section = env.qstr_obj_section elif sym.name in env.known_syms: sym.resolved = env.known_syms[sym.name] else: if sym.name in fun_table: sym.section = mp_fun_table_sec sym.mp_fun_table_offset = fun_table[sym.name] else: raise LinkError('{}: undefined symbol: {}'.format(sym.filename, sym.name)) # Align sections, assign their addresses, and create full_text env.full_text = bytearray(env.arch.asm_jump(8)) # dummy, to be filled in later env.full_rodata = bytearray(0) env.full_bss = bytearray(0) for sec in env.sections: if env.arch.separate_rodata and sec.name.startswith(('.rodata', '.data.rel.ro')): data = env.full_rodata elif sec.name.startswith('.bss'): data = env.full_bss else: data = env.full_text sec.addr = align_to(len(data), sec.alignment) data.extend(b'\x00' * (sec.addr - len(data))) data.extend(sec.data) env.print_sections() populate_got(env) if env.arch.name == 'EM_XTENSA': populate_lit(env) # Fill in relocations for sec in env.sections: if not sec.reloc: continue log(LOG_LEVEL_3, '{}: {} relocations via {}:'.format(sec.filename, sec.name, sec.reloc_name)) for r in sec.reloc: if sec.name.startswith(('.text', '.rodata')): do_relocation_text(env, sec.addr, r) elif sec.name.startswith('.data.rel.ro'): do_relocation_data(env, sec.addr, r) else: assert 0, sec.name ################################################################################ # .mpy output class MPYOutput: def open(self, fname): self.f = open(fname, 'wb') self.prev_base = -1 self.prev_offset = -1 def close(self): self.f.close() def write_bytes(self, buf): self.f.write(buf) def write_uint(self, val): b = bytearray() b.insert(0, val & 0x7f) val >>= 7 while val: b.insert(0, 0x80 | (val & 0x7f)) val >>= 7 self.write_bytes(b) def write_qstr(self, s): if s in qstrutil.static_qstr_list: self.write_bytes(bytes([0, qstrutil.static_qstr_list.index(s) + 1])) else: s = bytes(s, 'ascii') self.write_uint(len(s) << 1) self.write_bytes(s) def write_reloc(self, base, offset, dest, n): need_offset = not (base == self.prev_base and offset == self.prev_offset + 1) self.prev_offset = offset + n - 1 if dest <= 2: dest = (dest << 1) | (n > 1) else: assert 6 <= dest <= 127 assert n == 1 dest = dest << 1 | need_offset assert 0 <= dest <= 0xfe, dest self.write_bytes(bytes([dest])) if need_offset: if base == '.text': base = 0 elif base == '.rodata': base = 1 self.write_uint(offset << 1 | base) if n > 1: self.write_uint(n) def build_mpy(env, entry_offset, fmpy, native_qstr_vals, native_qstr_objs): # Write jump instruction to start of text jump = env.arch.asm_jump(entry_offset) env.full_text[:len(jump)] = jump log(LOG_LEVEL_1, 'arch: {}'.format(env.arch.name)) log(LOG_LEVEL_1, 'text size: {}'.format(len(env.full_text))) if len(env.full_rodata): log(LOG_LEVEL_1, 'rodata size: {}'.format(len(env.full_rodata))) log(LOG_LEVEL_1, 'bss size: {}'.format(len(env.full_bss))) log(LOG_LEVEL_1, 'GOT entries: {}'.format(len(env.got_entries))) #xxd(env.full_text) out = MPYOutput() out.open(fmpy) # MPY: header out.write_bytes(bytearray([ ord('M'), MPY_VERSION, env.arch.mpy_feature, MP_SMALL_INT_BITS, QSTR_WINDOW_SIZE, ])) # MPY: kind/len out.write_uint(len(env.full_text) << 2 | (MP_CODE_NATIVE_VIPER - MP_CODE_BYTECODE)) # MPY: machine code out.write_bytes(env.full_text) # MPY: n_qstr_link (assumes little endian) out.write_uint(len(native_qstr_vals) + len(native_qstr_objs)) for q in range(len(native_qstr_vals)): off = env.qstr_val_section.addr + q * env.arch.qstr_entry_size out.write_uint(off << 2) out.write_qstr(native_qstr_vals[q]) for q in range(len(native_qstr_objs)): off = env.qstr_obj_section.addr + q * env.arch.word_size out.write_uint(off << 2 | 3) out.write_qstr(native_qstr_objs[q]) # MPY: scope_flags scope_flags = MP_SCOPE_FLAG_VIPERRELOC if len(env.full_rodata): scope_flags |= MP_SCOPE_FLAG_VIPERRODATA if len(env.full_bss): scope_flags |= MP_SCOPE_FLAG_VIPERBSS out.write_uint(scope_flags) # MPY: n_obj out.write_uint(0) # MPY: n_raw_code out.write_uint(0) # MPY: rodata and/or bss if len(env.full_rodata): rodata_const_table_idx = 1 out.write_uint(len(env.full_rodata)) out.write_bytes(env.full_rodata) if len(env.full_bss): bss_const_table_idx = bool(env.full_rodata) + 1 out.write_uint(len(env.full_bss)) # MPY: relocation information prev_kind = None for base, addr, kind in env.mpy_relocs: if isinstance(kind, str) and kind.startswith('.text'): kind = 0 elif kind in ('.rodata', '.data.rel.ro'): if env.arch.separate_rodata: kind = rodata_const_table_idx else: kind = 0 elif isinstance(kind, str) and kind.startswith('.bss'): kind = bss_const_table_idx elif kind == 'mp_fun_table': kind = 6 else: kind = 7 + kind assert addr % env.arch.word_size == 0, addr offset = addr // env.arch.word_size if kind == prev_kind and base == prev_base and offset == prev_offset + 1: prev_n += 1 prev_offset += 1 else: if prev_kind is not None: out.write_reloc(prev_base, prev_offset - prev_n + 1, prev_kind, prev_n) prev_kind = kind prev_base = base prev_offset = offset prev_n = 1 if prev_kind is not None: out.write_reloc(prev_base, prev_offset - prev_n + 1, prev_kind, prev_n) # MPY: sentinel for end of relocations out.write_bytes(b'\xff') out.close() ################################################################################ # main def do_preprocess(args): if args.output is None: assert args.files[0].endswith('.c') args.output = args.files[0][:-1] + 'config.h' static_qstrs, qstr_vals, qstr_objs = extract_qstrs(args.files) with open(args.output, 'w') as f: print('#include \n' 'typedef uintptr_t mp_uint_t;\n' 'typedef intptr_t mp_int_t;\n' 'typedef uintptr_t mp_off_t;', file=f) for i, q in enumerate(static_qstrs): print('#define %s (%u)' % (q, i + 1), file=f) for i, q in enumerate(sorted(qstr_vals)): print('#define %s (mp_native_qstr_val_table[%d])' % (q, i), file=f) for i, q in enumerate(sorted(qstr_objs)): print('#define MP_OBJ_NEW_QSTR_%s ((mp_obj_t)mp_native_qstr_obj_table[%d])' % (q, i), file=f) if args.arch == 'xtensawin': qstr_type = 'uint32_t' # esp32 can only read 32-bit values from IRAM else: qstr_type = 'uint16_t' print('extern const {} mp_native_qstr_val_table[];'.format(qstr_type), file=f) print('extern const mp_uint_t mp_native_qstr_obj_table[];', file=f) def do_link(args): if args.output is None: assert args.files[0].endswith('.o') args.output = args.files[0][:-1] + 'mpy' native_qstr_vals = [] native_qstr_objs = [] if args.qstrs is not None: with open(args.qstrs) as f: for l in f: m = re.match(r'#define MP_QSTR_([A-Za-z0-9_]*) \(mp_native_', l) if m: native_qstr_vals.append(m.group(1)) else: m = re.match(r'#define MP_OBJ_NEW_QSTR_MP_QSTR_([A-Za-z0-9_]*)', l) if m: native_qstr_objs.append(m.group(1)) log(LOG_LEVEL_2, 'qstr vals: ' + ', '.join(native_qstr_vals)) log(LOG_LEVEL_2, 'qstr objs: ' + ', '.join(native_qstr_objs)) env = LinkEnv(args.arch) try: for file in args.files: load_object_file(env, file) link_objects(env, len(native_qstr_vals), len(native_qstr_objs)) build_mpy(env, env.find_addr('mpy_init'), args.output, native_qstr_vals, native_qstr_objs) except LinkError as er: print('LinkError:', er.args[0]) sys.exit(1) def main(): import argparse cmd_parser = argparse.ArgumentParser(description='Run scripts on the pyboard.') cmd_parser.add_argument('--verbose', '-v', action='count', default=1, help='increase verbosity') cmd_parser.add_argument('--arch', default='x64', help='architecture') cmd_parser.add_argument('--preprocess', action='store_true', help='preprocess source files') cmd_parser.add_argument('--qstrs', default=None, help='file defining additional qstrs') cmd_parser.add_argument('--output', '-o', default=None, help='output .mpy file (default to input with .o->.mpy)') cmd_parser.add_argument('files', nargs='+', help='input files') args = cmd_parser.parse_args() global log_level log_level = args.verbose if args.preprocess: do_preprocess(args) else: do_link(args) if __name__ == '__main__': main()