arm64_32 uses 32-bit GOT loads, so we should accept those
instructions in `ARM64Common::relaxGotLoad()` too.
Reviewed By: #lld-macho, gkm
Differential Revision: https://reviews.llvm.org/D100229
From what I can tell, it's pretty similar to arm64. The two main differences
are:
1. No 64-bit relocations
2. Stub code writes to 32-bit registers instead of 64-bit
Plus of course the various on-disk structures like `segment_command` are using
the 32-bit instead of the 64-bit variants.
Reviewed By: #lld-macho, gkm
Differential Revision: https://reviews.llvm.org/D99822
It's likely redundant, per discussion with @gkm. The BYTE8
attribute covers the bit width requirement already.
Reviewed By: #lld-macho, gkm
Differential Revision: https://reviews.llvm.org/D100133
The main challenge was handling the different on-disk structures (e.g.
`mach_header` vs `mach_header_64`). I tried to strike a balance between
sprinkling `target->wordSize == 8` checks everywhere (branchy = slow, and ugly)
and templatizing everything (causes code bloat, also ugly). I think I struck a
decent balance by judicious use of type erasure.
Note that LLD-ELF has a similar architecture, though it seems to use more templating.
Linking chromium_framework takes about the same time before and after this
change:
N Min Max Median Avg Stddev
x 20 4.52 4.67 4.595 4.5945 0.044423204
+ 20 4.5 4.71 4.575 4.582 0.056344803
No difference proven at 95.0% confidence
Reviewed By: #lld-macho, oontvoo
Differential Revision: https://reviews.llvm.org/D99633
Within `lld/macho/`, only `InputFiles.cpp` and `Symbols.h` require the `macho::` namespace qualifier to disambiguate references to `class Symbol`.
Add braces to outer `for` of a 5-level single-line `if`/`for` nest.
Differential Revision: https://reviews.llvm.org/D99555
This diff required fixing `getEmbeddedAddend` to apply sign
extension to 32-bit values. We were previously passing around wrong
64-bit addend values that became "right" after being truncated back to
32-bit.
I've also made `getEmbeddedAddend` return a signed int, which is similar
to what LLD-ELF does for its `getImplicitAddend`.
`reportRangeError`, `checkUInt`, and `checkInt` are counterparts of similar
functions in LLD-ELF.
Reviewed By: #lld-macho, thakis
Differential Revision: https://reviews.llvm.org/D98387
SUBTRACTOR relocations are always paired with UNSIGNED
relocations to indicate a pair of symbols whose address difference we
want. Functionally they are like a single relocation: only one pointer
gets written / relocated. Previously, we would handle these pairs by
skipping over the SUBTRACTOR relocation and writing the pointer when
handling the UNSIGNED reloc. This diff reverses things, so we write
while handling SUBTRACTORs and skip over the UNSIGNED relocs instead.
Being able to distinguish between SUBTRACTOR and UNSIGNED relocs in the
write phase (i.e. inside `relocateOne`) is useful for the upcoming range
check diff: we want to check that SUBTRACTOR relocs write signed values,
but UNSIGNED relocs (naturally) write unsigned values.
Reviewed By: #lld-macho, thakis
Differential Revision: https://reviews.llvm.org/D98386
The previous implementation miscalculated the addend, resulting
in an underflow. This meant that every SIGNED_N section relocation would
be associated with the last subsection (since the addend would now be a
huge number). We were "lucky" that this mistake was typically cancelled
out -- 64-to-32-bit-truncation meant that the final value was correct,
as long as subsections were not rearranged.
Reviewed By: #lld-macho, thakis
Differential Revision: https://reviews.llvm.org/D98385
With this, llvm-tblgen no longer tries and fails to allocate 7953 petabyte
when it runs during the build. Instead, `check-llvm` with lld/mac as host
linker now completes without any failures on an m1 mac.
This vector op handling code matches what happens in:
- ld64's OutputFile::applyFixUps() in OutputFile.cpp for kindStoreARM64PageOff12
- lld.ld64.darwinold's offset12KindFromInstruction() in
lld/lib/ReaderWriter/MachO/ArchHandler_arm64.cpp for offset12scale16
- RuntimeDyld's decodeAddend() in
llvm/lib/ExecutionEngine/RuntimeDyld/Targets/RuntimeDyldMachOAArch64.h for
ARM64_RELOC_PAGEOFF12
Fixes PR49444.
Differential Revision: https://reviews.llvm.org/D98053
On arm64, UNSIGNED relocs are the only ones that use embedded addends
instead of the ADDEND relocation.
Also ensure that the addend works when UNSIGNED is part of a SUBTRACTOR
pair.
Reviewed By: #lld-macho, alexshap
Differential Revision: https://reviews.llvm.org/D97105
Also add a few asserts to verify that we are indeed handling an
UNSIGNED relocation as the minued. I haven't made it an actual
user-facing error since I don't think llvm-mc is capable of generating
SUBTRACTOR relocations without an associated UNSIGNED.
Reviewed By: #lld-macho, smeenai
Differential Revision: https://reviews.llvm.org/D97103
`llvm-mc` doesn't generate any relocations for subtractions
between local symbols -- they must be global -- so the previous test
wasn't actually testing any relocation logic. I've fixed that and
extended the test to cover r_length=3 relocations as well as both x86_64
and arm64.
Reviewed By: #lld-macho, smeenai
Differential Revision: https://reviews.llvm.org/D97057
I've adjusted the RelocAttrBits to better fit the semantics of
the relocations. In particular:
1. *_UNSIGNED relocations are no longer marked with the `TLV` bit, even
though they can occur within TLV sections. Instead the `TLV` bit is
reserved for relocations that can reference thread-local symbols, and
*_UNSIGNED relocations have their own `UNSIGNED` bit. The previous
implementation caused TLV and regular UNSIGNED semantics to be
conflated, resulting in rebase opcodes being incorrectly emitted for TLV
relocations.
2. I've added a new `POINTER` bit to denote non-relaxable GOT
relocations. This distinction isn't important on x86 -- the GOT
relocations there are either relaxable or non-relaxable loads -- but
arm64 has `GOT_LOAD_PAGE21` which loads the page that the referent
symbol is in (regardless of whether the symbol ends up in the GOT). This
relocation must reference a GOT symbol (so must have the `GOT` bit set)
but isn't itself relaxable (so must not have the `LOAD` bit). The
`POINTER` bit is used for relocations that *must* reference a GOT
slot.
3. A similar situation occurs for TLV relocations.
4. ld64 supports both a pcrel and an absolute version of
ARM64_RELOC_POINTER_TO_GOT. But the semantics of the absolute version
are pretty weird -- it results in the value of the GOT slot being
written, rather than the address. (That means a reference to a
dynamically-bound slot will result in zeroes being written.) The
programs I've tried linking don't use this form of the relocation, so
I've dropped our partial support for it by removing the relevant
RelocAttrBits.
Reviewed By: alexshap
Differential Revision: https://reviews.llvm.org/D97031
This is an initial base commit for ARM64 target arch support. I don't represent that it complete or bug-free, but wish to put it out for review now that some basic things like branch target & load/store address relocs are working.
I can add more tests to this base commit, or add them in follow-up commits.
It is not entirely clear whether I use the "ARM64" (Apple) or "AArch64" (non-Apple) naming convention. Guidance is appreciated.
Differential Revision: https://reviews.llvm.org/D88629
Add per-reloc-type attribute bits and migrate code from per-target file into target independent code, driven by reloc attributes.
Many cleanups
Differential Revision: https://reviews.llvm.org/D95121
This is a refactor to pave the way for supporting paired-ADDEND for ARM64. The only paired reloc type for X86_64 is SUBTRACTOR. In a later diff, I will add SUBTRACTOR for both X86_64 and ARM64.
* s/`getImplicitAddend`/`getAddend`/ because it handles all forms of addend: implicit, explicit, paired.
* add predicate `bool isPairedReloc()`
* check range of `relInfo.r_symbolnum` is internal, unrelated to user-input, so use `assert()`, not `error()`
* minor cleanups & rearrangements in `InputFile::parseRelocations()`
Differential Revision: https://reviews.llvm.org/D90614
Their addresses are already encoded as section-relative offsets, so
there's no need to rebase them at runtime. {D85080} has some context
on the weirdness of TLV sections.
Fixes llvm.org/PR48491.
Reviewed By: #lld-macho, thakis
Differential Revision: https://reviews.llvm.org/D93257
Speeds up linking Chromium's base_unittests almost 10%. According to ministat:
N Min Max Median Avg Stddev
x 5 0.72193289 0.73073196 0.72560811 0.72565799 0.0032265649
+ 5 0.64069581 0.67173195 0.65876389 0.65796089 0.011349451
Difference at 95.0% confidence
-0.0676971 +/- 0.0121682
-9.32906% +/- 1.67685%
(Student's t, pooled s = 0.00834328)
Differential Revision: https://reviews.llvm.org/D92734
Apparently this is used in real programs. I've handled this by reusing
the logic we already have for branch (function call) relocations.
Reviewed By: #lld-macho, smeenai
Differential Revision: https://reviews.llvm.org/D87852
* Implement rebase opcodes. Rebase opcodes tell dyld where absolute
addresses have been encoded in the binary. If the binary is not loaded
at its preferred address, dyld has to rebase these addresses by adding
an offset to them.
* Support `-pie` and use it to test rebase opcodes.
This is necessary for absolute address references in dylibs, bundles etc
to work.
Reviewed By: #lld-macho, gkm
Differential Revision: https://reviews.llvm.org/D87199
We can have GOT_LOAD relocations that reference `__dso_handle`.
However, our binding opcode encoder doesn't support binding to the DSOHandle
symbol. Instead of adding support for that, I decided it would be cleaner to
implement GOT_LOAD relaxation since `__dso_handle`'s location is always
statically known.
Reviewed By: #lld-macho, smeenai
Differential Revision: https://reviews.llvm.org/D86641
Since there is no "weak lazy" lookup, function calls to weak symbols are
always non-lazily bound. We emit both regular non-lazy bindings as well
as weak bindings, in order that the weak bindings may overwrite the
non-lazy bindings if an appropriate symbol is found at runtime. However,
the bound addresses will still be written (non-lazily) into the
LazyPointerSection.
Reviewed By: #lld-macho, smeenai
Differential Revision: https://reviews.llvm.org/D86573
Previously, we were only emitting regular bindings to weak
dynamic symbols; this diff adds support for the weak bindings too, which
can overwrite the regular bindings at runtime. We also treat weak
defined global symbols similarly -- since they can also be interposed at
runtime, they need to be treated as potentially dynamic symbols.
Note that weak bindings differ from regular bindings in that they do not
specify the dylib to do the lookup in (i.e. weak symbol lookup happens
in a flat namespace.)
Differential Revision: https://reviews.llvm.org/D86572
Previously, the BindingEntry struct could only store bindings to offsets
within InputSections. Since the GOTSection and TLVPointerSections are
OutputSections, I handled those in a separate code path. However, this
makes it awkward to support weak bindings properly without code
duplication. This diff allows BindingEntries to point directly to
OutputSections, simplifying the upcoming weak binding implementation.
Along the way, I also converted a bunch of functions taking references
to symbols to take pointers instead. Given how much casting we do for
Symbol (especially in the upcoming weak binding diffs), it's cleaner
this way.
Differential Revision: https://reviews.llvm.org/D86571
References to symbols in dylibs work very similarly regardless of
whether the symbol is a TLV. The main difference is that we have a
separate `__thread_ptrs` section that acts as the GOT for these
thread-locals.
We can identify thread-locals in dylibs by a flag in their export trie
entries, and we cross-check it with the relocations that refer to them
to ensure that we are not using a GOT relocation to reference a
thread-local (or vice versa).
Reviewed By: #lld-macho, smeenai
Differential Revision: https://reviews.llvm.org/D85081
Note: What ELF refers to as "TLS", Mach-O seems to refer to as "TLV", i.e.
thread-local variables.
This diff implements support for TLV relocations that reference defined
symbols. On x86_64, TLV relocations are always used with movq opcodes, so for
defined TLVs, we don't need to create a synthetic section to store the
addresses of the symbols -- we can just convert the `movq` to a `leaq`.
One notable quirk of Mach-O's TLVs is that absolute-address relocations
inside TLV-defining sections behave differently -- their addresses are
no longer absolute, but relative to the start of the target section.
(AFAICT, RIP-relative relocations are not allowed in these sections.)
Reviewed By: #lld-macho, compnerd, smeenai
Differential Revision: https://reviews.llvm.org/D85080
This diff adds support for weak definitions, though it doesn't handle weak
symbols in dylibs quite correctly -- we need to emit binding opcodes for them
in the weak binding section rather than the lazy binding section.
What *is* covered in this diff:
1. Reading the weak flag from symbol table / export trie, and writing it to the
export trie
2. Refining the symbol table's rules for choosing one symbol definition over
another. Wrote a few dozen test cases to make sure we were matching ld64's
behavior.
We can now link basic C++ programs.
Reviewed By: #lld-macho, compnerd
Differential Revision: https://reviews.llvm.org/D83532
Previously, we only supported binding dysyms to the GOT. This
diff adds support for binding them to any arbitrary section. C++
programs appear to use this, I believe for vtables and type_info.
This diff also makes our bind opcode encoding a bit smarter -- we now
encode just the differences between bindings, which will make things
more compact.
I was initially concerned about the performance overhead of iterating
over these relocations, but it turns out that the number of such
relocations is small. A quick analysis of my llvm-project build
directory showed that < 1.3% out of ~7M relocations are RELOC_UNSIGNED
bindings to symbols (including both dynamic and static symbols).
Reviewed By: #lld-macho, smeenai
Differential Revision: https://reviews.llvm.org/D83103
Summary:
Turns out this case is actually really common -- it happens whenever there's
a reference to an `extern` variable that ends up statically linked.
Depends on D80856.
Reviewers: ruiu, pcc, MaskRay, smeenai, alexshap, gkm, Ktwu, christylee
Reviewed By: smeenai
Subscribers: llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D80857
Summary:
As far as I can tell, it's identical to _GOT_LOAD. llvm-mc has the following
comment explaining why _GOT exists:
```
// x86_64 distinguishes movq foo@GOTPCREL so that the linker can
// rewrite the movq to an leaq at link time if the symbol ends up in
// the same linkage unit.
```
Depends on D80855.
Reviewers: ruiu, pcc, MaskRay, smeenai, alexshap, gkm, Ktwu, christylee
Reviewed By: MaskRay, smeenai
Subscribers: llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D80856
Summary:
We should be reading / writing our addends / relocated addresses based on
r_length, and not just based on the type of the relocation. But since only
some r_length values are valid for a given reloc type, I've also added some
validation.
ld64 has code to allow for r_length = 0 in X86_64_RELOC_BRANCH relocs, but I'm
not sure how to create such a relocation...
Reviewed By: smeenai
Differential Revision: https://reviews.llvm.org/D80854
I considered making a `Target::validate()` method, but I wasn't sure how
I felt about the overhead of doing yet another switch-dispatch on the
relocation type, so I put the validation in `relocateOne` instead...
might be a bit of a micro-optimization, but `relocateOne` does assume
certain things about the relocations it gets, and this error handling
makes that explicit, so it's not a totally unreasonable code
organization.
Reviewed By: smeenai
Differential Revision: https://reviews.llvm.org/D80049
Summary:
This diff implements lazy symbol binding -- very similar to the PLT
mechanism in ELF.
ELF's .plt section is broken up into two sections in Mach-O:
StubsSection and StubHelperSection. Calls to functions in dylibs will
end up calling into StubsSection, which contains indirect jumps to
addresses stored in the LazyPointerSection (the counterpart to ELF's
.plt.got).
Initially, the LazyPointerSection contains addresses that point into one
of the entry points in the middle of the StubHelperSection. The code in
StubHelperSection will push on the stack an offset into the
LazyBindingSection. The push is followed by a jump to the beginning of
the StubHelperSection (similar to PLT0), which then calls into
dyld_stub_binder. dyld_stub_binder is a non-lazily bound symbol, so this
call looks it up in the GOT.
The stub binder will look up the bind opcodes in the LazyBindingSection
at the given offset. The bind opcodes will tell the binder to update the
address in the LazyPointerSection to point to the symbol, so that
subsequent calls don't have to redo the symbol resolution. The binder
will then jump to the resolved symbol.
Depends on D78269.
Reviewers: ruiu, pcc, MaskRay, smeenai, alexshap, gkm, Ktwu, christylee
Subscribers: llvm-commits
Tags: #llvm
Differential Revision: https://reviews.llvm.org/D78270
We currently only support extern relocations.
`X86_64_RELOC_SIGNED_{1,2,4}` are like X86_64_RELOC_SIGNED, but with the
implicit addend fixed to 1, 2, and 4, respectively.
See the comment in `lib/Target/X86/MCTargetDesc/X86MachObjectWriter.cpp RecordX86_64Relocation`.
Reviewed By: int3
Differential Revision: https://reviews.llvm.org/D79311
This diff implements:
* dylib loading (much of which is being restored from @pcc and @ruiu's
original work)
* The GOT_LOAD relocation, which allows us to load non-lazy dylib
symbols
* Basic bind opcode emission, which tells `dyld` how to populate the GOT
Differential Revision: https://reviews.llvm.org/D76252
Summary:
This is the first commit for the new Mach-O backend, designed to roughly
follow the architecture of the existing ELF and COFF backends, and
building off work that @ruiu and @pcc did in a branch a while back. Note
that this is a very stripped-down commit with the bare minimum of
functionality for ease of review. We'll be following up with more diffs
soon.
Currently, we're able to generate a simple "Hello World!" executable
that runs on OS X Catalina (and possibly on earlier OS X versions; I
haven't tested them). (This executable can be obtained by compiling
`test/MachO/relocations.s`.) We're mocking out a few load commands to
achieve this -- for example, we can't load dynamic libraries, but
Catalina requires binaries to be linked against `dyld`, so we hardcode
the emission of a `LC_LOAD_DYLIB` command. Other mocked out load
commands include LC_SYMTAB and LC_DYSYMTAB.
Differential Revision: https://reviews.llvm.org/D75382