zig/lib/std/dynamic_library.zig
Andrew Kelley 4a69b11e74 add license header to all std lib files
add SPDX license identifier
copyright ownership is zig contributors
2020-08-20 16:07:04 -04:00

416 lines
14 KiB
Zig

// SPDX-License-Identifier: MIT
// Copyright (c) 2015-2020 Zig Contributors
// This file is part of [zig](https://ziglang.org/), which is MIT licensed.
// The MIT license requires this copyright notice to be included in all copies
// and substantial portions of the software.
const builtin = @import("builtin");
const std = @import("std.zig");
const mem = std.mem;
const os = std.os;
const assert = std.debug.assert;
const testing = std.testing;
const elf = std.elf;
const windows = std.os.windows;
const system = std.os.system;
const maxInt = std.math.maxInt;
const max = std.math.max;
pub const DynLib = switch (builtin.os.tag) {
.linux => if (builtin.link_libc) DlDynlib else ElfDynLib,
.windows => WindowsDynLib,
.macosx, .tvos, .watchos, .ios, .freebsd => DlDynlib,
else => void,
};
// The link_map structure is not completely specified beside the fields
// reported below, any libc is free to store additional data in the remaining
// space.
// An iterator is provided in order to traverse the linked list in a idiomatic
// fashion.
const LinkMap = extern struct {
l_addr: usize,
l_name: [*:0]const u8,
l_ld: ?*elf.Dyn,
l_next: ?*LinkMap,
l_prev: ?*LinkMap,
pub const Iterator = struct {
current: ?*LinkMap,
pub fn end(self: *Iterator) bool {
return self.current == null;
}
pub fn next(self: *Iterator) ?*LinkMap {
if (self.current) |it| {
self.current = it.l_next;
return it;
}
return null;
}
};
};
const RDebug = extern struct {
r_version: i32,
r_map: ?*LinkMap,
r_brk: usize,
r_ldbase: usize,
};
fn elf_get_va_offset(phdrs: []elf.Phdr) !usize {
for (phdrs) |*phdr| {
if (phdr.p_type == elf.PT_LOAD) {
return @ptrToInt(phdr) - phdr.p_vaddr;
}
}
return error.InvalidExe;
}
pub fn linkmap_iterator(phdrs: []elf.Phdr) !LinkMap.Iterator {
const va_offset = try elf_get_va_offset(phdrs);
const dyn_table = init: {
for (phdrs) |*phdr| {
if (phdr.p_type == elf.PT_DYNAMIC) {
const ptr = @intToPtr([*]elf.Dyn, va_offset + phdr.p_vaddr);
break :init ptr[0 .. phdr.p_memsz / @sizeOf(elf.Dyn)];
}
}
// No PT_DYNAMIC means this is either a statically-linked program or a
// badly corrupted one
return LinkMap.Iterator{ .current = null };
};
const link_map_ptr = init: {
for (dyn_table) |*dyn| {
switch (dyn.d_tag) {
elf.DT_DEBUG => {
const r_debug = @intToPtr(*RDebug, dyn.d_val);
if (r_debug.r_version != 1) return error.InvalidExe;
break :init r_debug.r_map;
},
elf.DT_PLTGOT => {
const got_table = @intToPtr([*]usize, dyn.d_val);
// The address to the link_map structure is stored in the
// second slot
break :init @intToPtr(?*LinkMap, got_table[1]);
},
else => {},
}
}
return error.InvalidExe;
};
return LinkMap.Iterator{ .current = link_map_ptr };
}
pub const ElfDynLib = struct {
strings: [*:0]u8,
syms: [*]elf.Sym,
hashtab: [*]os.Elf_Symndx,
versym: ?[*]u16,
verdef: ?*elf.Verdef,
memory: []align(mem.page_size) u8,
pub const Error = error{
NotElfFile,
NotDynamicLibrary,
MissingDynamicLinkingInformation,
ElfStringSectionNotFound,
ElfSymSectionNotFound,
ElfHashTableNotFound,
};
/// Trusts the file. Malicious file will be able to execute arbitrary code.
pub fn open(path: []const u8) !ElfDynLib {
const fd = try os.open(path, 0, os.O_RDONLY | os.O_CLOEXEC);
defer os.close(fd);
const stat = try os.fstat(fd);
const size = try std.math.cast(usize, stat.size);
// This one is to read the ELF info. We do more mmapping later
// corresponding to the actual LOAD sections.
const file_bytes = try os.mmap(
null,
mem.alignForward(size, mem.page_size),
os.PROT_READ,
os.MAP_PRIVATE,
fd,
0,
);
defer os.munmap(file_bytes);
const eh = @ptrCast(*elf.Ehdr, file_bytes.ptr);
if (!mem.eql(u8, eh.e_ident[0..4], "\x7fELF")) return error.NotElfFile;
if (eh.e_type != elf.ET.DYN) return error.NotDynamicLibrary;
const elf_addr = @ptrToInt(file_bytes.ptr);
// Iterate over the program header entries to find out the
// dynamic vector as well as the total size of the virtual memory.
var maybe_dynv: ?[*]usize = null;
var virt_addr_end: usize = 0;
{
var i: usize = 0;
var ph_addr: usize = elf_addr + eh.e_phoff;
while (i < eh.e_phnum) : ({
i += 1;
ph_addr += eh.e_phentsize;
}) {
const ph = @intToPtr(*elf.Phdr, ph_addr);
switch (ph.p_type) {
elf.PT_LOAD => virt_addr_end = max(virt_addr_end, ph.p_vaddr + ph.p_memsz),
elf.PT_DYNAMIC => maybe_dynv = @intToPtr([*]usize, elf_addr + ph.p_offset),
else => {},
}
}
}
const dynv = maybe_dynv orelse return error.MissingDynamicLinkingInformation;
// Reserve the entire range (with no permissions) so that we can do MAP_FIXED below.
const all_loaded_mem = try os.mmap(
null,
virt_addr_end,
os.PROT_NONE,
os.MAP_PRIVATE | os.MAP_ANONYMOUS,
-1,
0,
);
errdefer os.munmap(all_loaded_mem);
const base = @ptrToInt(all_loaded_mem.ptr);
// Now iterate again and actually load all the program sections.
{
var i: usize = 0;
var ph_addr: usize = elf_addr + eh.e_phoff;
while (i < eh.e_phnum) : ({
i += 1;
ph_addr += eh.e_phentsize;
}) {
const ph = @intToPtr(*elf.Phdr, ph_addr);
switch (ph.p_type) {
elf.PT_LOAD => {
// The VirtAddr may not be page-aligned; in such case there will be
// extra nonsense mapped before/after the VirtAddr,MemSiz
const aligned_addr = (base + ph.p_vaddr) & ~(@as(usize, mem.page_size) - 1);
const extra_bytes = (base + ph.p_vaddr) - aligned_addr;
const extended_memsz = mem.alignForward(ph.p_memsz + extra_bytes, mem.page_size);
const ptr = @intToPtr([*]align(mem.page_size) u8, aligned_addr);
const prot = elfToMmapProt(ph.p_flags);
if ((ph.p_flags & elf.PF_W) == 0) {
// If it does not need write access, it can be mapped from the fd.
_ = try os.mmap(
ptr,
extended_memsz,
prot,
os.MAP_PRIVATE | os.MAP_FIXED,
fd,
ph.p_offset - extra_bytes,
);
} else {
const sect_mem = try os.mmap(
ptr,
extended_memsz,
prot,
os.MAP_PRIVATE | os.MAP_FIXED | os.MAP_ANONYMOUS,
-1,
0,
);
mem.copy(u8, sect_mem, file_bytes[0..ph.p_filesz]);
}
},
else => {},
}
}
}
var maybe_strings: ?[*:0]u8 = null;
var maybe_syms: ?[*]elf.Sym = null;
var maybe_hashtab: ?[*]os.Elf_Symndx = null;
var maybe_versym: ?[*]u16 = null;
var maybe_verdef: ?*elf.Verdef = null;
{
var i: usize = 0;
while (dynv[i] != 0) : (i += 2) {
const p = base + dynv[i + 1];
switch (dynv[i]) {
elf.DT_STRTAB => maybe_strings = @intToPtr([*:0]u8, p),
elf.DT_SYMTAB => maybe_syms = @intToPtr([*]elf.Sym, p),
elf.DT_HASH => maybe_hashtab = @intToPtr([*]os.Elf_Symndx, p),
elf.DT_VERSYM => maybe_versym = @intToPtr([*]u16, p),
elf.DT_VERDEF => maybe_verdef = @intToPtr(*elf.Verdef, p),
else => {},
}
}
}
return ElfDynLib{
.memory = all_loaded_mem,
.strings = maybe_strings orelse return error.ElfStringSectionNotFound,
.syms = maybe_syms orelse return error.ElfSymSectionNotFound,
.hashtab = maybe_hashtab orelse return error.ElfHashTableNotFound,
.versym = maybe_versym,
.verdef = maybe_verdef,
};
}
pub const openC = @compileError("deprecated: renamed to openZ");
/// Trusts the file. Malicious file will be able to execute arbitrary code.
pub fn openZ(path_c: [*:0]const u8) !ElfDynLib {
return open(mem.spanZ(path_c));
}
/// Trusts the file
pub fn close(self: *ElfDynLib) void {
os.munmap(self.memory);
self.* = undefined;
}
pub fn lookup(self: *ElfDynLib, comptime T: type, name: [:0]const u8) ?T {
if (self.lookupAddress("", name)) |symbol| {
return @intToPtr(T, symbol);
} else {
return null;
}
}
/// Returns the address of the symbol
pub fn lookupAddress(self: *const ElfDynLib, vername: []const u8, name: []const u8) ?usize {
const maybe_versym = if (self.verdef == null) null else self.versym;
const OK_TYPES = (1 << elf.STT_NOTYPE | 1 << elf.STT_OBJECT | 1 << elf.STT_FUNC | 1 << elf.STT_COMMON);
const OK_BINDS = (1 << elf.STB_GLOBAL | 1 << elf.STB_WEAK | 1 << elf.STB_GNU_UNIQUE);
var i: usize = 0;
while (i < self.hashtab[1]) : (i += 1) {
if (0 == (@as(u32, 1) << @intCast(u5, self.syms[i].st_info & 0xf) & OK_TYPES)) continue;
if (0 == (@as(u32, 1) << @intCast(u5, self.syms[i].st_info >> 4) & OK_BINDS)) continue;
if (0 == self.syms[i].st_shndx) continue;
if (!mem.eql(u8, name, mem.spanZ(self.strings + self.syms[i].st_name))) continue;
if (maybe_versym) |versym| {
if (!checkver(self.verdef.?, versym[i], vername, self.strings))
continue;
}
return @ptrToInt(self.memory.ptr) + self.syms[i].st_value;
}
return null;
}
fn elfToMmapProt(elf_prot: u64) u32 {
var result: u32 = os.PROT_NONE;
if ((elf_prot & elf.PF_R) != 0) result |= os.PROT_READ;
if ((elf_prot & elf.PF_W) != 0) result |= os.PROT_WRITE;
if ((elf_prot & elf.PF_X) != 0) result |= os.PROT_EXEC;
return result;
}
};
fn checkver(def_arg: *elf.Verdef, vsym_arg: i32, vername: []const u8, strings: [*:0]u8) bool {
var def = def_arg;
const vsym = @bitCast(u32, vsym_arg) & 0x7fff;
while (true) {
if (0 == (def.vd_flags & elf.VER_FLG_BASE) and (def.vd_ndx & 0x7fff) == vsym)
break;
if (def.vd_next == 0)
return false;
def = @intToPtr(*elf.Verdef, @ptrToInt(def) + def.vd_next);
}
const aux = @intToPtr(*elf.Verdaux, @ptrToInt(def) + def.vd_aux);
return mem.eql(u8, vername, mem.spanZ(strings + aux.vda_name));
}
pub const WindowsDynLib = struct {
pub const Error = error{FileNotFound};
dll: windows.HMODULE,
pub fn open(path: []const u8) !WindowsDynLib {
const path_w = try windows.sliceToPrefixedFileW(path);
return openW(path_w.span().ptr);
}
pub const openC = @compileError("deprecated: renamed to openZ");
pub fn openZ(path_c: [*:0]const u8) !WindowsDynLib {
const path_w = try windows.cStrToPrefixedFileW(path_c);
return openW(path_w.span().ptr);
}
pub fn openW(path_w: [*:0]const u16) !WindowsDynLib {
return WindowsDynLib{
// + 4 to skip over the \??\
.dll = try windows.LoadLibraryW(path_w + 4),
};
}
pub fn close(self: *WindowsDynLib) void {
windows.FreeLibrary(self.dll);
self.* = undefined;
}
pub fn lookup(self: *WindowsDynLib, comptime T: type, name: [:0]const u8) ?T {
if (windows.kernel32.GetProcAddress(self.dll, name.ptr)) |addr| {
return @ptrCast(T, addr);
} else {
return null;
}
}
};
pub const DlDynlib = struct {
pub const Error = error{FileNotFound};
handle: *c_void,
pub fn open(path: []const u8) !DlDynlib {
const path_c = try os.toPosixPath(path);
return openZ(&path_c);
}
pub const openC = @compileError("deprecated: renamed to openZ");
pub fn openZ(path_c: [*:0]const u8) !DlDynlib {
return DlDynlib{
.handle = system.dlopen(path_c, system.RTLD_LAZY) orelse {
return error.FileNotFound;
},
};
}
pub fn close(self: *DlDynlib) void {
_ = system.dlclose(self.handle);
self.* = undefined;
}
pub fn lookup(self: *DlDynlib, comptime T: type, name: [:0]const u8) ?T {
// dlsym (and other dl-functions) secretly take shadow parameter - return address on stack
// https://gcc.gnu.org/bugzilla/show_bug.cgi?id=66826
if (@call(.{ .modifier = .never_tail }, system.dlsym, .{ self.handle, name.ptr })) |symbol| {
return @ptrCast(T, symbol);
} else {
return null;
}
}
};
test "dynamic_library" {
const libname = switch (builtin.os.tag) {
.linux, .freebsd => "invalid_so.so",
.windows => "invalid_dll.dll",
.macosx, .tvos, .watchos, .ios => "invalid_dylib.dylib",
else => return error.SkipZigTest,
};
const dynlib = DynLib.open(libname) catch |err| {
testing.expect(err == error.FileNotFound);
return;
};
}