loader.h source code [codebrowser/EXTERNAL_HEADERS/mach-o/loader.h]

1	/*
2	* Copyright (c) 1999-2010 Apple Inc. All Rights Reserved.
3	*
4	* @APPLE_LICENSE_HEADER_START@
5	*
6	* This file contains Original Code and/or Modifications of Original Code
7	* as defined in and that are subject to the Apple Public Source License
8	* Version 2.0 (the 'License'). You may not use this file except in
9	* compliance with the License. Please obtain a copy of the License at
10	* http://www.opensource.apple.com/apsl/ and read it before using this
11	* file.
12	*
13	* The Original Code and all software distributed under the License are
14	* distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
15	* EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
16	* INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
17	* FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
18	* Please see the License for the specific language governing rights and
19	* limitations under the License.
20	*
21	* @APPLE_LICENSE_HEADER_END@
22	*/
23	#ifndef _MACHO_LOADER_H_
24	#define _MACHO_LOADER_H_
25
26	/*
27	* This file describes the format of mach object files.
28	*/
29	#include <stdint.h>
30
31	/*
32	* <mach/machine.h> is needed here for the cpu_type_t and cpu_subtype_t types
33	* and contains the constants for the possible values of these types.
34	*/
35	#include <mach/machine.h>
36
37	/*
38	* <mach/vm_prot.h> is needed here for the vm_prot_t type and contains the
39	* constants that are or'ed together for the possible values of this type.
40	*/
41	#include <mach/vm_prot.h>
42
43	/*
44	* <machine/thread_status.h> is expected to define the flavors of the thread
45	* states and the structures of those flavors for each machine.
46	*/
47	#include <mach/machine/thread_status.h>
48	#include <architecture/byte_order.h>
49
50	/*
51	* The 32-bit mach header appears at the very beginning of the object file for
52	* 32-bit architectures.
53	*/
54	struct mach_header {
55	uint32_t magic; / mach magic number identifier /
56	cpu_type_t cputype; / cpu specifier /
57	cpu_subtype_t cpusubtype; / machine specifier /
58	uint32_t filetype; / type of file /
59	uint32_t ncmds; / number of load commands /
60	uint32_t sizeofcmds; / the size of all the load commands /
61	uint32_t flags; / flags /
62	};
63
64	/ Constant for the magic field of the mach_header (32-bit architectures) /
65	#define MH_MAGIC 0xfeedface /* the mach magic number */
66	#define MH_CIGAM 0xcefaedfe /* NXSwapInt(MH_MAGIC) */
67
68	/*
69	* The 64-bit mach header appears at the very beginning of object files for
70	* 64-bit architectures.
71	*/
72	struct mach_header_64 {
73	uint32_t magic; / mach magic number identifier /
74	cpu_type_t cputype; / cpu specifier /
75	cpu_subtype_t cpusubtype; / machine specifier /
76	uint32_t filetype; / type of file /
77	uint32_t ncmds; / number of load commands /
78	uint32_t sizeofcmds; / the size of all the load commands /
79	uint32_t flags; / flags /
80	uint32_t reserved; / reserved /
81	};
82
83	/ Constant for the magic field of the mach_header_64 (64-bit architectures) /
84	#define MH_MAGIC_64 0xfeedfacf /* the 64-bit mach magic number */
85	#define MH_CIGAM_64 0xcffaedfe /* NXSwapInt(MH_MAGIC_64) */
86
87	/*
88	* The layout of the file depends on the filetype. For all but the MH_OBJECT
89	* file type the segments are padded out and aligned on a segment alignment
90	* boundary for efficient demand pageing. The MH_EXECUTE, MH_FVMLIB, MH_DYLIB,
91	* MH_DYLINKER and MH_BUNDLE file types also have the headers included as part
92	* of their first segment.
93	*
94	* The file type MH_OBJECT is a compact format intended as output of the
95	* assembler and input (and possibly output) of the link editor (the .o
96	* format). All sections are in one unnamed segment with no segment padding.
97	* This format is used as an executable format when the file is so small the
98	* segment padding greatly increases its size.
99	*
100	* The file type MH_PRELOAD is an executable format intended for things that
101	* are not executed under the kernel (proms, stand alones, kernels, etc). The
102	* format can be executed under the kernel but may demand paged it and not
103	* preload it before execution.
104	*
105	* A core file is in MH_CORE format and can be any in an arbritray legal
106	* Mach-O file.
107	*
108	* Constants for the filetype field of the mach_header
109	*/
110	#define MH_OBJECT 0x1 /* relocatable object file */
111	#define MH_EXECUTE 0x2 /* demand paged executable file */
112	#define MH_FVMLIB 0x3 /* fixed VM shared library file */
113	#define MH_CORE 0x4 /* core file */
114	#define MH_PRELOAD 0x5 /* preloaded executable file */
115	#define MH_DYLIB 0x6 /* dynamically bound shared library */
116	#define MH_DYLINKER 0x7 /* dynamic link editor */
117	#define MH_BUNDLE 0x8 /* dynamically bound bundle file */
118	#define MH_DYLIB_STUB 0x9 /* shared library stub for static */
119	/ linking only, no section contents /
120	#define MH_DSYM 0xa /* companion file with only debug */
121	/ sections /
122	#define MH_KEXT_BUNDLE 0xb /* x86_64 kexts */
123
124	/ Constants for the flags field of the mach_header /
125	#define MH_NOUNDEFS 0x1 /* the object file has no undefined
126	references */
127	#define MH_INCRLINK 0x2 /* the object file is the output of an
128	incremental link against a base file
129	and can't be link edited again */
130	#define MH_DYLDLINK 0x4 /* the object file is input for the
131	dynamic linker and can't be staticly
132	link edited again */
133	#define MH_BINDATLOAD 0x8 /* the object file's undefined
134	references are bound by the dynamic
135	linker when loaded. */
136	#define MH_PREBOUND 0x10 /* the file has its dynamic undefined
137	references prebound. */
138	#define MH_SPLIT_SEGS 0x20 /* the file has its read-only and
139	read-write segments split */
140	#define MH_LAZY_INIT 0x40 /* the shared library init routine is
141	to be run lazily via catching memory
142	faults to its writeable segments
143	(obsolete) */
144	#define MH_TWOLEVEL 0x80 /* the image is using two-level name
145	space bindings */
146	#define MH_FORCE_FLAT 0x100 /* the executable is forcing all images
147	to use flat name space bindings */
148	#define MH_NOMULTIDEFS 0x200 /* this umbrella guarantees no multiple
149	defintions of symbols in its
150	sub-images so the two-level namespace
151	hints can always be used. */
152	#define MH_NOFIXPREBINDING 0x400 /* do not have dyld notify the
153	prebinding agent about this
154	executable */
155	#define MH_PREBINDABLE 0x800 /* the binary is not prebound but can
156	have its prebinding redone. only used
157	when MH_PREBOUND is not set. */
158	#define MH_ALLMODSBOUND 0x1000 /* indicates that this binary binds to
159	all two-level namespace modules of
160	its dependent libraries. only used
161	when MH_PREBINDABLE and MH_TWOLEVEL
162	are both set. */
163	#define MH_SUBSECTIONS_VIA_SYMBOLS 0x2000/* safe to divide up the sections into
164	sub-sections via symbols for dead
165	code stripping */
166	#define MH_CANONICAL 0x4000 /* the binary has been canonicalized
167	via the unprebind operation */
168	#define MH_WEAK_DEFINES 0x8000 /* the final linked image contains
169	external weak symbols */
170	#define MH_BINDS_TO_WEAK 0x10000 /* the final linked image uses
171	weak symbols */
172
173	#define MH_ALLOW_STACK_EXECUTION 0x20000/* When this bit is set, all stacks
174	in the task will be given stack
175	execution privilege. Only used in
176	MH_EXECUTE filetypes. */
177	#define MH_ROOT_SAFE 0x40000 /* When this bit is set, the binary
178	declares it is safe for use in
179	processes with uid zero */
180
181	#define MH_SETUID_SAFE 0x80000 /* When this bit is set, the binary
182	declares it is safe for use in
183	processes when issetugid() is true */
184
185	#define MH_NO_REEXPORTED_DYLIBS 0x100000 /* When this bit is set on a dylib,
186	the static linker does not need to
187	examine dependent dylibs to see
188	if any are re-exported */
189	#define MH_PIE 0x200000 /* When this bit is set, the OS will
190	load the main executable at a
191	random address. Only used in
192	MH_EXECUTE filetypes. */
193	#define MH_DEAD_STRIPPABLE_DYLIB 0x400000 /* Only for use on dylibs. When
194	linking against a dylib that
195	has this bit set, the static linker
196	will automatically not create a
197	LC_LOAD_DYLIB load command to the
198	dylib if no symbols are being
199	referenced from the dylib. */
200	#define MH_HAS_TLV_DESCRIPTORS 0x800000 /* Contains a section of type
201	S_THREAD_LOCAL_VARIABLES */
202
203	#define MH_NO_HEAP_EXECUTION 0x1000000 /* When this bit is set, the OS will
204	run the main executable with
205	a non-executable heap even on
206	platforms (e.g. i386) that don't
207	require it. Only used in MH_EXECUTE
208	filetypes. */
209
210	#define MH_APP_EXTENSION_SAFE 0x02000000 /* The code was linked for use in an
211	application extension. */
212
213	/*
214	* The load commands directly follow the mach_header. The total size of all
215	* of the commands is given by the sizeofcmds field in the mach_header. All
216	* load commands must have as their first two fields cmd and cmdsize. The cmd
217	* field is filled in with a constant for that command type. Each command type
218	* has a structure specifically for it. The cmdsize field is the size in bytes
219	* of the particular load command structure plus anything that follows it that
220	* is a part of the load command (i.e. section structures, strings, etc.). To
221	* advance to the next load command the cmdsize can be added to the offset or
222	* pointer of the current load command. The cmdsize for 32-bit architectures
223	* MUST be a multiple of 4 bytes and for 64-bit architectures MUST be a multiple
224	* of 8 bytes (these are forever the maximum alignment of any load commands).
225	* The padded bytes must be zero. All tables in the object file must also
226	* follow these rules so the file can be memory mapped. Otherwise the pointers
227	* to these tables will not work well or at all on some machines. With all
228	* padding zeroed like objects will compare byte for byte.
229	*/
230	struct load_command {
231	uint32_t cmd; / type of load command /
232	uint32_t cmdsize; / total size of command in bytes /
233	};
234
235	/*
236	* After MacOS X 10.1 when a new load command is added that is required to be
237	* understood by the dynamic linker for the image to execute properly the
238	* LC_REQ_DYLD bit will be or'ed into the load command constant. If the dynamic
239	* linker sees such a load command it it does not understand will issue a
240	* "unknown load command required for execution" error and refuse to use the
241	* image. Other load commands without this bit that are not understood will
242	* simply be ignored.
243	*/
244	#define LC_REQ_DYLD 0x80000000
245
246	/ Constants for the cmd field of all load commands, the type /
247	#define LC_SEGMENT 0x1 /* segment of this file to be mapped */
248	#define LC_SYMTAB 0x2 /* link-edit stab symbol table info */
249	#define LC_SYMSEG 0x3 /* link-edit gdb symbol table info (obsolete) */
250	#define LC_THREAD 0x4 /* thread */
251	#define LC_UNIXTHREAD 0x5 /* unix thread (includes a stack) */
252	#define LC_LOADFVMLIB 0x6 /* load a specified fixed VM shared library */
253	#define LC_IDFVMLIB 0x7 /* fixed VM shared library identification */
254	#define LC_IDENT 0x8 /* object identification info (obsolete) */
255	#define LC_FVMFILE 0x9 /* fixed VM file inclusion (internal use) */
256	#define LC_PREPAGE 0xa /* prepage command (internal use) */
257	#define LC_DYSYMTAB 0xb /* dynamic link-edit symbol table info */
258	#define LC_LOAD_DYLIB 0xc /* load a dynamically linked shared library */
259	#define LC_ID_DYLIB 0xd /* dynamically linked shared lib ident */
260	#define LC_LOAD_DYLINKER 0xe /* load a dynamic linker */
261	#define LC_ID_DYLINKER 0xf /* dynamic linker identification */
262	#define LC_PREBOUND_DYLIB 0x10 /* modules prebound for a dynamically */
263	/ linked shared library /
264	#define LC_ROUTINES 0x11 /* image routines */
265	#define LC_SUB_FRAMEWORK 0x12 /* sub framework */
266	#define LC_SUB_UMBRELLA 0x13 /* sub umbrella */
267	#define LC_SUB_CLIENT 0x14 /* sub client */
268	#define LC_SUB_LIBRARY 0x15 /* sub library */
269	#define LC_TWOLEVEL_HINTS 0x16 /* two-level namespace lookup hints */
270	#define LC_PREBIND_CKSUM 0x17 /* prebind checksum */
271
272	/*
273	* load a dynamically linked shared library that is allowed to be missing
274	* (all symbols are weak imported).
275	*/
276	#define LC_LOAD_WEAK_DYLIB (0x18 \| LC_REQ_DYLD)
277
278	#define LC_SEGMENT_64 0x19 /* 64-bit segment of this file to be
279	mapped */
280	#define LC_ROUTINES_64 0x1a /* 64-bit image routines */
281	#define LC_UUID 0x1b /* the uuid */
282	#define LC_RPATH (0x1c \| LC_REQ_DYLD) /* runpath additions */
283	#define LC_CODE_SIGNATURE 0x1d /* local of code signature */
284	#define LC_SEGMENT_SPLIT_INFO 0x1e /* local of info to split segments */
285	#define LC_REEXPORT_DYLIB (0x1f \| LC_REQ_DYLD) /* load and re-export dylib */
286	#define LC_LAZY_LOAD_DYLIB 0x20 /* delay load of dylib until first use */
287	#define LC_ENCRYPTION_INFO 0x21 /* encrypted segment information */
288	#define LC_DYLD_INFO 0x22 /* compressed dyld information */
289	#define LC_DYLD_INFO_ONLY (0x22\|LC_REQ_DYLD) /* compressed dyld information only */
290	#define LC_LOAD_UPWARD_DYLIB (0x23 \| LC_REQ_DYLD) /* load upward dylib */
291	#define LC_VERSION_MIN_MACOSX 0x24 /* build for MacOSX min OS version */
292	#define LC_VERSION_MIN_IPHONEOS 0x25 /* build for iPhoneOS min OS version */
293	#define LC_FUNCTION_STARTS 0x26 /* compressed table of function start addresses */
294	#define LC_DYLD_ENVIRONMENT 0x27 /* string for dyld to treat
295	like environment variable */
296	#define LC_MAIN (0x28\|LC_REQ_DYLD) /* replacement for LC_UNIXTHREAD */
297	#define LC_DATA_IN_CODE 0x29 /* table of non-instructions in __text */
298	#define LC_SOURCE_VERSION 0x2A /* source version used to build binary */
299	#define LC_DYLIB_CODE_SIGN_DRS 0x2B /* Code signing DRs copied from linked dylibs */
300	#define LC_ENCRYPTION_INFO_64 0x2C /* 64-bit encrypted segment information */
301	#define LC_LINKER_OPTION 0x2D /* linker options in MH_OBJECT files */
302	#define LC_LINKER_OPTIMIZATION_HINT 0x2E /* optimization hints in MH_OBJECT files */
303	#define LC_VERSION_MIN_TVOS 0x2F /* build for AppleTV min OS version */
304	#define LC_VERSION_MIN_WATCHOS 0x30 /* build for Watch min OS version */
305	#define LC_NOTE 0x31 /* arbitrary data included within a Mach-O file */
306	#define LC_BUILD_VERSION 0x32 /* build for platform min OS version */
307
308	/*
309	* A variable length string in a load command is represented by an lc_str
310	* union. The strings are stored just after the load command structure and
311	* the offset is from the start of the load command structure. The size
312	* of the string is reflected in the cmdsize field of the load command.
313	* Once again any padded bytes to bring the cmdsize field to a multiple
314	* of 4 bytes must be zero.
315	*/
316	union lc_str {
317	uint32_t offset; / offset to the string /
318	#ifndef __LP64__
319	char ptr; /* pointer to the string /
320	#endif
321	};
322
323	/*
324	* The segment load command indicates that a part of this file is to be
325	* mapped into the task's address space. The size of this segment in memory,
326	* vmsize, maybe equal to or larger than the amount to map from this file,
327	* filesize. The file is mapped starting at fileoff to the beginning of
328	* the segment in memory, vmaddr. The rest of the memory of the segment,
329	* if any, is allocated zero fill on demand. The segment's maximum virtual
330	* memory protection and initial virtual memory protection are specified
331	* by the maxprot and initprot fields. If the segment has sections then the
332	* section structures directly follow the segment command and their size is
333	* reflected in cmdsize.
334	*/
335	struct segment_command { / for 32-bit architectures /
336	uint32_t cmd; / LC_SEGMENT /
337	uint32_t cmdsize; / includes sizeof section structs /
338	char segname[`16`]; / segment name /
339	uint32_t vmaddr; / memory address of this segment /
340	uint32_t vmsize; / memory size of this segment /
341	uint32_t fileoff; / file offset of this segment /
342	uint32_t filesize; / amount to map from the file /
343	vm_prot_t maxprot; / maximum VM protection /
344	vm_prot_t initprot; / initial VM protection /
345	uint32_t nsects; / number of sections in segment /
346	uint32_t flags; / flags /
347	};
348
349	/*
350	* The 64-bit segment load command indicates that a part of this file is to be
351	* mapped into a 64-bit task's address space. If the 64-bit segment has
352	* sections then section_64 structures directly follow the 64-bit segment
353	* command and their size is reflected in cmdsize.
354	*/
355	struct segment_command_64 { / for 64-bit architectures /
356	uint32_t cmd; / LC_SEGMENT_64 /
357	uint32_t cmdsize; / includes sizeof section_64 structs /
358	char segname[`16`]; / segment name /
359	uint64_t vmaddr; / memory address of this segment /
360	uint64_t vmsize; / memory size of this segment /
361	uint64_t fileoff; / file offset of this segment /
362	uint64_t filesize; / amount to map from the file /
363	vm_prot_t maxprot; / maximum VM protection /
364	vm_prot_t initprot; / initial VM protection /
365	uint32_t nsects; / number of sections in segment /
366	uint32_t flags; / flags /
367	};
368
369	/ Constants for the flags field of the segment_command /
370	#define SG_HIGHVM 0x1 /* the file contents for this segment is for
371	the high part of the VM space, the low part
372	is zero filled (for stacks in core files) */
373	#define SG_FVMLIB 0x2 /* this segment is the VM that is allocated by
374	a fixed VM library, for overlap checking in
375	the link editor */
376	#define SG_NORELOC 0x4 /* this segment has nothing that was relocated
377	in it and nothing relocated to it, that is
378	it maybe safely replaced without relocation*/
379	#define SG_PROTECTED_VERSION_1 0x8 /* This segment is protected. If the
380	segment starts at file offset 0, the
381	first page of the segment is not
382	protected. All other pages of the
383	segment are protected. */
384
385	/*
386	* A segment is made up of zero or more sections. Non-MH_OBJECT files have
387	* all of their segments with the proper sections in each, and padded to the
388	* specified segment alignment when produced by the link editor. The first
389	* segment of a MH_EXECUTE and MH_FVMLIB format file contains the mach_header
390	* and load commands of the object file before its first section. The zero
391	* fill sections are always last in their segment (in all formats). This
392	* allows the zeroed segment padding to be mapped into memory where zero fill
393	* sections might be. The gigabyte zero fill sections, those with the section
394	* type S_GB_ZEROFILL, can only be in a segment with sections of this type.
395	* These segments are then placed after all other segments.
396	*
397	* The MH_OBJECT format has all of its sections in one segment for
398	* compactness. There is no padding to a specified segment boundary and the
399	* mach_header and load commands are not part of the segment.
400	*
401	* Sections with the same section name, sectname, going into the same segment,
402	* segname, are combined by the link editor. The resulting section is aligned
403	* to the maximum alignment of the combined sections and is the new section's
404	* alignment. The combined sections are aligned to their original alignment in
405	* the combined section. Any padded bytes to get the specified alignment are
406	* zeroed.
407	*
408	* The format of the relocation entries referenced by the reloff and nreloc
409	* fields of the section structure for mach object files is described in the
410	* header file <reloc.h>.
411	*/
412	struct section { / for 32-bit architectures /
413	char sectname[`16`]; / name of this section /
414	char segname[`16`]; / segment this section goes in /
415	uint32_t addr; / memory address of this section /
416	uint32_t size; / size in bytes of this section /
417	uint32_t offset; / file offset of this section /
418	uint32_t align; / section alignment (power of 2) /
419	uint32_t reloff; / file offset of relocation entries /
420	uint32_t nreloc; / number of relocation entries /
421	uint32_t flags; / flags (section type and attributes)/
422	uint32_t reserved1; / reserved (for offset or index) /
423	uint32_t reserved2; / reserved (for count or sizeof) /
424	};
425
426	struct section_64 { / for 64-bit architectures /
427	char sectname[`16`]; / name of this section /
428	char segname[`16`]; / segment this section goes in /
429	uint64_t addr; / memory address of this section /
430	uint64_t size; / size in bytes of this section /
431	uint32_t offset; / file offset of this section /
432	uint32_t align; / section alignment (power of 2) /
433	uint32_t reloff; / file offset of relocation entries /
434	uint32_t nreloc; / number of relocation entries /
435	uint32_t flags; / flags (section type and attributes)/
436	uint32_t reserved1; / reserved (for offset or index) /
437	uint32_t reserved2; / reserved (for count or sizeof) /
438	uint32_t reserved3; / reserved /
439	};
440
441	/*
442	* The flags field of a section structure is separated into two parts a section
443	* type and section attributes. The section types are mutually exclusive (it
444	* can only have one type) but the section attributes are not (it may have more
445	* than one attribute).
446	*/
447	#define SECTION_TYPE 0x000000ff /* 256 section types */
448	#define SECTION_ATTRIBUTES 0xffffff00 /* 24 section attributes */
449
450	/ Constants for the type of a section /
451	#define S_REGULAR 0x0 /* regular section */
452	#define S_ZEROFILL 0x1 /* zero fill on demand section */
453	#define S_CSTRING_LITERALS 0x2 /* section with only literal C strings*/
454	#define S_4BYTE_LITERALS 0x3 /* section with only 4 byte literals */
455	#define S_8BYTE_LITERALS 0x4 /* section with only 8 byte literals */
456	#define S_LITERAL_POINTERS 0x5 /* section with only pointers to */
457	/ literals /
458	/*
459	* For the two types of symbol pointers sections and the symbol stubs section
460	* they have indirect symbol table entries. For each of the entries in the
461	* section the indirect symbol table entries, in corresponding order in the
462	* indirect symbol table, start at the index stored in the reserved1 field
463	* of the section structure. Since the indirect symbol table entries
464	* correspond to the entries in the section the number of indirect symbol table
465	* entries is inferred from the size of the section divided by the size of the
466	* entries in the section. For symbol pointers sections the size of the entries
467	* in the section is 4 bytes and for symbol stubs sections the byte size of the
468	* stubs is stored in the reserved2 field of the section structure.
469	*/
470	#define S_NON_LAZY_SYMBOL_POINTERS 0x6 /* section with only non-lazy
471	symbol pointers */
472	#define S_LAZY_SYMBOL_POINTERS 0x7 /* section with only lazy symbol
473	pointers */
474	#define S_SYMBOL_STUBS 0x8 /* section with only symbol
475	stubs, byte size of stub in
476	the reserved2 field */
477	#define S_MOD_INIT_FUNC_POINTERS 0x9 /* section with only function
478	pointers for initialization*/
479	#define S_MOD_TERM_FUNC_POINTERS 0xa /* section with only function
480	pointers for termination */
481	#define S_COALESCED 0xb /* section contains symbols that
482	are to be coalesced */
483	#define S_GB_ZEROFILL 0xc /* zero fill on demand section
484	(that can be larger than 4
485	gigabytes) */
486	#define S_INTERPOSING 0xd /* section with only pairs of
487	function pointers for
488	interposing */
489	#define S_16BYTE_LITERALS 0xe /* section with only 16 byte
490	literals */
491	#define S_DTRACE_DOF 0xf /* section contains
492	DTrace Object Format */
493	#define S_LAZY_DYLIB_SYMBOL_POINTERS 0x10 /* section with only lazy
494	symbol pointers to lazy
495	loaded dylibs */
496	/*
497	* Section types to support thread local variables
498	*/
499	#define S_THREAD_LOCAL_REGULAR 0x11 /* template of initial
500	values for TLVs */
501	#define S_THREAD_LOCAL_ZEROFILL 0x12 /* template of initial
502	values for TLVs */
503	#define S_THREAD_LOCAL_VARIABLES 0x13 /* TLV descriptors */
504	#define S_THREAD_LOCAL_VARIABLE_POINTERS 0x14 /* pointers to TLV
505	descriptors */
506	#define S_THREAD_LOCAL_INIT_FUNCTION_POINTERS 0x15 /* functions to call
507	to initialize TLV
508	values */
509
510	/*
511	* Constants for the section attributes part of the flags field of a section
512	* structure.
513	*/
514	#define SECTION_ATTRIBUTES_USR 0xff000000 /* User setable attributes */
515	#define S_ATTR_PURE_INSTRUCTIONS 0x80000000 /* section contains only true
516	machine instructions */
517	#define S_ATTR_NO_TOC 0x40000000 /* section contains coalesced
518	symbols that are not to be
519	in a ranlib table of
520	contents */
521	#define S_ATTR_STRIP_STATIC_SYMS 0x20000000 /* ok to strip static symbols
522	in this section in files
523	with the MH_DYLDLINK flag */
524	#define S_ATTR_NO_DEAD_STRIP 0x10000000 /* no dead stripping */
525	#define S_ATTR_LIVE_SUPPORT 0x08000000 /* blocks are live if they
526	reference live blocks */
527	#define S_ATTR_SELF_MODIFYING_CODE 0x04000000 /* Used with i386 code stubs
528	written on by dyld */
529	/*
530	* If a segment contains any sections marked with S_ATTR_DEBUG then all
531	* sections in that segment must have this attribute. No section other than
532	* a section marked with this attribute may reference the contents of this
533	* section. A section with this attribute may contain no symbols and must have
534	* a section type S_REGULAR. The static linker will not copy section contents
535	* from sections with this attribute into its output file. These sections
536	* generally contain DWARF debugging info.
537	*/
538	#define S_ATTR_DEBUG 0x02000000 /* a debug section */
539	#define SECTION_ATTRIBUTES_SYS 0x00ffff00 /* system setable attributes */
540	#define S_ATTR_SOME_INSTRUCTIONS 0x00000400 /* section contains some
541	machine instructions */
542	#define S_ATTR_EXT_RELOC 0x00000200 /* section has external
543	relocation entries */
544	#define S_ATTR_LOC_RELOC 0x00000100 /* section has local
545	relocation entries */
546
547
548	/*
549	* The names of segments and sections in them are mostly meaningless to the
550	* link-editor. But there are few things to support traditional UNIX
551	* executables that require the link-editor and assembler to use some names
552	* agreed upon by convention.
553	*
554	* The initial protection of the "__TEXT" segment has write protection turned
555	* off (not writeable).
556	*
557	* The link-editor will allocate common symbols at the end of the "__common"
558	* section in the "__DATA" segment. It will create the section and segment
559	* if needed.
560	*/
561
562	/ The currently known segment names and the section names in those segments /
563
564	#define SEG_PAGEZERO "__PAGEZERO" /* the pagezero segment which has no */
565	/ protections and catches NULL /
566	/ references for MH_EXECUTE files /
567
568
569	#define SEG_TEXT "__TEXT" /* the tradition UNIX text segment */
570	#define SECT_TEXT "__text" /* the real text part of the text */
571	/ section no headers, and no padding /
572	#define SECT_FVMLIB_INIT0 "__fvmlib_init0" /* the fvmlib initialization */
573	/ section /
574	#define SECT_FVMLIB_INIT1 "__fvmlib_init1" /* the section following the */
575	/ fvmlib initialization /
576	/ section /
577
578	#define SEG_DATA "__DATA" /* the tradition UNIX data segment */
579	#define SECT_DATA "__data" /* the real initialized data section */
580	/ no padding, no bss overlap /
581	#define SECT_BSS "__bss" /* the real uninitialized data section*/
582	/ no padding /
583	#define SECT_COMMON "__common" /* the section common symbols are */
584	/ allocated in by the link editor /
585
586	#define SEG_OBJC "__OBJC" /* objective-C runtime segment */
587	#define SECT_OBJC_SYMBOLS "__symbol_table" /* symbol table */
588	#define SECT_OBJC_MODULES "__module_info" /* module information */
589	#define SECT_OBJC_STRINGS "__selector_strs" /* string table */
590	#define SECT_OBJC_REFS "__selector_refs" /* string table */
591
592	#define SEG_ICON "__ICON" /* the icon segment */
593	#define SECT_ICON_HEADER "__header" /* the icon headers */
594	#define SECT_ICON_TIFF "__tiff" /* the icons in tiff format */
595
596	#define SEG_LINKEDIT "__LINKEDIT" /* the segment containing all structs */
597	/ created and maintained by the link /
598	/ editor. Created with -seglinkedit /
599	/ option to ld(1) for MH_EXECUTE and /
600	/ FVMLIB file types only /
601
602	#define SEG_UNIXSTACK "__UNIXSTACK" /* the unix stack segment */
603
604	#define SEG_IMPORT "__IMPORT" /* the segment for the self (dyld) */
605	/ modifing code stubs that has read, /
606	/ write and execute permissions /
607
608	/*
609	* Fixed virtual memory shared libraries are identified by two things. The
610	* target pathname (the name of the library as found for execution), and the
611	* minor version number. The address of where the headers are loaded is in
612	* header_addr. (THIS IS OBSOLETE and no longer supported).
613	*/
614	struct fvmlib {
615	union lc_str name; / library's target pathname /
616	uint32_t minor_version; / library's minor version number /
617	uint32_t header_addr; / library's header address /
618	};
619
620	/*
621	* A fixed virtual shared library (filetype == MH_FVMLIB in the mach header)
622	* contains a fvmlib_command (cmd == LC_IDFVMLIB) to identify the library.
623	* An object that uses a fixed virtual shared library also contains a
624	* fvmlib_command (cmd == LC_LOADFVMLIB) for each library it uses.
625	* (THIS IS OBSOLETE and no longer supported).
626	*/
627	struct fvmlib_command {
628	uint32_t cmd; / LC_IDFVMLIB or LC_LOADFVMLIB /
629	uint32_t cmdsize; / includes pathname string /
630	struct fvmlib fvmlib; / the library identification /
631	};
632
633	/*
634	* Dynamicly linked shared libraries are identified by two things. The
635	* pathname (the name of the library as found for execution), and the
636	* compatibility version number. The pathname must match and the compatibility
637	* number in the user of the library must be greater than or equal to the
638	* library being used. The time stamp is used to record the time a library was
639	* built and copied into user so it can be use to determined if the library used
640	* at runtime is exactly the same as used to built the program.
641	*/
642	struct dylib {
643	union lc_str name; / library's path name /
644	uint32_t timestamp; / library's build time stamp /
645	uint32_t current_version; / library's current version number /
646	uint32_t compatibility_version; / library's compatibility vers number/
647	};
648
649	/*
650	* A dynamically linked shared library (filetype == MH_DYLIB in the mach header)
651	* contains a dylib_command (cmd == LC_ID_DYLIB) to identify the library.
652	* An object that uses a dynamically linked shared library also contains a
653	* dylib_command (cmd == LC_LOAD_DYLIB, LC_LOAD_WEAK_DYLIB, or
654	* LC_REEXPORT_DYLIB) for each library it uses.
655	*/
656	struct dylib_command {
657	uint32_t cmd; / LC_ID_DYLIB, LC_LOAD_{,WEAK_}DYLIB,*
658	LC_REEXPORT_DYLIB /*
659	uint32_t cmdsize; / includes pathname string /
660	struct dylib dylib; / the library identification /
661	};
662
663	/*
664	* A dynamically linked shared library may be a subframework of an umbrella
665	* framework. If so it will be linked with "-umbrella umbrella_name" where
666	* Where "umbrella_name" is the name of the umbrella framework. A subframework
667	* can only be linked against by its umbrella framework or other subframeworks
668	* that are part of the same umbrella framework. Otherwise the static link
669	* editor produces an error and states to link against the umbrella framework.
670	* The name of the umbrella framework for subframeworks is recorded in the
671	* following structure.
672	*/
673	struct sub_framework_command {
674	uint32_t cmd; / LC_SUB_FRAMEWORK /
675	uint32_t cmdsize; / includes umbrella string /
676	union lc_str umbrella; / the umbrella framework name /
677	};
678
679	/*
680	* For dynamically linked shared libraries that are subframework of an umbrella
681	* framework they can allow clients other than the umbrella framework or other
682	* subframeworks in the same umbrella framework. To do this the subframework
683	* is built with "-allowable_client client_name" and an LC_SUB_CLIENT load
684	* command is created for each -allowable_client flag. The client_name is
685	* usually a framework name. It can also be a name used for bundles clients
686	* where the bundle is built with "-client_name client_name".
687	*/
688	struct sub_client_command {
689	uint32_t cmd; / LC_SUB_CLIENT /
690	uint32_t cmdsize; / includes client string /
691	union lc_str client; / the client name /
692	};
693
694	/*
695	* A dynamically linked shared library may be a sub_umbrella of an umbrella
696	* framework. If so it will be linked with "-sub_umbrella umbrella_name" where
697	* Where "umbrella_name" is the name of the sub_umbrella framework. When
698	* staticly linking when -twolevel_namespace is in effect a twolevel namespace
699	* umbrella framework will only cause its subframeworks and those frameworks
700	* listed as sub_umbrella frameworks to be implicited linked in. Any other
701	* dependent dynamic libraries will not be linked it when -twolevel_namespace
702	* is in effect. The primary library recorded by the static linker when
703	* resolving a symbol in these libraries will be the umbrella framework.
704	* Zero or more sub_umbrella frameworks may be use by an umbrella framework.
705	* The name of a sub_umbrella framework is recorded in the following structure.
706	*/
707	struct sub_umbrella_command {
708	uint32_t cmd; / LC_SUB_UMBRELLA /
709	uint32_t cmdsize; / includes sub_umbrella string /
710	union lc_str sub_umbrella; / the sub_umbrella framework name /
711	};
712
713	/*
714	* A dynamically linked shared library may be a sub_library of another shared
715	* library. If so it will be linked with "-sub_library library_name" where
716	* Where "library_name" is the name of the sub_library shared library. When
717	* staticly linking when -twolevel_namespace is in effect a twolevel namespace
718	* shared library will only cause its subframeworks and those frameworks
719	* listed as sub_umbrella frameworks and libraries listed as sub_libraries to
720	* be implicited linked in. Any other dependent dynamic libraries will not be
721	* linked it when -twolevel_namespace is in effect. The primary library
722	* recorded by the static linker when resolving a symbol in these libraries
723	* will be the umbrella framework (or dynamic library). Zero or more sub_library
724	* shared libraries may be use by an umbrella framework or (or dynamic library).
725	* The name of a sub_library framework is recorded in the following structure.
726	* For example /usr/lib/libobjc_profile.A.dylib would be recorded as "libobjc".
727	*/
728	struct sub_library_command {
729	uint32_t cmd; / LC_SUB_LIBRARY /
730	uint32_t cmdsize; / includes sub_library string /
731	union lc_str sub_library; / the sub_library name /
732	};
733
734	/*
735	* A program (filetype == MH_EXECUTE) that is
736	* prebound to its dynamic libraries has one of these for each library that
737	* the static linker used in prebinding. It contains a bit vector for the
738	* modules in the library. The bits indicate which modules are bound (1) and
739	* which are not (0) from the library. The bit for module 0 is the low bit
740	* of the first byte. So the bit for the Nth module is:
741	* (linked_modules[N/8] >> N%8) & 1
742	*/
743	struct prebound_dylib_command {
744	uint32_t cmd; / LC_PREBOUND_DYLIB /
745	uint32_t cmdsize; / includes strings /
746	union lc_str name; / library's path name /
747	uint32_t nmodules; / number of modules in library /
748	union lc_str linked_modules; / bit vector of linked modules /
749	};
750
751	/*
752	* A program that uses a dynamic linker contains a dylinker_command to identify
753	* the name of the dynamic linker (LC_LOAD_DYLINKER). And a dynamic linker
754	* contains a dylinker_command to identify the dynamic linker (LC_ID_DYLINKER).
755	* A file can have at most one of these.
756	* This struct is also used for the LC_DYLD_ENVIRONMENT load command and
757	* contains string for dyld to treat like environment variable.
758	*/
759	struct dylinker_command {
760	uint32_t cmd; / LC_ID_DYLINKER, LC_LOAD_DYLINKER or*
761	LC_DYLD_ENVIRONMENT /*
762	uint32_t cmdsize; / includes pathname string /
763	union lc_str name; / dynamic linker's path name /
764	};
765
766	/*
767	* Thread commands contain machine-specific data structures suitable for
768	* use in the thread state primitives. The machine specific data structures
769	* follow the struct thread_command as follows.
770	* Each flavor of machine specific data structure is preceded by an unsigned
771	* long constant for the flavor of that data structure, an uint32_t
772	* that is the count of longs of the size of the state data structure and then
773	* the state data structure follows. This triple may be repeated for many
774	* flavors. The constants for the flavors, counts and state data structure
775	* definitions are expected to be in the header file <machine/thread_status.h>.
776	* These machine specific data structures sizes must be multiples of
777	* 4 bytes The cmdsize reflects the total size of the thread_command
778	* and all of the sizes of the constants for the flavors, counts and state
779	* data structures.
780	*
781	* For executable objects that are unix processes there will be one
782	* thread_command (cmd == LC_UNIXTHREAD) created for it by the link-editor.
783	* This is the same as a LC_THREAD, except that a stack is automatically
784	* created (based on the shell's limit for the stack size). Command arguments
785	* and environment variables are copied onto that stack.
786	*/
787	struct thread_command {
788	uint32_t cmd; / LC_THREAD or LC_UNIXTHREAD /
789	uint32_t cmdsize; / total size of this command /
790	/ uint32_t flavor flavor of thread state /
791	/ uint32_t count count of longs in thread state /
792	/ struct XXX_thread_state state thread state for this flavor /
793	/ ... /
794	};
795
796	/*
797	* The routines command contains the address of the dynamic shared library
798	* initialization routine and an index into the module table for the module
799	* that defines the routine. Before any modules are used from the library the
800	* dynamic linker fully binds the module that defines the initialization routine
801	* and then calls it. This gets called before any module initialization
802	* routines (used for C++ static constructors) in the library.
803	*/
804	struct routines_command { / for 32-bit architectures /
805	uint32_t cmd; / LC_ROUTINES /
806	uint32_t cmdsize; / total size of this command /
807	uint32_t init_address; / address of initialization routine /
808	uint32_t init_module; / index into the module table that /
809	/ the init routine is defined in /
810	uint32_t reserved1;
811	uint32_t reserved2;
812	uint32_t reserved3;
813	uint32_t reserved4;
814	uint32_t reserved5;
815	uint32_t reserved6;
816	};
817
818	/*
819	* The 64-bit routines command. Same use as above.
820	*/
821	struct routines_command_64 { / for 64-bit architectures /
822	uint32_t cmd; / LC_ROUTINES_64 /
823	uint32_t cmdsize; / total size of this command /
824	uint64_t init_address; / address of initialization routine /
825	uint64_t init_module; / index into the module table that /
826	/ the init routine is defined in /
827	uint64_t reserved1;
828	uint64_t reserved2;
829	uint64_t reserved3;
830	uint64_t reserved4;
831	uint64_t reserved5;
832	uint64_t reserved6;
833	};
834
835	/*
836	* The symtab_command contains the offsets and sizes of the link-edit 4.3BSD
837	* "stab" style symbol table information as described in the header files
838	* <nlist.h> and <stab.h>.
839	*/
840	struct symtab_command {
841	uint32_t cmd; / LC_SYMTAB /
842	uint32_t cmdsize; / sizeof(struct symtab_command) /
843	uint32_t symoff; / symbol table offset /
844	uint32_t nsyms; / number of symbol table entries /
845	uint32_t stroff; / string table offset /
846	uint32_t strsize; / string table size in bytes /
847	};
848
849	/*
850	* This is the second set of the symbolic information which is used to support
851	* the data structures for the dynamically link editor.
852	*
853	* The original set of symbolic information in the symtab_command which contains
854	* the symbol and string tables must also be present when this load command is
855	* present. When this load command is present the symbol table is organized
856	* into three groups of symbols:
857	* local symbols (static and debugging symbols) - grouped by module
858	* defined external symbols - grouped by module (sorted by name if not lib)
859	* undefined external symbols (sorted by name if MH_BINDATLOAD is not set,
860	* and in order the were seen by the static
861	* linker if MH_BINDATLOAD is set)
862	* In this load command there are offsets and counts to each of the three groups
863	* of symbols.
864	*
865	* This load command contains a the offsets and sizes of the following new
866	* symbolic information tables:
867	* table of contents
868	* module table
869	* reference symbol table
870	* indirect symbol table
871	* The first three tables above (the table of contents, module table and
872	* reference symbol table) are only present if the file is a dynamically linked
873	* shared library. For executable and object modules, which are files
874	* containing only one module, the information that would be in these three
875	* tables is determined as follows:
876	* table of contents - the defined external symbols are sorted by name
877	* module table - the file contains only one module so everything in the
878	* file is part of the module.
879	* reference symbol table - is the defined and undefined external symbols
880	*
881	* For dynamically linked shared library files this load command also contains
882	* offsets and sizes to the pool of relocation entries for all sections
883	* separated into two groups:
884	* external relocation entries
885	* local relocation entries
886	* For executable and object modules the relocation entries continue to hang
887	* off the section structures.
888	*/
889	struct dysymtab_command {
890	uint32_t cmd; / LC_DYSYMTAB /
891	uint32_t cmdsize; / sizeof(struct dysymtab_command) /
892
893	/*
894	* The symbols indicated by symoff and nsyms of the LC_SYMTAB load command
895	* are grouped into the following three groups:
896	* local symbols (further grouped by the module they are from)
897	* defined external symbols (further grouped by the module they are from)
898	* undefined symbols
899	*
900	* The local symbols are used only for debugging. The dynamic binding
901	* process may have to use them to indicate to the debugger the local
902	* symbols for a module that is being bound.
903	*
904	* The last two groups are used by the dynamic binding process to do the
905	* binding (indirectly through the module table and the reference symbol
906	* table when this is a dynamically linked shared library file).
907	*/
908	uint32_t ilocalsym; / index to local symbols /
909	uint32_t nlocalsym; / number of local symbols /
910
911	uint32_t iextdefsym;/ index to externally defined symbols /
912	uint32_t nextdefsym;/ number of externally defined symbols /
913
914	uint32_t iundefsym; / index to undefined symbols /
915	uint32_t nundefsym; / number of undefined symbols /
916
917	/*
918	* For the for the dynamic binding process to find which module a symbol
919	* is defined in the table of contents is used (analogous to the ranlib
920	* structure in an archive) which maps defined external symbols to modules
921	* they are defined in. This exists only in a dynamically linked shared
922	* library file. For executable and object modules the defined external
923	* symbols are sorted by name and is use as the table of contents.
924	*/
925	uint32_t tocoff; / file offset to table of contents /
926	uint32_t ntoc; / number of entries in table of contents /
927
928	/*
929	* To support dynamic binding of "modules" (whole object files) the symbol
930	* table must reflect the modules that the file was created from. This is
931	* done by having a module table that has indexes and counts into the merged
932	* tables for each module. The module structure that these two entries
933	* refer to is described below. This exists only in a dynamically linked
934	* shared library file. For executable and object modules the file only
935	* contains one module so everything in the file belongs to the module.
936	*/
937	uint32_t modtaboff; / file offset to module table /
938	uint32_t nmodtab; / number of module table entries /
939
940	/*
941	* To support dynamic module binding the module structure for each module
942	* indicates the external references (defined and undefined) each module
943	* makes. For each module there is an offset and a count into the
944	* reference symbol table for the symbols that the module references.
945	* This exists only in a dynamically linked shared library file. For
946	* executable and object modules the defined external symbols and the
947	* undefined external symbols indicates the external references.
948	*/
949	uint32_t extrefsymoff; / offset to referenced symbol table /
950	uint32_t nextrefsyms; / number of referenced symbol table entries /
951
952	/*
953	* The sections that contain "symbol pointers" and "routine stubs" have
954	* indexes and (implied counts based on the size of the section and fixed
955	* size of the entry) into the "indirect symbol" table for each pointer
956	* and stub. For every section of these two types the index into the
957	* indirect symbol table is stored in the section header in the field
958	* reserved1. An indirect symbol table entry is simply a 32bit index into
959	* the symbol table to the symbol that the pointer or stub is referring to.
960	* The indirect symbol table is ordered to match the entries in the section.
961	*/
962	uint32_t indirectsymoff; / file offset to the indirect symbol table /
963	uint32_t nindirectsyms; / number of indirect symbol table entries /
964
965	/*
966	* To support relocating an individual module in a library file quickly the
967	* external relocation entries for each module in the library need to be
968	* accessed efficiently. Since the relocation entries can't be accessed
969	* through the section headers for a library file they are separated into
970	* groups of local and external entries further grouped by module. In this
971	* case the presents of this load command who's extreloff, nextrel,
972	* locreloff and nlocrel fields are non-zero indicates that the relocation
973	* entries of non-merged sections are not referenced through the section
974	* structures (and the reloff and nreloc fields in the section headers are
975	* set to zero).
976	*
977	* Since the relocation entries are not accessed through the section headers
978	* this requires the r_address field to be something other than a section
979	* offset to identify the item to be relocated. In this case r_address is
980	* set to the offset from the vmaddr of the first LC_SEGMENT command.
981	* For MH_SPLIT_SEGS images r_address is set to the the offset from the
982	* vmaddr of the first read-write LC_SEGMENT command.
983	*
984	* The relocation entries are grouped by module and the module table
985	* entries have indexes and counts into them for the group of external
986	* relocation entries for that the module.
987	*
988	* For sections that are merged across modules there must not be any
989	* remaining external relocation entries for them (for merged sections
990	* remaining relocation entries must be local).
991	*/
992	uint32_t extreloff; / offset to external relocation entries /
993	uint32_t nextrel; / number of external relocation entries /
994
995	/*
996	* All the local relocation entries are grouped together (they are not
997	* grouped by their module since they are only used if the object is moved
998	* from it staticly link edited address).
999	*/
1000	uint32_t locreloff; / offset to local relocation entries /
1001	uint32_t nlocrel; / number of local relocation entries /
1002
1003	};
1004
1005	/*
1006	* An indirect symbol table entry is simply a 32bit index into the symbol table
1007	* to the symbol that the pointer or stub is refering to. Unless it is for a
1008	* non-lazy symbol pointer section for a defined symbol which strip(1) as
1009	* removed. In which case it has the value INDIRECT_SYMBOL_LOCAL. If the
1010	* symbol was also absolute INDIRECT_SYMBOL_ABS is or'ed with that.
1011	*/
1012	#define INDIRECT_SYMBOL_LOCAL 0x80000000
1013	#define INDIRECT_SYMBOL_ABS 0x40000000
1014
1015
1016	/ a table of contents entry /
1017	struct dylib_table_of_contents {
1018	uint32_t symbol_index; / the defined external symbol*
1019	(index into the symbol table) /*
1020	uint32_t module_index; / index into the module table this symbol*
1021	is defined in /*
1022	};
1023
1024	/ a module table entry /
1025	struct dylib_module {
1026	uint32_t module_name; / the module name (index into string table) /
1027
1028	uint32_t iextdefsym; / index into externally defined symbols /
1029	uint32_t nextdefsym; / number of externally defined symbols /
1030	uint32_t irefsym; / index into reference symbol table /
1031	uint32_t nrefsym; / number of reference symbol table entries /
1032	uint32_t ilocalsym; / index into symbols for local symbols /
1033	uint32_t nlocalsym; / number of local symbols /
1034
1035	uint32_t iextrel; / index into external relocation entries /
1036	uint32_t nextrel; / number of external relocation entries /
1037
1038	uint32_t iinit_iterm; / low 16 bits are the index into the init*
1039	section, high 16 bits are the index into
1040	the term section /*
1041	uint32_t ninit_nterm; / low 16 bits are the number of init section*
1042	entries, high 16 bits are the number of
1043	term section entries /*
1044
1045	uint32_t / for this module address of the start of /
1046	objc_module_info_addr; / the (__OBJC,__module_info) section /
1047	uint32_t / for this module size of /
1048	objc_module_info_size; / the (__OBJC,__module_info) section /
1049	};
1050
1051	/ a 64-bit module table entry /
1052	struct dylib_module_64 {
1053	uint32_t module_name; / the module name (index into string table) /
1054
1055	uint32_t iextdefsym; / index into externally defined symbols /
1056	uint32_t nextdefsym; / number of externally defined symbols /
1057	uint32_t irefsym; / index into reference symbol table /
1058	uint32_t nrefsym; / number of reference symbol table entries /
1059	uint32_t ilocalsym; / index into symbols for local symbols /
1060	uint32_t nlocalsym; / number of local symbols /
1061
1062	uint32_t iextrel; / index into external relocation entries /
1063	uint32_t nextrel; / number of external relocation entries /
1064
1065	uint32_t iinit_iterm; / low 16 bits are the index into the init*
1066	section, high 16 bits are the index into
1067	the term section /*
1068	uint32_t ninit_nterm; / low 16 bits are the number of init section*
1069	entries, high 16 bits are the number of
1070	term section entries /*
1071
1072	uint32_t / for this module size of /
1073	objc_module_info_size; / the (__OBJC,__module_info) section /
1074	uint64_t / for this module address of the start of /
1075	objc_module_info_addr; / the (__OBJC,__module_info) section /
1076	};
1077
1078	/*
1079	* The entries in the reference symbol table are used when loading the module
1080	* (both by the static and dynamic link editors) and if the module is unloaded
1081	* or replaced. Therefore all external symbols (defined and undefined) are
1082	* listed in the module's reference table. The flags describe the type of
1083	* reference that is being made. The constants for the flags are defined in
1084	* <mach-o/nlist.h> as they are also used for symbol table entries.
1085	*/
1086	struct dylib_reference {
1087	uint32_t isym:`24`, / index into the symbol table /
1088	flags:`8`; / flags to indicate the type of reference /
1089	};
1090
1091	/*
1092	* The twolevel_hints_command contains the offset and number of hints in the
1093	* two-level namespace lookup hints table.
1094	*/
1095	struct twolevel_hints_command {
1096	uint32_t cmd; / LC_TWOLEVEL_HINTS /
1097	uint32_t cmdsize; / sizeof(struct twolevel_hints_command) /
1098	uint32_t offset; / offset to the hint table /
1099	uint32_t nhints; / number of hints in the hint table /
1100	};
1101
1102	/*
1103	* The entries in the two-level namespace lookup hints table are twolevel_hint
1104	* structs. These provide hints to the dynamic link editor where to start
1105	* looking for an undefined symbol in a two-level namespace image. The
1106	* isub_image field is an index into the sub-images (sub-frameworks and
1107	* sub-umbrellas list) that made up the two-level image that the undefined
1108	* symbol was found in when it was built by the static link editor. If
1109	* isub-image is 0 the the symbol is expected to be defined in library and not
1110	* in the sub-images. If isub-image is non-zero it is an index into the array
1111	* of sub-images for the umbrella with the first index in the sub-images being
1112	* 1. The array of sub-images is the ordered list of sub-images of the umbrella
1113	* that would be searched for a symbol that has the umbrella recorded as its
1114	* primary library. The table of contents index is an index into the
1115	* library's table of contents. This is used as the starting point of the
1116	* binary search or a directed linear search.
1117	*/
1118	struct twolevel_hint {
1119	uint32_t
1120	isub_image:`8`, / index into the sub images /
1121	itoc:`24`; / index into the table of contents /
1122	};
1123
1124	/*
1125	* The prebind_cksum_command contains the value of the original check sum for
1126	* prebound files or zero. When a prebound file is first created or modified
1127	* for other than updating its prebinding information the value of the check sum
1128	* is set to zero. When the file has it prebinding re-done and if the value of
1129	* the check sum is zero the original check sum is calculated and stored in
1130	* cksum field of this load command in the output file. If when the prebinding
1131	* is re-done and the cksum field is non-zero it is left unchanged from the
1132	* input file.
1133	*/
1134	struct prebind_cksum_command {
1135	uint32_t cmd; / LC_PREBIND_CKSUM /
1136	uint32_t cmdsize; / sizeof(struct prebind_cksum_command) /
1137	uint32_t cksum; / the check sum or zero /
1138	};
1139
1140	/*
1141	* The uuid load command contains a single 128-bit unique random number that
1142	* identifies an object produced by the static link editor.
1143	*/
1144	struct uuid_command {
1145	uint32_t cmd; / LC_UUID /
1146	uint32_t cmdsize; / sizeof(struct uuid_command) /
1147	uint8_t uuid[`16`]; / the 128-bit uuid /
1148	};
1149
1150	/*
1151	* The rpath_command contains a path which at runtime should be added to
1152	* the current run path used to find @rpath prefixed dylibs.
1153	*/
1154	struct rpath_command {
1155	uint32_t cmd; / LC_RPATH /
1156	uint32_t cmdsize; / includes string /
1157	union lc_str path; / path to add to run path /
1158	};
1159
1160	/*
1161	* The linkedit_data_command contains the offsets and sizes of a blob
1162	* of data in the __LINKEDIT segment.
1163	*/
1164	struct linkedit_data_command {
1165	uint32_t cmd; / LC_CODE_SIGNATURE, LC_SEGMENT_SPLIT_INFO,*
1166	LC_FUNCTION_STARTS, LC_DATA_IN_CODE,
1167	LC_DYLIB_CODE_SIGN_DRS or
1168	LC_LINKER_OPTIMIZATION_HINT. /*
1169	uint32_t cmdsize; / sizeof(struct linkedit_data_command) /
1170	uint32_t dataoff; / file offset of data in __LINKEDIT segment /
1171	uint32_t datasize; / file size of data in __LINKEDIT segment /
1172	};
1173
1174	/*
1175	* The encryption_info_command contains the file offset and size of an
1176	* of an encrypted segment.
1177	*/
1178	struct encryption_info_command {
1179	uint32_t cmd; / LC_ENCRYPTION_INFO /
1180	uint32_t cmdsize; / sizeof(struct encryption_info_command) /
1181	uint32_t cryptoff; / file offset of encrypted range /
1182	uint32_t cryptsize; / file size of encrypted range /
1183	uint32_t cryptid; / which enryption system,*
1184	0 means not-encrypted yet /*
1185	};
1186
1187	/*
1188	* The encryption_info_command_64 contains the file offset and size of an
1189	* of an encrypted segment (for use in x86_64 targets).
1190	*/
1191	struct encryption_info_command_64 {
1192	uint32_t cmd; / LC_ENCRYPTION_INFO_64 /
1193	uint32_t cmdsize; / sizeof(struct encryption_info_command_64) /
1194	uint32_t cryptoff; / file offset of encrypted range /
1195	uint32_t cryptsize; / file size of encrypted range /
1196	uint32_t cryptid; / which enryption system,*
1197	0 means not-encrypted yet /*
1198	uint32_t pad; / padding to make this struct's size a multiple*
1199	of 8 bytes /*
1200	};
1201
1202	/*
1203	* The version_min_command contains the min OS version on which this
1204	* binary was built to run.
1205	*/
1206	struct version_min_command {
1207	uint32_t cmd; / LC_VERSION_MIN_MACOSX or*
1208	LC_VERSION_MIN_IPHONEOS or
1209	LC_VERSION_MIN_WATCHOS or
1210	LC_VERSION_MIN_TVOS /*
1211	uint32_t cmdsize; / sizeof(struct min_version_command) /
1212	uint32_t version; / X.Y.Z is encoded in nibbles xxxx.yy.zz /
1213	uint32_t sdk; / X.Y.Z is encoded in nibbles xxxx.yy.zz /
1214	};
1215
1216	/*
1217	* The build_version_command contains the min OS version on which this
1218	* binary was built to run for its platform. The list of known platforms and
1219	* tool values following it.
1220	*/
1221	struct build_version_command {
1222	uint32_t cmd; / LC_BUILD_VERSION /
1223	uint32_t cmdsize; / sizeof(struct build_version_command) plus /
1224	/ ntools * sizeof(struct build_tool_version) /
1225	uint32_t platform; / platform /
1226	uint32_t minos; / X.Y.Z is encoded in nibbles xxxx.yy.zz /
1227	uint32_t sdk; / X.Y.Z is encoded in nibbles xxxx.yy.zz /
1228	uint32_t ntools; / number of tool entries following this /
1229	};
1230
1231	struct build_tool_version {
1232	uint32_t tool; / enum for the tool /
1233	uint32_t version; / version number of the tool /
1234	};
1235
1236	/ Known values for the platform field above. /
1237	#define PLATFORM_MACOS 1
1238	#define PLATFORM_IOS 2
1239	#define PLATFORM_TVOS 3
1240	#define PLATFORM_WATCHOS 4
1241
1242	/ Known values for the tool field above. /
1243	#define TOOL_CLANG 1
1244	#define TOOL_SWIFT 2
1245	#define TOOL_LD 3
1246
1247	/*
1248	* The dyld_info_command contains the file offsets and sizes of
1249	* the new compressed form of the information dyld needs to
1250	* load the image. This information is used by dyld on Mac OS X
1251	* 10.6 and later. All information pointed to by this command
1252	* is encoded using byte streams, so no endian swapping is needed
1253	* to interpret it.
1254	*/
1255	struct dyld_info_command {
1256	uint32_t cmd; / LC_DYLD_INFO or LC_DYLD_INFO_ONLY /
1257	uint32_t cmdsize; / sizeof(struct dyld_info_command) /
1258
1259	/*
1260	* Dyld rebases an image whenever dyld loads it at an address different
1261	* from its preferred address. The rebase information is a stream
1262	* of byte sized opcodes whose symbolic names start with REBASE_OPCODE_.
1263	* Conceptually the rebase information is a table of tuples:
1264	* <seg-index, seg-offset, type>
1265	* The opcodes are a compressed way to encode the table by only
1266	* encoding when a column changes. In addition simple patterns
1267	* like "every n'th offset for m times" can be encoded in a few
1268	* bytes.
1269	*/
1270	uint32_t rebase_off; / file offset to rebase info /
1271	uint32_t rebase_size; / size of rebase info /
1272
1273	/*
1274	* Dyld binds an image during the loading process, if the image
1275	* requires any pointers to be initialized to symbols in other images.
1276	* The bind information is a stream of byte sized
1277	* opcodes whose symbolic names start with BIND_OPCODE_.
1278	* Conceptually the bind information is a table of tuples:
1279	* <seg-index, seg-offset, type, symbol-library-ordinal, symbol-name, addend>
1280	* The opcodes are a compressed way to encode the table by only
1281	* encoding when a column changes. In addition simple patterns
1282	* like for runs of pointers initialzed to the same value can be
1283	* encoded in a few bytes.
1284	*/
1285	uint32_t bind_off; / file offset to binding info /
1286	uint32_t bind_size; / size of binding info /
1287
1288	/*
1289	* Some C++ programs require dyld to unique symbols so that all
1290	* images in the process use the same copy of some code/data.
1291	* This step is done after binding. The content of the weak_bind
1292	* info is an opcode stream like the bind_info. But it is sorted
1293	* alphabetically by symbol name. This enable dyld to walk
1294	* all images with weak binding information in order and look
1295	* for collisions. If there are no collisions, dyld does
1296	* no updating. That means that some fixups are also encoded
1297	* in the bind_info. For instance, all calls to "operator new"
1298	* are first bound to libstdc++.dylib using the information
1299	* in bind_info. Then if some image overrides operator new
1300	* that is detected when the weak_bind information is processed
1301	* and the call to operator new is then rebound.
1302	*/
1303	uint32_t weak_bind_off; / file offset to weak binding info /
1304	uint32_t weak_bind_size; / size of weak binding info /
1305
1306	/*
1307	* Some uses of external symbols do not need to be bound immediately.
1308	* Instead they can be lazily bound on first use. The lazy_bind
1309	* are contains a stream of BIND opcodes to bind all lazy symbols.
1310	* Normal use is that dyld ignores the lazy_bind section when
1311	* loading an image. Instead the static linker arranged for the
1312	* lazy pointer to initially point to a helper function which
1313	* pushes the offset into the lazy_bind area for the symbol
1314	* needing to be bound, then jumps to dyld which simply adds
1315	* the offset to lazy_bind_off to get the information on what
1316	* to bind.
1317	*/
1318	uint32_t lazy_bind_off; / file offset to lazy binding info /
1319	uint32_t lazy_bind_size; / size of lazy binding infs /
1320
1321	/*
1322	* The symbols exported by a dylib are encoded in a trie. This
1323	* is a compact representation that factors out common prefixes.
1324	* It also reduces LINKEDIT pages in RAM because it encodes all
1325	* information (name, address, flags) in one small, contiguous range.
1326	* The export area is a stream of nodes. The first node sequentially
1327	* is the start node for the trie.
1328	*
1329	* Nodes for a symbol start with a uleb128 that is the length of
1330	* the exported symbol information for the string so far.
1331	* If there is no exported symbol, the node starts with a zero byte.
1332	* If there is exported info, it follows the length.
1333	*
1334	* First is a uleb128 containing flags. Normally, it is followed by
1335	* a uleb128 encoded offset which is location of the content named
1336	* by the symbol from the mach_header for the image. If the flags
1337	* is EXPORT_SYMBOL_FLAGS_REEXPORT, then following the flags is
1338	* a uleb128 encoded library ordinal, then a zero terminated
1339	* UTF8 string. If the string is zero length, then the symbol
1340	* is re-export from the specified dylib with the same name.
1341	* If the flags is EXPORT_SYMBOL_FLAGS_STUB_AND_RESOLVER, then following
1342	* the flags is two uleb128s: the stub offset and the resolver offset.
1343	* The stub is used by non-lazy pointers. The resolver is used
1344	* by lazy pointers and must be called to get the actual address to use.
1345	*
1346	* After the optional exported symbol information is a byte of
1347	* how many edges (0-255) that this node has leaving it,
1348	* followed by each edge.
1349	* Each edge is a zero terminated UTF8 of the addition chars
1350	* in the symbol, followed by a uleb128 offset for the node that
1351	* edge points to.
1352	*
1353	*/
1354	uint32_t export_off; / file offset to lazy binding info /
1355	uint32_t export_size; / size of lazy binding infs /
1356	};
1357
1358	/*
1359	* The following are used to encode rebasing information
1360	*/
1361	#define REBASE_TYPE_POINTER 1
1362	#define REBASE_TYPE_TEXT_ABSOLUTE32 2
1363	#define REBASE_TYPE_TEXT_PCREL32 3
1364
1365	#define REBASE_OPCODE_MASK 0xF0
1366	#define REBASE_IMMEDIATE_MASK 0x0F
1367	#define REBASE_OPCODE_DONE 0x00
1368	#define REBASE_OPCODE_SET_TYPE_IMM 0x10
1369	#define REBASE_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB 0x20
1370	#define REBASE_OPCODE_ADD_ADDR_ULEB 0x30
1371	#define REBASE_OPCODE_ADD_ADDR_IMM_SCALED 0x40
1372	#define REBASE_OPCODE_DO_REBASE_IMM_TIMES 0x50
1373	#define REBASE_OPCODE_DO_REBASE_ULEB_TIMES 0x60
1374	#define REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB 0x70
1375	#define REBASE_OPCODE_DO_REBASE_ULEB_TIMES_SKIPPING_ULEB 0x80
1376
1377
1378	/*
1379	* The following are used to encode binding information
1380	*/
1381	#define BIND_TYPE_POINTER 1
1382	#define BIND_TYPE_TEXT_ABSOLUTE32 2
1383	#define BIND_TYPE_TEXT_PCREL32 3
1384
1385	#define BIND_SPECIAL_DYLIB_SELF 0
1386	#define BIND_SPECIAL_DYLIB_MAIN_EXECUTABLE -1
1387	#define BIND_SPECIAL_DYLIB_FLAT_LOOKUP -2
1388
1389	#define BIND_SYMBOL_FLAGS_WEAK_IMPORT 0x1
1390	#define BIND_SYMBOL_FLAGS_NON_WEAK_DEFINITION 0x8
1391
1392	#define BIND_OPCODE_MASK 0xF0
1393	#define BIND_IMMEDIATE_MASK 0x0F
1394	#define BIND_OPCODE_DONE 0x00
1395	#define BIND_OPCODE_SET_DYLIB_ORDINAL_IMM 0x10
1396	#define BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB 0x20
1397	#define BIND_OPCODE_SET_DYLIB_SPECIAL_IMM 0x30
1398	#define BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM 0x40
1399	#define BIND_OPCODE_SET_TYPE_IMM 0x50
1400	#define BIND_OPCODE_SET_ADDEND_SLEB 0x60
1401	#define BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB 0x70
1402	#define BIND_OPCODE_ADD_ADDR_ULEB 0x80
1403	#define BIND_OPCODE_DO_BIND 0x90
1404	#define BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB 0xA0
1405	#define BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED 0xB0
1406	#define BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB 0xC0
1407
1408
1409	/*
1410	* The following are used on the flags byte of a terminal node
1411	* in the export information.
1412	*/
1413	#define EXPORT_SYMBOL_FLAGS_KIND_MASK 0x03
1414	#define EXPORT_SYMBOL_FLAGS_KIND_REGULAR 0x00
1415	#define EXPORT_SYMBOL_FLAGS_KIND_THREAD_LOCAL 0x01
1416	#define EXPORT_SYMBOL_FLAGS_WEAK_DEFINITION 0x04
1417	#define EXPORT_SYMBOL_FLAGS_REEXPORT 0x08
1418	#define EXPORT_SYMBOL_FLAGS_STUB_AND_RESOLVER 0x10
1419
1420	/*
1421	* The linker_option_command contains linker options embedded in object files.
1422	*/
1423	struct linker_option_command {
1424	uint32_t cmd; / LC_LINKER_OPTION only used in MH_OBJECT filetypes /
1425	uint32_t cmdsize;
1426	uint32_t count; / number of strings /
1427	/ concatenation of zero terminated UTF8 strings.*
1428	Zero filled at end to align /*
1429	};
1430
1431	/*
1432	* The symseg_command contains the offset and size of the GNU style
1433	* symbol table information as described in the header file <symseg.h>.
1434	* The symbol roots of the symbol segments must also be aligned properly
1435	* in the file. So the requirement of keeping the offsets aligned to a
1436	* multiple of a 4 bytes translates to the length field of the symbol
1437	* roots also being a multiple of a long. Also the padding must again be
1438	* zeroed. (THIS IS OBSOLETE and no longer supported).
1439	*/
1440	struct symseg_command {
1441	uint32_t cmd; / LC_SYMSEG /
1442	uint32_t cmdsize; / sizeof(struct symseg_command) /
1443	uint32_t offset; / symbol segment offset /
1444	uint32_t size; / symbol segment size in bytes /
1445	};
1446
1447	/*
1448	* The ident_command contains a free format string table following the
1449	* ident_command structure. The strings are null terminated and the size of
1450	* the command is padded out with zero bytes to a multiple of 4 bytes/
1451	* (THIS IS OBSOLETE and no longer supported).
1452	*/
1453	struct ident_command {
1454	uint32_t cmd; / LC_IDENT /
1455	uint32_t cmdsize; / strings that follow this command /
1456	};
1457
1458	/*
1459	* The fvmfile_command contains a reference to a file to be loaded at the
1460	* specified virtual address. (Presently, this command is reserved for
1461	* internal use. The kernel ignores this command when loading a program into
1462	* memory).
1463	*/
1464	struct fvmfile_command {
1465	uint32_t cmd; / LC_FVMFILE /
1466	uint32_t cmdsize; / includes pathname string /
1467	union lc_str name; / files pathname /
1468	uint32_t header_addr; / files virtual address /
1469	};
1470
1471
1472	/*
1473	* The entry_point_command is a replacement for thread_command.
1474	* It is used for main executables to specify the location (file offset)
1475	* of main(). If -stack_size was used at link time, the stacksize
1476	* field will contain the stack size need for the main thread.
1477	*/
1478	struct entry_point_command {
1479	uint32_t cmd; / LC_MAIN only used in MH_EXECUTE filetypes /
1480	uint32_t cmdsize; / 24 /
1481	uint64_t entryoff; / file (__TEXT) offset of main() /
1482	uint64_t stacksize;/ if not zero, initial stack size /
1483	};
1484
1485
1486	/*
1487	* The source_version_command is an optional load command containing
1488	* the version of the sources used to build the binary.
1489	*/
1490	struct source_version_command {
1491	uint32_t cmd; / LC_SOURCE_VERSION /
1492	uint32_t cmdsize; / 16 /
1493	uint64_t version; / A.B.C.D.E packed as a24.b10.c10.d10.e10 /
1494	};
1495
1496
1497	/*
1498	* The LC_DATA_IN_CODE load commands uses a linkedit_data_command
1499	* to point to an array of data_in_code_entry entries. Each entry
1500	* describes a range of data in a code section.
1501	*/
1502	struct data_in_code_entry {
1503	uint32_t offset; / from mach_header to start of data range/
1504	uint16_t length; / number of bytes in data range /
1505	uint16_t kind; / a DICE_KIND_* value /
1506	};
1507	#define DICE_KIND_DATA 0x0001
1508	#define DICE_KIND_JUMP_TABLE8 0x0002
1509	#define DICE_KIND_JUMP_TABLE16 0x0003
1510	#define DICE_KIND_JUMP_TABLE32 0x0004
1511	#define DICE_KIND_ABS_JUMP_TABLE32 0x0005
1512
1513
1514
1515	/*
1516	* Sections of type S_THREAD_LOCAL_VARIABLES contain an array
1517	* of tlv_descriptor structures.
1518	*/
1519	struct tlv_descriptor
1520	{
1521	void* (thunk)(struct* tlv_descriptor*);
1522	unsigned long key;
1523	unsigned long offset;
1524	};
1525
1526	/*
1527	* LC_NOTE commands describe a region of arbitrary data included in a Mach-O
1528	* file. Its initial use is to record extra data in MH_CORE files.
1529	*/
1530	struct note_command {
1531	uint32_t cmd; / LC_NOTE /
1532	uint32_t cmdsize; / sizeof(struct note_command) /
1533	char data_owner[`16`]; / owner name for this LC_NOTE /
1534	uint64_t offset; / file offset of this data /
1535	uint64_t size; / length of data region /
1536	};
1537
1538	#endif /* _MACHO_LOADER_H_ */
1539

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