Aegisub/vendor/luajit/src/jit/bcsave.lua

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2014-04-28 04:45:14 +02:00
----------------------------------------------------------------------------
-- LuaJIT module to save/list bytecode.
--
-- Copyright (C) 2005-2014 Mike Pall. All rights reserved.
-- Released under the MIT license. See Copyright Notice in luajit.h
----------------------------------------------------------------------------
--
-- This module saves or lists the bytecode for an input file.
-- It's run by the -b command line option.
--
------------------------------------------------------------------------------
local jit = require("jit")
assert(jit.version_num == 20003, "LuaJIT core/library version mismatch")
local bit = require("bit")
-- Symbol name prefix for LuaJIT bytecode.
local LJBC_PREFIX = "luaJIT_BC_"
------------------------------------------------------------------------------
local function usage()
io.stderr:write[[
Save LuaJIT bytecode: luajit -b[options] input output
-l Only list bytecode.
-s Strip debug info (default).
-g Keep debug info.
-n name Set module name (default: auto-detect from input name).
-t type Set output file type (default: auto-detect from output name).
-a arch Override architecture for object files (default: native).
-o os Override OS for object files (default: native).
-e chunk Use chunk string as input.
-- Stop handling options.
- Use stdin as input and/or stdout as output.
File types: c h obj o raw (default)
]]
os.exit(1)
end
local function check(ok, ...)
if ok then return ok, ... end
io.stderr:write("luajit: ", ...)
io.stderr:write("\n")
os.exit(1)
end
local function readfile(input)
if type(input) == "function" then return input end
if input == "-" then input = nil end
return check(loadfile(input))
end
local function savefile(name, mode)
if name == "-" then return io.stdout end
return check(io.open(name, mode))
end
------------------------------------------------------------------------------
local map_type = {
raw = "raw", c = "c", h = "h", o = "obj", obj = "obj",
}
local map_arch = {
x86 = true, x64 = true, arm = true, ppc = true, ppcspe = true,
mips = true, mipsel = true,
}
local map_os = {
linux = true, windows = true, osx = true, freebsd = true, netbsd = true,
openbsd = true, solaris = true,
}
local function checkarg(str, map, err)
str = string.lower(str)
local s = check(map[str], "unknown ", err)
return s == true and str or s
end
local function detecttype(str)
local ext = string.match(string.lower(str), "%.(%a+)$")
return map_type[ext] or "raw"
end
local function checkmodname(str)
check(string.match(str, "^[%w_.%-]+$"), "bad module name")
return string.gsub(str, "[%.%-]", "_")
end
local function detectmodname(str)
if type(str) == "string" then
local tail = string.match(str, "[^/\\]+$")
if tail then str = tail end
local head = string.match(str, "^(.*)%.[^.]*$")
if head then str = head end
str = string.match(str, "^[%w_.%-]+")
else
str = nil
end
check(str, "cannot derive module name, use -n name")
return string.gsub(str, "[%.%-]", "_")
end
------------------------------------------------------------------------------
local function bcsave_tail(fp, output, s)
local ok, err = fp:write(s)
if ok and output ~= "-" then ok, err = fp:close() end
check(ok, "cannot write ", output, ": ", err)
end
local function bcsave_raw(output, s)
local fp = savefile(output, "wb")
bcsave_tail(fp, output, s)
end
local function bcsave_c(ctx, output, s)
local fp = savefile(output, "w")
if ctx.type == "c" then
fp:write(string.format([[
#ifdef _cplusplus
extern "C"
#endif
#ifdef _WIN32
__declspec(dllexport)
#endif
const char %s%s[] = {
]], LJBC_PREFIX, ctx.modname))
else
fp:write(string.format([[
#define %s%s_SIZE %d
static const char %s%s[] = {
]], LJBC_PREFIX, ctx.modname, #s, LJBC_PREFIX, ctx.modname))
end
local t, n, m = {}, 0, 0
for i=1,#s do
local b = tostring(string.byte(s, i))
m = m + #b + 1
if m > 78 then
fp:write(table.concat(t, ",", 1, n), ",\n")
n, m = 0, #b + 1
end
n = n + 1
t[n] = b
end
bcsave_tail(fp, output, table.concat(t, ",", 1, n).."\n};\n")
end
local function bcsave_elfobj(ctx, output, s, ffi)
ffi.cdef[[
typedef struct {
uint8_t emagic[4], eclass, eendian, eversion, eosabi, eabiversion, epad[7];
uint16_t type, machine;
uint32_t version;
uint32_t entry, phofs, shofs;
uint32_t flags;
uint16_t ehsize, phentsize, phnum, shentsize, shnum, shstridx;
} ELF32header;
typedef struct {
uint8_t emagic[4], eclass, eendian, eversion, eosabi, eabiversion, epad[7];
uint16_t type, machine;
uint32_t version;
uint64_t entry, phofs, shofs;
uint32_t flags;
uint16_t ehsize, phentsize, phnum, shentsize, shnum, shstridx;
} ELF64header;
typedef struct {
uint32_t name, type, flags, addr, ofs, size, link, info, align, entsize;
} ELF32sectheader;
typedef struct {
uint32_t name, type;
uint64_t flags, addr, ofs, size;
uint32_t link, info;
uint64_t align, entsize;
} ELF64sectheader;
typedef struct {
uint32_t name, value, size;
uint8_t info, other;
uint16_t sectidx;
} ELF32symbol;
typedef struct {
uint32_t name;
uint8_t info, other;
uint16_t sectidx;
uint64_t value, size;
} ELF64symbol;
typedef struct {
ELF32header hdr;
ELF32sectheader sect[6];
ELF32symbol sym[2];
uint8_t space[4096];
} ELF32obj;
typedef struct {
ELF64header hdr;
ELF64sectheader sect[6];
ELF64symbol sym[2];
uint8_t space[4096];
} ELF64obj;
]]
local symname = LJBC_PREFIX..ctx.modname
local is64, isbe = false, false
if ctx.arch == "x64" then
is64 = true
elseif ctx.arch == "ppc" or ctx.arch == "ppcspe" or ctx.arch == "mips" then
isbe = true
end
-- Handle different host/target endianess.
local function f32(x) return x end
local f16, fofs = f32, f32
if ffi.abi("be") ~= isbe then
f32 = bit.bswap
function f16(x) return bit.rshift(bit.bswap(x), 16) end
if is64 then
local two32 = ffi.cast("int64_t", 2^32)
function fofs(x) return bit.bswap(x)*two32 end
else
fofs = f32
end
end
-- Create ELF object and fill in header.
local o = ffi.new(is64 and "ELF64obj" or "ELF32obj")
local hdr = o.hdr
if ctx.os == "bsd" or ctx.os == "other" then -- Determine native hdr.eosabi.
local bf = assert(io.open("/bin/ls", "rb"))
local bs = bf:read(9)
bf:close()
ffi.copy(o, bs, 9)
check(hdr.emagic[0] == 127, "no support for writing native object files")
else
hdr.emagic = "\127ELF"
hdr.eosabi = ({ freebsd=9, netbsd=2, openbsd=12, solaris=6 })[ctx.os] or 0
end
hdr.eclass = is64 and 2 or 1
hdr.eendian = isbe and 2 or 1
hdr.eversion = 1
hdr.type = f16(1)
hdr.machine = f16(({ x86=3, x64=62, arm=40, ppc=20, ppcspe=20, mips=8, mipsel=8 })[ctx.arch])
if ctx.arch == "mips" or ctx.arch == "mipsel" then
hdr.flags = 0x50001006
end
hdr.version = f32(1)
hdr.shofs = fofs(ffi.offsetof(o, "sect"))
hdr.ehsize = f16(ffi.sizeof(hdr))
hdr.shentsize = f16(ffi.sizeof(o.sect[0]))
hdr.shnum = f16(6)
hdr.shstridx = f16(2)
-- Fill in sections and symbols.
local sofs, ofs = ffi.offsetof(o, "space"), 1
for i,name in ipairs{
".symtab", ".shstrtab", ".strtab", ".rodata", ".note.GNU-stack",
} do
local sect = o.sect[i]
sect.align = fofs(1)
sect.name = f32(ofs)
ffi.copy(o.space+ofs, name)
ofs = ofs + #name+1
end
o.sect[1].type = f32(2) -- .symtab
o.sect[1].link = f32(3)
o.sect[1].info = f32(1)
o.sect[1].align = fofs(8)
o.sect[1].ofs = fofs(ffi.offsetof(o, "sym"))
o.sect[1].entsize = fofs(ffi.sizeof(o.sym[0]))
o.sect[1].size = fofs(ffi.sizeof(o.sym))
o.sym[1].name = f32(1)
o.sym[1].sectidx = f16(4)
o.sym[1].size = fofs(#s)
o.sym[1].info = 17
o.sect[2].type = f32(3) -- .shstrtab
o.sect[2].ofs = fofs(sofs)
o.sect[2].size = fofs(ofs)
o.sect[3].type = f32(3) -- .strtab
o.sect[3].ofs = fofs(sofs + ofs)
o.sect[3].size = fofs(#symname+1)
ffi.copy(o.space+ofs+1, symname)
ofs = ofs + #symname + 2
o.sect[4].type = f32(1) -- .rodata
o.sect[4].flags = fofs(2)
o.sect[4].ofs = fofs(sofs + ofs)
o.sect[4].size = fofs(#s)
o.sect[5].type = f32(1) -- .note.GNU-stack
o.sect[5].ofs = fofs(sofs + ofs + #s)
-- Write ELF object file.
local fp = savefile(output, "wb")
fp:write(ffi.string(o, ffi.sizeof(o)-4096+ofs))
bcsave_tail(fp, output, s)
end
local function bcsave_peobj(ctx, output, s, ffi)
ffi.cdef[[
typedef struct {
uint16_t arch, nsects;
uint32_t time, symtabofs, nsyms;
uint16_t opthdrsz, flags;
} PEheader;
typedef struct {
char name[8];
uint32_t vsize, vaddr, size, ofs, relocofs, lineofs;
uint16_t nreloc, nline;
uint32_t flags;
} PEsection;
typedef struct __attribute((packed)) {
union {
char name[8];
uint32_t nameref[2];
};
uint32_t value;
int16_t sect;
uint16_t type;
uint8_t scl, naux;
} PEsym;
typedef struct __attribute((packed)) {
uint32_t size;
uint16_t nreloc, nline;
uint32_t cksum;
uint16_t assoc;
uint8_t comdatsel, unused[3];
} PEsymaux;
typedef struct {
PEheader hdr;
PEsection sect[2];
// Must be an even number of symbol structs.
PEsym sym0;
PEsymaux sym0aux;
PEsym sym1;
PEsymaux sym1aux;
PEsym sym2;
PEsym sym3;
uint32_t strtabsize;
uint8_t space[4096];
} PEobj;
]]
local symname = LJBC_PREFIX..ctx.modname
local is64 = false
if ctx.arch == "x86" then
symname = "_"..symname
elseif ctx.arch == "x64" then
is64 = true
end
local symexport = " /EXPORT:"..symname..",DATA "
-- The file format is always little-endian. Swap if the host is big-endian.
local function f32(x) return x end
local f16 = f32
if ffi.abi("be") then
f32 = bit.bswap
function f16(x) return bit.rshift(bit.bswap(x), 16) end
end
-- Create PE object and fill in header.
local o = ffi.new("PEobj")
local hdr = o.hdr
hdr.arch = f16(({ x86=0x14c, x64=0x8664, arm=0x1c0, ppc=0x1f2, mips=0x366, mipsel=0x366 })[ctx.arch])
hdr.nsects = f16(2)
hdr.symtabofs = f32(ffi.offsetof(o, "sym0"))
hdr.nsyms = f32(6)
-- Fill in sections and symbols.
o.sect[0].name = ".drectve"
o.sect[0].size = f32(#symexport)
o.sect[0].flags = f32(0x00100a00)
o.sym0.sect = f16(1)
o.sym0.scl = 3
o.sym0.name = ".drectve"
o.sym0.naux = 1
o.sym0aux.size = f32(#symexport)
o.sect[1].name = ".rdata"
o.sect[1].size = f32(#s)
o.sect[1].flags = f32(0x40300040)
o.sym1.sect = f16(2)
o.sym1.scl = 3
o.sym1.name = ".rdata"
o.sym1.naux = 1
o.sym1aux.size = f32(#s)
o.sym2.sect = f16(2)
o.sym2.scl = 2
o.sym2.nameref[1] = f32(4)
o.sym3.sect = f16(-1)
o.sym3.scl = 2
o.sym3.value = f32(1)
o.sym3.name = "@feat.00" -- Mark as SafeSEH compliant.
ffi.copy(o.space, symname)
local ofs = #symname + 1
o.strtabsize = f32(ofs + 4)
o.sect[0].ofs = f32(ffi.offsetof(o, "space") + ofs)
ffi.copy(o.space + ofs, symexport)
ofs = ofs + #symexport
o.sect[1].ofs = f32(ffi.offsetof(o, "space") + ofs)
-- Write PE object file.
local fp = savefile(output, "wb")
fp:write(ffi.string(o, ffi.sizeof(o)-4096+ofs))
bcsave_tail(fp, output, s)
end
local function bcsave_machobj(ctx, output, s, ffi)
ffi.cdef[[
typedef struct
{
uint32_t magic, cputype, cpusubtype, filetype, ncmds, sizeofcmds, flags;
} mach_header;
typedef struct
{
mach_header; uint32_t reserved;
} mach_header_64;
typedef struct {
uint32_t cmd, cmdsize;
char segname[16];
uint32_t vmaddr, vmsize, fileoff, filesize;
uint32_t maxprot, initprot, nsects, flags;
} mach_segment_command;
typedef struct {
uint32_t cmd, cmdsize;
char segname[16];
uint64_t vmaddr, vmsize, fileoff, filesize;
uint32_t maxprot, initprot, nsects, flags;
} mach_segment_command_64;
typedef struct {
char sectname[16], segname[16];
uint32_t addr, size;
uint32_t offset, align, reloff, nreloc, flags;
uint32_t reserved1, reserved2;
} mach_section;
typedef struct {
char sectname[16], segname[16];
uint64_t addr, size;
uint32_t offset, align, reloff, nreloc, flags;
uint32_t reserved1, reserved2, reserved3;
} mach_section_64;
typedef struct {
uint32_t cmd, cmdsize, symoff, nsyms, stroff, strsize;
} mach_symtab_command;
typedef struct {
int32_t strx;
uint8_t type, sect;
int16_t desc;
uint32_t value;
} mach_nlist;
typedef struct {
uint32_t strx;
uint8_t type, sect;
uint16_t desc;
uint64_t value;
} mach_nlist_64;
typedef struct
{
uint32_t magic, nfat_arch;
} mach_fat_header;
typedef struct
{
uint32_t cputype, cpusubtype, offset, size, align;
} mach_fat_arch;
typedef struct {
struct {
mach_header hdr;
mach_segment_command seg;
mach_section sec;
mach_symtab_command sym;
} arch[1];
mach_nlist sym_entry;
uint8_t space[4096];
} mach_obj;
typedef struct {
struct {
mach_header_64 hdr;
mach_segment_command_64 seg;
mach_section_64 sec;
mach_symtab_command sym;
} arch[1];
mach_nlist_64 sym_entry;
uint8_t space[4096];
} mach_obj_64;
typedef struct {
mach_fat_header fat;
mach_fat_arch fat_arch[4];
struct {
mach_header hdr;
mach_segment_command seg;
mach_section sec;
mach_symtab_command sym;
} arch[4];
mach_nlist sym_entry;
uint8_t space[4096];
} mach_fat_obj;
]]
local symname = '_'..LJBC_PREFIX..ctx.modname
local isfat, is64, align, mobj = false, false, 4, "mach_obj"
if ctx.arch == "x64" then
is64, align, mobj = true, 8, "mach_obj_64"
elseif ctx.arch == "arm" then
isfat, mobj = true, "mach_fat_obj"
else
check(ctx.arch == "x86", "unsupported architecture for OSX")
end
local function aligned(v, a) return bit.band(v+a-1, -a) end
local be32 = bit.bswap -- Mach-O FAT is BE, supported archs are LE.
-- Create Mach-O object and fill in header.
local o = ffi.new(mobj)
local mach_size = aligned(ffi.offsetof(o, "space")+#symname+2, align)
local cputype = ({ x86={7}, x64={0x01000007}, arm={7,12,12,12} })[ctx.arch]
local cpusubtype = ({ x86={3}, x64={3}, arm={3,6,9,11} })[ctx.arch]
if isfat then
o.fat.magic = be32(0xcafebabe)
o.fat.nfat_arch = be32(#cpusubtype)
end
-- Fill in sections and symbols.
for i=0,#cpusubtype-1 do
local ofs = 0
if isfat then
local a = o.fat_arch[i]
a.cputype = be32(cputype[i+1])
a.cpusubtype = be32(cpusubtype[i+1])
-- Subsequent slices overlap each other to share data.
ofs = ffi.offsetof(o, "arch") + i*ffi.sizeof(o.arch[0])
a.offset = be32(ofs)
a.size = be32(mach_size-ofs+#s)
end
local a = o.arch[i]
a.hdr.magic = is64 and 0xfeedfacf or 0xfeedface
a.hdr.cputype = cputype[i+1]
a.hdr.cpusubtype = cpusubtype[i+1]
a.hdr.filetype = 1
a.hdr.ncmds = 2
a.hdr.sizeofcmds = ffi.sizeof(a.seg)+ffi.sizeof(a.sec)+ffi.sizeof(a.sym)
a.seg.cmd = is64 and 0x19 or 0x1
a.seg.cmdsize = ffi.sizeof(a.seg)+ffi.sizeof(a.sec)
a.seg.vmsize = #s
a.seg.fileoff = mach_size-ofs
a.seg.filesize = #s
a.seg.maxprot = 1
a.seg.initprot = 1
a.seg.nsects = 1
ffi.copy(a.sec.sectname, "__data")
ffi.copy(a.sec.segname, "__DATA")
a.sec.size = #s
a.sec.offset = mach_size-ofs
a.sym.cmd = 2
a.sym.cmdsize = ffi.sizeof(a.sym)
a.sym.symoff = ffi.offsetof(o, "sym_entry")-ofs
a.sym.nsyms = 1
a.sym.stroff = ffi.offsetof(o, "sym_entry")+ffi.sizeof(o.sym_entry)-ofs
a.sym.strsize = aligned(#symname+2, align)
end
o.sym_entry.type = 0xf
o.sym_entry.sect = 1
o.sym_entry.strx = 1
ffi.copy(o.space+1, symname)
-- Write Macho-O object file.
local fp = savefile(output, "wb")
fp:write(ffi.string(o, mach_size))
bcsave_tail(fp, output, s)
end
local function bcsave_obj(ctx, output, s)
local ok, ffi = pcall(require, "ffi")
check(ok, "FFI library required to write this file type")
if ctx.os == "windows" then
return bcsave_peobj(ctx, output, s, ffi)
elseif ctx.os == "osx" then
return bcsave_machobj(ctx, output, s, ffi)
else
return bcsave_elfobj(ctx, output, s, ffi)
end
end
------------------------------------------------------------------------------
local function bclist(input, output)
local f = readfile(input)
require("jit.bc").dump(f, savefile(output, "w"), true)
end
local function bcsave(ctx, input, output)
local f = readfile(input)
local s = string.dump(f, ctx.strip)
local t = ctx.type
if not t then
t = detecttype(output)
ctx.type = t
end
if t == "raw" then
bcsave_raw(output, s)
else
if not ctx.modname then ctx.modname = detectmodname(input) end
if t == "obj" then
bcsave_obj(ctx, output, s)
else
bcsave_c(ctx, output, s)
end
end
end
local function docmd(...)
local arg = {...}
local n = 1
local list = false
local ctx = {
strip = true, arch = jit.arch, os = string.lower(jit.os),
type = false, modname = false,
}
while n <= #arg do
local a = arg[n]
if type(a) == "string" and string.sub(a, 1, 1) == "-" and a ~= "-" then
table.remove(arg, n)
if a == "--" then break end
for m=2,#a do
local opt = string.sub(a, m, m)
if opt == "l" then
list = true
elseif opt == "s" then
ctx.strip = true
elseif opt == "g" then
ctx.strip = false
else
if arg[n] == nil or m ~= #a then usage() end
if opt == "e" then
if n ~= 1 then usage() end
arg[1] = check(loadstring(arg[1]))
elseif opt == "n" then
ctx.modname = checkmodname(table.remove(arg, n))
elseif opt == "t" then
ctx.type = checkarg(table.remove(arg, n), map_type, "file type")
elseif opt == "a" then
ctx.arch = checkarg(table.remove(arg, n), map_arch, "architecture")
elseif opt == "o" then
ctx.os = checkarg(table.remove(arg, n), map_os, "OS name")
else
usage()
end
end
end
else
n = n + 1
end
end
if list then
if #arg == 0 or #arg > 2 then usage() end
bclist(arg[1], arg[2] or "-")
else
if #arg ~= 2 then usage() end
bcsave(ctx, arg[1], arg[2])
end
end
------------------------------------------------------------------------------
-- Public module functions.
module(...)
start = docmd -- Process -b command line option.