It turns out that during training, the time required to parse the
textual protobuf of a training log is about the same as the time it
takes to compile the module generating that log. Using binary protobufs
instead elides that cost almost completely.
Differential Revision: https://reviews.llvm.org/D106157
This diff changes llvm-ifs to use unified IFS file format
and perform other renaming changes in preparation for the
merging between elfabi/ifs.
Differential Revision: https://reviews.llvm.org/D99810
This change implements unified text stub format and command line
interface proposed in the elfabi/ifs merge plan.
Differential Revision: https://reviews.llvm.org/D99399
Adds support for MachO static initializers/deinitializers and eh-frame
registration via the ORC runtime.
This commit introduces cooperative support code into the ORC runtime and ORC
LLVM libraries (especially the MachOPlatform class) to support macho runtime
features for JIT'd code. This commit introduces support for static
initializers, static destructors (via cxa_atexit interposition), and eh-frame
registration. Near-future commits will add support for MachO native
thread-local variables, and language runtime registration (e.g. for Objective-C
and Swift).
The llvm-jitlink tool is updated to use the ORC runtime where available, and
regression tests for the new MachOPlatform support are added to compiler-rt.
Notable changes on the ORC runtime side:
1. The new macho_platform.h / macho_platform.cpp files contain the bulk of the
runtime-side support. This includes eh-frame registration; jit versions of
dlopen, dlsym, and dlclose; a cxa_atexit interpose to record static destructors,
and an '__orc_rt_macho_run_program' function that defines running a JIT'd MachO
program in terms of the jit- dlopen/dlsym/dlclose functions.
2. Replaces JITTargetAddress (and casting operations) with ExecutorAddress
(copied from LLVM) to improve type-safety of address management.
3. Adds serialization support for ExecutorAddress and unordered_map types to
the runtime-side Simple Packed Serialization code.
4. Adds orc-runtime regression tests to ensure that static initializers and
cxa-atexit interposes work as expected.
Notable changes on the LLVM side:
1. The MachOPlatform class is updated to:
1.1. Load the ORC runtime into the ExecutionSession.
1.2. Set up standard aliases for macho-specific runtime functions. E.g.
___cxa_atexit -> ___orc_rt_macho_cxa_atexit.
1.3. Install the MachOPlatformPlugin to scrape LinkGraphs for information
needed to support MachO features (e.g. eh-frames, mod-inits), and
communicate this information to the runtime.
1.4. Provide entry-points that the runtime can call to request initializers,
perform symbol lookup, and request deinitialiers (the latter is
implemented as an empty placeholder as macho object deinits are rarely
used).
1.5. Create a MachO header object for each JITDylib (defining the __mh_header
and __dso_handle symbols).
2. The llvm-jitlink tool (and llvm-jitlink-executor) are updated to use the
runtime when available.
3. A `lookupInitSymbolsAsync` method is added to the Platform base class. This
can be used to issue an async lookup for initializer symbols. The existing
`lookupInitSymbols` method is retained (the GenericIRPlatform code is still
using it), but is deprecated and will be removed soon.
4. JIT-dispatch support code is added to ExecutorProcessControl.
The JIT-dispatch system allows handlers in the JIT process to be associated with
'tag' symbols in the executor, and allows the executor to make remote procedure
calls back to the JIT process (via __orc_rt_jit_dispatch) using those tags.
The primary use case is ORC runtime code that needs to call bakc to handlers in
orc::Platform subclasses. E.g. __orc_rt_macho_jit_dlopen calling back to
MachOPlatform::rt_getInitializers using __orc_rt_macho_get_initializers_tag.
(The system is generic however, and could be used by non-runtime code).
The new ExecutorProcessControl::JITDispatchInfo struct provides the address
(in the executor) of the jit-dispatch function and a jit-dispatch context
object, and implementations of the dispatch function are added to
SelfExecutorProcessControl and OrcRPCExecutorProcessControl.
5. OrcRPCTPCServer is updated to support JIT-dispatch calls over ORC-RPC.
6. Serialization support for StringMap is added to the LLVM-side Simple Packed
Serialization code.
7. A JITLink::allocateBuffer operation is introduced to allocate writable memory
attached to the graph. This is used by the MachO header synthesis code, and will
be generically useful for other clients who want to create new graph content
from scratch.
This patch relands https://reviews.llvm.org/D104799, but fixes the
memory handling causing leak sanitizer failures.
This reverts commit a56fe117e04f7d4b953a4226af412dad59425fb5.
At most these use the StringRef/Twine wrappers and don't have any implicit uses of std::string.
Move the include down to any cpp implementation where std::string is actually used.
llvm::KnownBits::byteSwap() and reverse() don't modify in-place, so
we weren't actually computing anything. This was causing a miscompile on an
arm64 stage2 bootstrap clang build.
We can build it with -Werror=global-constructors now. This helps
in situation where libSupport is embedded as a shared library,
potential with dlopen/dlclose scenario, and when command-line
parsing or other facilities may not be involved. Avoiding the
implicit construction of these cl::opt can avoid double-registration
issues and other kind of behavior.
Reviewed By: lattner, jpienaar
Differential Revision: https://reviews.llvm.org/D105959
We can build it with -Werror=global-constructors now. This helps
in situation where libSupport is embedded as a shared library,
potential with dlopen/dlclose scenario, and when command-line
parsing or other facilities may not be involved. Avoiding the
implicit construction of these cl::opt can avoid double-registration
issues and other kind of behavior.
Reviewed By: lattner, jpienaar
Differential Revision: https://reviews.llvm.org/D105959
We can build it with -Werror=global-constructors now. This helps
in situation where libSupport is embedded as a shared library,
potential with dlopen/dlclose scenario, and when command-line
parsing or other facilities may not be involved. Avoiding the
implicit construction of these cl::opt can avoid double-registration
issues and other kind of behavior.
Reviewed By: lattner, jpienaar
Differential Revision: https://reviews.llvm.org/D105959
The ceiling variant was recently added (due to the work towards D105216), and we're spending a lot of time trying to find optimizations for the expression. This patch brute forces the space of i8 unsigned divides and checks that we get a correct (well consistent with APInt) result for both udiv and udiv ceiling.
(This is basically what I've been doing locally in a hand rolled C++ program, and I realized there no good reason not to check it in as a unit test which directly exercises the logic on constants.)
Differential Revision: https://reviews.llvm.org/D106083
SME introduces the ZA array, a new piece of architectural register state
consisting of a matrix of [SVLb x SVLb] bytes, where SVL is the
implementation defined Streaming SVE vector length and SVLb is the
number of 8-bit elements in a vector of SVL bits.
SME instructions consist of three types of matrix operands:
* Tiles: a ZA tile is a square, two-dimensional sub-array of elements
within the ZA array. These tiles make up the larger accumulator array
and the granularity varies based on the element size, i.e.
- ZAQ0..ZAQ15 (smallest tile granule)
- ZAD0..ZAD7
- ZAS0..ZAS3
- ZAH0..ZAH1
or ZAB0 (largest tile granule, single tile)
* Tile vectors: similar to regular tiles, but have an extra 'h' or 'v'
to tell how the vector at [reg+offset] is layed out in the tile,
horizontally or vertically. E.g. za1h.h or za15v.q, which corresponds
to vectors in registers ZAH1 and ZAQ15, respectively.
* Accumulator matrix: this is the entire accumulator array ZA.
This patch adds the register classes and related operands and parsing
for SME instructions operating on the accumulator array.
The ADDHA and ADDVA instructions which operate on tiles are also added
in this patch to make some use of the code added, later patches will
make use of the other operands introduced here.
The reference can be found here:
https://developer.arm.com/documentation/ddi0602/2021-06
Co-authored by: Sander de Smalen (@sdesmalen)
Reviewed By: david-arm
Differential Revision: https://reviews.llvm.org/D105570
Continuing from D105763, this allows placing certain properties
about attributes in the TableGen definition. In particular, we
store whether an attribute applies to fn/param/ret (or a combination
thereof). This information is used by the Verifier, as well as the
ForceFunctionAttrs pass. I also plan to use this in LLParser,
which also duplicates info on which attributes are valid where.
This keeps metadata about attributes in one place, and makes it
more likely that it stays in sync, rather than in various
functions spread across the codebase.
Differential Revision: https://reviews.llvm.org/D105780
First patch in a series adding MC layer support for the Arm Scalable
Matrix Extension.
This patch adds the following features:
sme, sme-i64, sme-f64
The sme-i64 and sme-f64 flags are for the optional I16I64 and F64F64
features.
If a target supports I16I64 then the following instructions are
implemented:
* 64-bit integer ADDHA and ADDVA variants (D105570).
* SMOPA, SMOPS, SUMOPA, SUMOPS, UMOPA, UMOPS, USMOPA, and USMOPS
instructions that accumulate 16-bit integer outer products into 64-bit
integer tiles.
If a target supports F64F64 then the FMOPA and FMOPS instructions that
accumulate double-precision floating-point outer products into
double-precision tiles are implemented.
Outer products are implemented in D105571.
The reference can be found here:
https://developer.arm.com/documentation/ddi0602/2021-06
Reviewed By: CarolineConcatto
Differential Revision: https://reviews.llvm.org/D105569
This patch makes the operations on InstructionCost saturate, so that when
costs are accumulated they saturate to <max value>.
One of the compelling reasons for wanting to have saturation support
is because in various places, arbitrary values are used to represent
a 'high' cost, but when accumulating the cost of some set of operations
or a loop, overflow is not taken into account, which may lead to unexpected
results. By defining the operations to saturate, we can express the cost
of something 'very expensive' as InstructionCost::getMax().
Reviewed By: kparzysz, dmgreen
Differential Revision: https://reviews.llvm.org/D105108
Rules:
1. SCEVUnknown is a pointer if and only if the LLVM IR value is a
pointer.
2. SCEVPtrToInt is never a pointer.
3. If any other SCEV expression has no pointer operands, the result is
an integer.
4. If a SCEVAddExpr has exactly one pointer operand, the result is a
pointer.
5. If a SCEVAddRecExpr's first operand is a pointer, and it has no other
pointer operands, the result is a pointer.
6. If every operand of a SCEVMinMaxExpr is a pointer, the result is a
pointer.
7. Otherwise, the SCEV expression is invalid.
I'm not sure how useful rule 6 is in practice. If we exclude it, we can
guarantee that ScalarEvolution::getPointerBase always returns a
SCEVUnknown, which might be a helpful property. Anyway, I'll leave that
for a followup.
This is basically mop-up at this point; all the changes with significant
functional effects have landed. Some of the remaining changes could be
split off, but I don't see much point.
Differential Revision: https://reviews.llvm.org/D105510
C++23 will make these conversions ambiguous - so fix them to make the
codebase forward-compatible with C++23 (& a follow-up change I've made
will make this ambiguous/invalid even in <C++23 so we don't regress
this & it generally improves the code anyway)
SelectionDAG's equivalents in ISD::InputArg/OutputArg track the
original argument index. Mips relies on this, and its currently
reinventing its own parallel CallLowering infrastructure which tracks
these indexes on the side. Add this to help move towards deleting the
custom mips handling.
This adds a new llvm::thread class with the same interface as std::thread
except there is an extra constructor that allows us to set the new thread's
stack size. On Darwin even the default size is boosted to 8MB to match the main
thread.
It also switches all users of the older C-style `llvm_execute_on_thread` API
family over to `llvm::thread` followed by either a `detach` or `join` call and
removes the old API.
Moved definition of DefaultStackSize into the .cpp file to hopefully
fix the build on some (GCC-6?) machines.
This adds a new llvm::thread class with the same interface as std::thread
except there is an extra constructor that allows us to set the new thread's
stack size. On Darwin even the default size is boosted to 8MB to match the main
thread.
It also switches all users of the older C-style `llvm_execute_on_thread` API
family over to `llvm::thread` followed by either a `detach` or `join` call and
removes the old API.
These currently always require a type parameter. The bitcode reader
already upgrades old bitcode without the type parameter to use the
pointee type.
In cases where the caller does not have byval but the callee does, we
need to follow CallBase::paramHasAttr() and also look at the callee for
the byval type so that CallBase::isByValArgument() and
CallBase::getParamByValType() are in sync. Do the same for preallocated.
While we're here add a corresponding version for inalloca since we'll
need it soon.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D104663
The build system was linking the PluginsTests unittest against libLLVM.so
and LLVMAsmParser which was causing the test to fail with this error:
LLVM ERROR: inconsistency in registered CommandLine options
We need to add llvm libraries to LLVM_LINK_COMPONENTS so that
they are dropped from the linker arguments when linking with
LLVM_LINK_LLVM_DYLIB=ON
Reviewed By: aeubanks
Differential Revision: https://reviews.llvm.org/D105523
This change yields an additional 2% size reduction on an internal search
binary, and an additional 0.5% size reduction on fuchsia.
Differential Revision: https://reviews.llvm.org/D104751
Address mistakenly comparing the pointer values of two C-style strings
rather than comparing their contents in the unit tests for makeVisitor,
added in 6d6f35eb7b92c6dd4478834497752f4e963db16d
This patch adds intrinsic definitions and SDNodes for predicated
load/store/gather/scatter, based on the work done in D57504.
Reviewed By: simoll, craig.topper
Differential Revision: https://reviews.llvm.org/D99355
Adds support for both synchronous and asynchronous calls to wrapper functions
using SPS (Simple Packed Serialization). Also adds support for wrapping
functions on the JIT side in SPS-based wrappers that can be called from the
executor.
These new methods simplify calls between the JIT and Executor, and will be used
in upcoming ORC runtime patches to enable communication between ORC and the
runtime.
This enables proper lowering of non-byte sized loads. We still aren't
faithfully preserving memory types everywhere, so the legality checks
still only consider the size.
This will currently accept the old number of bytes syntax, and convert
it to a scalar. This should be removed in the near future (I think I
converted all of the tests already, but likely missed a few).
Not sure what the exact syntax and policy should be. We can continue
printing the number of bytes for non-generic instructions to avoid
test churn and only allow non-scalar types for generic instructions.
This will currently print the LLT in parentheses, but accept parsing
the existing integers and implicitly converting to scalar. The
parentheses are a bit ugly, but the parser logic seems unable to deal
without either parentheses or some keyword to indicate the start of a
type.
Dynamically loaded plugins for the new pass manager are initialised by
calling llvmGetPassPluginInfo. This is defined as a weak symbol so that
it is continually redefined by each plugin that is loaded. When loading
a plugin from a shared library, the intention is that
llvmGetPassPluginInfo will be resolved to the definition in the most
recent plugin. However, using a global search for this resolution can
fail in situations where multiple plugins are loaded.
Currently:
* If a plugin does not define llvmGetPassPluginInfo, then it will be
silently resolved to the previous plugin's definition.
* If loading the same plugin twice with another in between, e.g. plugin
A/plugin B/plugin A, then the second load of plugin A will resolve to
llvmGetPassPluginInfo in plugin B.
* The previous case can also occur when a dynamic library defines both
NPM and legacy plugins; the legacy plugins are loaded first and then
with `-fplugin=A -fpass-plugin=B -fpass-plugin=A`: A will be loaded as
a legacy plugin and define llvmGetPassPluginInfo; B will be loaded
and redefine it; and finally when A is loaded as an NPM plugin it will
be resolved to the definition from B.
Instead of searching globally, restrict the symbol lookup to the library
that is currently being loaded.
Differential Revision: https://reviews.llvm.org/D104916
Symbol tables can have symbols with no size in mach-o files that were failing to get combined into a single entry. This resulted in many duplicate entries for the same address and made gsym files larger.
Differential Revision: https://reviews.llvm.org/D105068
Relands patch reverted by 61242c0addb120294211d24a97ed89837418cb36
The original patch mistakenly included unrelated tests.
Adds a utility to combine multiple Callables into a single Callable.
This is useful to make constructing a visitor for `std::visit`-like
functions more natural; functions like this will be added in future
patches.
Intended to supercede https://reviews.llvm.org/D99560 by
perfectly-forwarding the combined Callables.
Reviewed By: dblaikie
Differential Revision: https://reviews.llvm.org/D100670
Adds a utility to combine multiple Callables into a single Callable.
This is useful to make constructing a visitor for `std::visit`-like
functions more natural; functions like this will be added in future
patches.
Intended to supercede https://reviews.llvm.org/D99560 by
perfectly-forwarding the combined Callables.
Reviewed By: dblaikie
Differential Revision: https://reviews.llvm.org/D100670
On AIX the alignment implementation has the storage aligned to the
preferred alignment instead of the alignment of a type. Macro guard
these tests for AIX and have them pass when the "reference alignment" is
less than or equal to the alignment observed. In other words, the
alignment applied is at least as strict as the required alignment.
Reviewed By: hubert.reinterpretcast
Differential Revision: https://reviews.llvm.org/D104786