llvm dev - Jan 2021 - LLVM Orc Weekly #28 -- ORC Runtime Prototype update

Big question for JIT clients: Does anyone have any objection to APIs in ORC
*relying* on the runtime being loaded in the target? If so, now is the time
to let me know. :)

I think possible objections are JIT'd program startup time (unlikely to be
very high, and likely fixable via careful runtime design and pre-linking of
parts of the runtime), and difficulties building compiler-rt (which sounds
like something we should fix in compiler-rt).

If we can assume that the runtime is loadable then we can significantly
simplify the TargetProcess library, and TargetProcessControl API, and
further accelerate feature development in LLVM 13.

-- Lang.

On Tue, Jan 19, 2021 at 8:45 AM Lang Hames <lhames at gmail.com> wrote:
> Hi Stefan,
>
> % ./bin/llvm-jitlink -oop-executor inits.o
>> JIT session error: Symbols not found: [
>> __ZTIN4llvm6detail14format_adapterE ]
>
>
> I've been testing with a debug build:
>
> % xcrun cmake -GNinja -DCMAKE_BUILD_TYPE=Debug
> -DLLVM_ENABLE_PROJECTS="llvm;clang;compiler-rt" ../llvm
>
> Matching this build might fix the issue, though building with my config
> (if it works) is only a short-term fix. The error that you're seeing
> implies that the runtime is dependending on a symbol from libSupport that
> is not being linked in to the target (llvm-jitlink-executor). I'll aim
to
> break these dependencies on libSupport in the future. Mostly that means
> either removing the dependence on llvm::Error / llvm::Expected (e.g. by
> creating stripped down versions for the orc runtime), or making those types
> header-only.
>
> -- Lang.
>
>
>
>
>
> On Tue, Jan 19, 2021 at 12:50 AM Stefan Gränitz <stefan.graenitz at
gmail.com>
> wrote:
>
>> Wow, thanks for the update. One more ORC milestone in a short period of
>> time!
>>
>> On macOS I built the C++ example like this:
>>
>> % cmake -GNinja -DLLVM_TARGETS_TO_BUILD=host
>> -DLLVM_ENABLE_PROJECTS="clang;compiler-rt" ../llvm
>> % ninja llvm-jitlink llvm-jitlink-executor
>> lib/clang/12.0.0/lib/darwin/libclang_rt.orc_osx.a
>> % clang++ -c -o inits.o inits.cpp
>>
>> The in-process version works perfectly, but with the out-of-process
flag
>> the examples fails:
>>
>> % ./bin/llvm-jitlink inits.o
>> Foo::Foo()
>> Foo::foo()
>> Foo::~Foo()
>> % ./bin/llvm-jitlink -oop-executor inits.o
>> JIT session error: Symbols not found: [
>> __ZTIN4llvm6detail14format_adapterE ]
>>
>> Any idea what could go wrong here? Otherwise I can try to debug it
later
>> this week. (Full error below.)
>>
>> Best
>> Stefan
>>
>> --
>>
>> JIT session error: Symbols not found: [
>> __ZTIN4llvm6detail14format_adapterE ]
>>
/Users/staefsn/Develop/LLVM/monorepo/llvm-orc-runtime/build/bin/llvm-jitlink:
>> Failed to materialize symbols: { (Main, {
>> ___orc_rt_macho_symbol_lookup_remote,
>>
__ZN4llvm3orc6shared21WrapperFunctionResult22destroyWithArrayDeleteE39LLVMOrcSharedCWrapperFunctionResultDatay,
>>
__ZNSt3__113__vector_baseIN4llvm3orc6shared25MachOJITDylibInitializersENS_9allocatorIS4_EEED2Ev,
>>
__ZNK4llvm8ExpectedINS_3orc6shared21WrapperFunctionResultEE22fatalUncheckedExpectedEv,
>>
__ZN4llvm3orc6shared21toWrapperFunctionBlobIJNSt3__112basic_stringIcNS3_11char_traitsIcEENS3_9allocatorIcEEEEEEENS1_21WrapperFunctionResultEDpRKT_,
>> __ZN4llvm3orc6shared20VectorRawByteChannelD1Ev,
>>
__ZN4llvm3orc6shared21SequenceSerializationINS1_20VectorRawByteChannelEJNSt3__16vectorINS1_25MachOJITDylibInitializers13SectionExtentENS4_9allocatorIS7_EEEESA_SA_EE11deserializeISA_JSA_SA_EEENS_5ErrorERS3_RT_DpRT0_,
>>
__ZNSt3__16vectorIN4llvm3orc6shared25MachOJITDylibInitializers13SectionExtentENS_9allocatorIS5_EEE8__appendEm,
>>
__ZN4llvm3orc6shared21toWrapperFunctionBlobIJyNSt3__112basic_stringIcNS3_11char_traitsIcEENS3_9allocatorIcEEEEEEENS1_21WrapperFunctionResultEDpRKT_,
>> __ZN4llvm29VerifyEnableABIBreakingChecksE,
>>
__ZN4llvm15format_providerImvE6formatERKmRNS_11raw_ostreamENS_9StringRefE,
>>
__ZNSt3__114__split_bufferIN4llvm3orc6shared25MachOJITDylibInitializersERNS_9allocatorIS4_EEED2Ev,
>> __ZTVN4llvm6detail23provider_format_adapterIRmEE,
>>
__ZN4llvm3orc6shared21SequenceSerializationINS1_20VectorRawByteChannelEJyNSt3__112basic_stringIcNS4_11char_traitsIcEENS4_9allocatorIcEEEEEE9serializeIRKyJRKSA_EEENS_5ErrorERS3_OT_DpOT0_,
>> __ZTVN4llvm6detail23provider_format_adapterImEE,
>>
__ZN4llvm6detail23provider_format_adapterImE6formatERNS_11raw_ostreamENS_9StringRefE,
>> __ZN4llvm6detail23provider_format_adapterIRmED1Ev,
>> ___orc_rt_macho_get_deinitializers_tag,
>> __ZN4llvm6detail23provider_format_adapterIRmED0Ev,
>> __ZTVN4llvm3orc6shared14RawByteChannelE,
>> __ZN6orc_rt12jit_dispatchEPKvN4llvm8ArrayRefIhEE,
>> __ZN4llvm3orc6shared20VectorRawByteChannelD0Ev,
>> __ZTVN4llvm3orc6shared20VectorRawByteChannelE,
>> __ZN4llvm8cantFailENS_5ErrorEPKc,
>> __ZN4llvm6detail23provider_format_adapterImED1Ev,
>> __ZTVN4llvm6detail23provider_format_adapterIRjEE,
>> __ZN4llvm6detail23provider_format_adapterImED0Ev,
>>
__ZN4llvm15format_providerIjvE6formatERKjRNS_11raw_ostreamENS_9StringRefE,
>> __ZTSN4llvm3orc6shared14RawByteChannelE,
>>
__ZN4llvm6detail23provider_format_adapterIRjE6formatERNS_11raw_ostreamENS_9StringRefE,
>> __ZN4llvm6detail23provider_format_adapterIRjED0Ev,
>>
__ZN4llvm3orc6shared19SerializationTraitsINS1_20VectorRawByteChannelENSt3__16vectorINS1_25MachOJITDylibInitializersENS4_9allocatorIS6_EEEES9_vE11deserializeERS3_RS9_,
>> __ZTIN4llvm6detail23provider_format_adapterImEE,
>>
__ZN4llvm6detail15HelperFunctions15consumeHexStyleERNS_9StringRefERNS_13HexPrintStyleE,
>> __ZTIN4llvm6detail23provider_format_adapterIRmEE,
>> ___orc_rt_macho_get_initializers_tag,
>> __ZTSN4llvm6detail23provider_format_adapterImEE,
>> __ZN4llvm3orc6shared20VectorRawByteChannel4sendEv,
>>
__ZN4llvm6detail23provider_format_adapterIRmE6formatERNS_11raw_ostreamENS_9StringRefE,
>> ___orc_rt_macho_symbol_lookup_tag,
>> __ZTSN4llvm6detail23provider_format_adapterIRmEE,
>> __ZN4llvm3orc6shared20VectorRawByteChannel11appendBytesEPKcj,
>> __ZTSN4llvm6detail23provider_format_adapterIRjEE,
>> __ZN4llvm3orc6shared20VectorRawByteChannel9readBytesEPcj,
>> __ZTSN4llvm3orc6shared20VectorRawByteChannelE,
>> __ZN4llvm6detail23provider_format_adapterIRjED1Ev,
>> __ZN4llvm3orc6shared14RawByteChannelD1Ev,
>>
__ZN4llvm3orc6shared23fromWrapperFunctionBlobIJNSt3__16vectorINS1_25MachOJITDylibInitializersENS3_9allocatorIS5_EEEEEEENS_5ErrorENS_8ArrayRefIhEEDpRT_,
>> __ZN4llvm3orc6shared14RawByteChannelD0Ev,
>>
__ZN4llvm3orc6shared21SequenceSerializationINS1_20VectorRawByteChannelEJyyNSt3__16vectorINS1_25MachOJITDylibInitializers13SectionExtentENS4_9allocatorIS7_EEEESA_SA_EE11deserializeIyJySA_SA_SA_EEENS_5ErrorERS3_RT_DpRT0_,
>>
__ZNSt3__16vectorIN4llvm3orc6shared25MachOJITDylibInitializersENS_9allocatorIS4_EEE8__appendEm,
>>
__ZN4llvm3orc6shared21SequenceSerializationINS1_20VectorRawByteChannelEJyyEE11deserializeIyJyEEENS_5ErrorERS3_RT_DpRT0_,
>>
__ZNSt3__16vectorIN4llvm3orc6shared25MachOJITDylibInitializersENS_9allocatorIS4_EEE6resizeEm,
>>
__ZN4llvm3orc6shared19SerializationTraitsINS1_20VectorRawByteChannelENSt3__112basic_stringIcNS4_11char_traitsIcEENS4_9allocatorIcEEEESA_vE11deserializeERNS1_14RawByteChannelERSA_,
>>
__ZN4llvm3orc6shared23fromWrapperFunctionBlobIJyEEENS_5ErrorENS_8ArrayRefIhEEDpRT_,
>> __ZTIN4llvm6detail23provider_format_adapterIRjEE,
>> __ZN4llvm3orc6shared21WrapperFunctionResult20getAnyOutOfBandErrorEv,
>> __ZTIN4llvm3orc6shared20VectorRawByteChannelE,
>> ___orc_rt_macho_get_initializers_remote,
>> __ZTIN4llvm3orc6shared14RawByteChannelE,
>>
__ZNSt3__16vectorIhNS_9allocatorIhEEE26__swap_out_circular_bufferERNS_14__split_bufferIhRS2_EE,
>>
__ZN4llvm3orc6shared19SerializationTraitsINS1_20VectorRawByteChannelENSt3__16vectorINS1_25MachOJITDylibInitializers13SectionExtentENS4_9allocatorIS7_EEEESA_vE11deserializeERS3_RSA_
>> }) }
>>
/Users/staefsn/Develop/LLVM/monorepo/llvm-orc-runtime/build/bin/llvm-jitlink-executor:Response
>> has unknown sequence number 527162
>>
>> On 18/01/2021 08:55, Lang Hames wrote:
>>
>> Hi All,
>>
>> Happy 2021!
>>
>> I've just posted a new Orc Runtime Preview patch:
>>
https://github.com/lhames/llvm-project/commit/8833a7f24693f1c7a3616438718e7927c6624894
>>
>> Quick background:
>>
>> To date, neither ORC nor MCJIT have had their own runtime libraries.
This
>> has limited and complicated the implementation of many features (e.g.
jit
>> re-entry functions, exception handling, JID'd initializers and
>> de-initializers), and more-or-less prevented the implementation of
others
>> (e.g. native thread local storage).
>>
>> Late last year I started work on a prototype ORC runtime library to
>> address this, and with the above commit I've finally got something
worth
>> sharing.
>>
>> The prototype above is simultaneously limited and complex. Limited, in
>> that it only tackles a small subset of the desired functionality.
Complex
>> in that it's one of the most involved pieces of functionality that
I
>> anticipate supporting, as it requires two-way communication between the
>> executor and JIT processes. My aim in choosing to tackle the hard part
>> first was to get a sense of our ultimate requirements for the project,
>> particularly in regards to *where it should live within the LLVM
Project*.
>> It's not a perfect fit for LLVM proper: there will be lots of
target
>> specific code, including assembly, and it should be easily buildable
for
>> multiple targets (that sounds more like compiler-rt). On the other hand
>> it's not a perfect fit for compiler-rt: it shares data structures
with
>> LLVM, and it would be very useful to be able to re-use llvm::Error  /
>> llvm::Expected (that sounds like LLVM). At the moment I think the best
way
>> to square things would be to keep it in compiler-rt, allow inclusion of
>> header-only code from LLVM in compiler-rt, and then make Error /
Expected
>> header-only (or copy / adapt them for this library). This will be a
>> discussion for llvm-dev at some point in the near future.
>>
>> On to the actual functionality though: The prototype makes significant
>> changes to the MachOPlatform class and introduces an ORC runtime
library in
>> compiler-rt/lib/orc. Together, these changes allow us to emulate the
dlopen
>> / dlsym / dlclose in the JIT executor process. We can use this to
define
>> what it means to run a *JIT program*, rather than just running a JIT
>> function (the way TargetProcessControl::runAsMain does):
>>
>> ORC_RT_INTERFACE int64_t __orc_rt_macho_run_program(int argc, char
*argv[])
>> {
>>   using MainTy = int (*)(int, char *[]);
>>
>>   void *H = __orc_rt_macho_jit_dlopen("Main",
ORC_RT_RTLD_LAZY);
>>   if (!H) {
>>     __orc_rt_log_error(__orc_rt_macho_jit_dlerror());
>>     return -1;
>>   }
>>
>>   auto *Main =
reinterpret_cast<MainTy>(__orc_rt_macho_jit_dlsym(H,
>> "main"));
>>   if (!Main) {
>>     __orc_rt_log_error(__orc_rt_macho_jit_dlerror());
>>     return -1;
>>   }
>>
>>   int Result = Main(argc, argv);
>>
>>   if (__orc_rt_macho_jit_dlclose(H) == -1)
>>     __orc_rt_log_error(__orc_rt_macho_jit_dlerror());
>>
>>   return Result;
>> }
>>
>> The functions __orc_rt_macho_jit_dlopen, __orc_rt_macho_jit_dlsym,
>> and __orc_rt_macho_jit_dlclose behave the same as their dlfcn.h
>> counterparts (dlopen, dlsym, dlclose), but operate on JITDylibs rather
than
>> regular dylibs. This includes running static initializers and
registering
>> with language runtimes (e.g. ObjC).
>>
>> While we could run static initializers before (e.g. via
>> LLJIT::runConstructors), we had to initiate this from the JIT process
side,
>> which has two significant drawbacks: (1) Extra RPC round trips, and (2)
in
>> the out-of-process case: initializers not running on the executor
thread
>> that requested them, since that thread will be blocked waiting for its
call
>> to return. Issue (1) only affects performance, but (2) can affect
>> correctness if the initializers modify thread local values, or interact
>> with locks or threads. Interacting with threads from initializers is
>> generally best avoided, but nonetheless is done by real-world code, so
we
>> want to support it. By using the runtime we can improve both
performance
>> and correctness (or at least consistency with current behavior).
>>
>> The effect of this is that we can now load C++, Objective-C and Swift
>> programs in the JIT and expect them to run correctly, at least for
simple
>> cases. This works regardless of whether the JIT'd code runs
in-process or
>> out-of-process. To test all this I have integrated support for the
>> prototype runtime into llvm-jitlink. You can demo output from this tool
>> below for two simple input programs: One swift, one C++. All of this is
>> MachO specific at the moment, but provides a template that could be
easily
>> re-used to support this on ELF platforms, and likely on COFF platforms
too.
>>
>> While the discussion on where the runtime should live plays out I will
>> continue adding / moving functionality to the prototype runtime. Next
up
>> will be eh-frame registration and resolver functions (both currently in
>> OrcTargetProcess). After that I'll try to tackle support for native
MachO
>> thread local storage.
>>
>> As always: Questions and comments are very welcome.
>>
>> -- Lang.
>>
>> lhames at Langs-MacBook-Pro scratch % cat foo.swift
>> class MyClass {
>>   func foo() {
>>     print("foo")
>>   }
>> }
>>
>> let m = MyClass()
>> m.foo();
>>
>> lhames at Langs-MacBook-Pro scratch % xcrun swiftc -emit-object -o
foo.o
>> foo.swift
>> lhames at Langs-MacBook-Pro scratch % llvm-jitlink -dlopen
>> /usr/lib/swift/libswiftCore.dylib foo.o
>> foo
>> lhames at Langs-MacBook-Pro scratch % llvm-jitlink -oop-executor
-dlopen
>> /usr/lib/swift/libswiftCore.dylib foo.o
>> foo
>> lhames at Langs-MacBook-Pro scratch % cat inits.cpp
>> #include <iostream>
>>
>> class Foo {
>> public:
>>   Foo() { std::cout << "Foo::Foo()\n"; }
>>   ~Foo() { std::cout << "Foo::~Foo()\n"; }
>>   void foo() { std::cout << "Foo::foo()\n"; }
>> };
>>
>> Foo F;
>>
>> int main(int argc, char *argv[]) {
>>   F.foo();
>>   return 0;
>> }
>> lhames at Langs-MacBook-Pro scratch % xcrun clang++ -c -o inits.o
inits.cpp
>> lhames at Langs-MacBook-Pro scratch % llvm-jitlink inits.o
>>
>> Foo::Foo()
>> Foo::foo()
>> Foo::~Foo()
>> lhames at Langs-MacBook-Pro scratch % llvm-jitlink -oop-executor
inits.o
>> Foo::Foo()
>> Foo::foo()
>> Foo::~Foo()
>>
>> -- https://flowcrypt.com/pub/stefan.graenitz at gmail.com
>>
>>
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We always compile and execute in the same process, so I don't imagine that
would make any difference to us...?

Geoff

On Tue, Jan 19, 2021 at 11:08 PM Lang Hames <lhames at gmail.com> wrote:
> Big question for JIT clients: Does anyone have any objection to APIs in
> ORC *relying* on the runtime being loaded in the target? If so, now is the
> time to let me know. :)
>
> I think possible objections are JIT'd program startup time (unlikely to
be
> very high, and likely fixable via careful runtime design and pre-linking of
> parts of the runtime), and difficulties building compiler-rt (which sounds
> like something we should fix in compiler-rt).
>
> If we can assume that the runtime is loadable then we can significantly
> simplify the TargetProcess library, and TargetProcessControl API, and
> further accelerate feature development in LLVM 13.
>
> -- Lang.
>
>
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Would this introduce start-up latency based on the size of the compilation? JIT
jobs with 100-200MB of source are not uncommon here, and I'd hate to see
latency get much worse.

A small enough fixed latency would be ok.
--
Kevin P. Neal
SAS/C and SAS/C++ Compiler
Compute Services
SAS Institute, Inc.


From: llvm-dev <llvm-dev-bounces at lists.llvm.org> On Behalf Of Lang
Hames via llvm-dev
Sent: Tuesday, January 19, 2021 5:09 PM
To: Stefan Gränitz <stefan.graenitz at gmail.com>
Cc: Vivien Millet <vivien.millet at gmail.com>; Athul Acharya <aacharya
at gmail.com>; LLVM Developers Mailing List <llvm-dev at
lists.llvm.org>; kris <cq.personal at gmail.com>; Jared Wyles
<jared.wyles at gmail.com>; Frances Mocnik <fmocnik at gmail.com>;
Jacob Lifshay <programmerjake at gmail.com>; Christian Schafmeister
<meister at temple.edu>
Subject: Re: [llvm-dev] LLVM Orc Weekly #28 -- ORC Runtime Prototype update


EXTERNAL
Big question for JIT clients: Does anyone have any objection to APIs in ORC
*relying* on the runtime being loaded in the target? If so, now is the time to
let me know. :)

I think possible objections are JIT'd program startup time (unlikely to be
very high, and likely fixable via careful runtime design and pre-linking of
parts of the runtime), and difficulties building compiler-rt (which sounds like
something we should fix in compiler-rt).

If we can assume that the runtime is loadable then we can significantly simplify
the TargetProcess library, and TargetProcessControl API, and further accelerate
feature development in LLVM 13.

-- Lang.


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I am always in favor of getting JIT improvements into mainline as soon
as possible. Also, simplifying APIs is an important goal.

On the other hand this raises a few general questions for me:

IIUC the current patch introduces a dependency from LLVM to
compiler-rt/clang build artifacts, because the llvm-jitlink-executor
executable is fully functional only if it can find the clang_rt.orc
static library in the build tree. Do we have dependencies like that in
mainline so far?

And how does it affect testing? So far, it seems we have no testing for
out-of-process execution, because the only tool that exercises this
functionality is llvm-jitlink, which itself is mostly used as a testing
helper. If the functionality now moves into the TargetProcess library,
it might be worth thinking through the test strategy first.

At the moment, the TargetProcess library is only used by JITLink. Will
it stay like that? If so, RuntimeDyld-based JITs will not be affected by
the patch. Will it be possible to build and run e.g. a LLJIT instance
with a RuntimeDyldLinkingLayer if only LLVM gets built (omitting
LLVM_ENABLE_PROJECTS="clang;compiler-rt")?

Last but not least, there are examples that use JITLink. Could we still
build and run them if only LLVM gets built?

Thanks,
Stefan

On 19/01/2021 23:08, Lang Hames wrote:
> Big question for JIT clients: Does anyone have any objection to APIs
> in ORC *relying* on the runtime being loaded in the target? If so, now
> is the time to let me know. :)
>
> I think possible objections are JIT'd program startup time (unlikely
> to be very high, and likely fixable via careful runtime design and
> pre-linking of parts of the runtime), and difficulties building
> compiler-rt (which sounds like something we should fix in compiler-rt).
>
> If we can assume that the runtime is loadable then we can
> significantly simplify the TargetProcess library, and
> TargetProcessControl API, and further accelerate feature development
> in LLVM 13.
>
> -- Lang.
>
> On Tue, Jan 19, 2021 at 8:45 AM Lang Hames <lhames at gmail.com
> <mailto:lhames at gmail.com>> wrote:
>
>     Hi Stefan,
>
>         % ./bin/llvm-jitlink -oop-executor inits.o
>         JIT session error: Symbols not found: [
>         __ZTIN4llvm6detail14format_adapterE ]
>
>
>     I've been testing with a debug build:
>
>     % xcrun cmake -GNinja -DCMAKE_BUILD_TYPE=Debug
>     -DLLVM_ENABLE_PROJECTS="llvm;clang;compiler-rt" ../llvm
>
>     Matching this build might fix the issue, though building with my
>     config (if it works) is only a short-term fix. The error that
>     you're seeing implies that the runtime is dependending on a symbol
>     from libSupport that is not being linked in to the target
>     (llvm-jitlink-executor). I'll aim to break these dependencies on
>     libSupport in the future. Mostly that means either removing the
>     dependence on llvm::Error / llvm::Expected (e.g. by creating
>     stripped down versions for the orc runtime), or making those types
>     header-only.
>
>     -- Lang.
>
>
>
>
>
>     On Tue, Jan 19, 2021 at 12:50 AM Stefan Gränitz
>     <stefan.graenitz at gmail.com <mailto:stefan.graenitz at
gmail.com>> wrote:
>
>         Wow, thanks for the update. One more ORC milestone in a short
>         period of time!
>
>         On macOS I built the C++ example like this:
>
>         % cmake -GNinja -DLLVM_TARGETS_TO_BUILD=host
>         -DLLVM_ENABLE_PROJECTS="clang;compiler-rt" ../llvm
>         % ninja llvm-jitlink llvm-jitlink-executor
>         lib/clang/12.0.0/lib/darwin/libclang_rt.orc_osx.a
>         % clang++ -c -o inits.o inits.cpp
>
>         The in-process version works perfectly, but with the
>         out-of-process flag the examples fails:
>
>         % ./bin/llvm-jitlink inits.o
>         Foo::Foo()
>         Foo::foo()
>         Foo::~Foo()
>         % ./bin/llvm-jitlink -oop-executor inits.o
>         JIT session error: Symbols not found: [
>         __ZTIN4llvm6detail14format_adapterE ]
>
>         Any idea what could go wrong here? Otherwise I can try to
>         debug it later this week. (Full error below.)
>
>         Best
>         Stefan
>
>         --
>
>         JIT session error: Symbols not found: [
>         __ZTIN4llvm6detail14format_adapterE ]
>        
/Users/staefsn/Develop/LLVM/monorepo/llvm-orc-runtime/build/bin/llvm-jitlink:
>         Failed to materialize symbols: { (Main, {
>         ___orc_rt_macho_symbol_lookup_remote,
>        
__ZN4llvm3orc6shared21WrapperFunctionResult22destroyWithArrayDeleteE39LLVMOrcSharedCWrapperFunctionResultDatay,
>        
__ZNSt3__113__vector_baseIN4llvm3orc6shared25MachOJITDylibInitializersENS_9allocatorIS4_EEED2Ev,
>        
__ZNK4llvm8ExpectedINS_3orc6shared21WrapperFunctionResultEE22fatalUncheckedExpectedEv,
>        
__ZN4llvm3orc6shared21toWrapperFunctionBlobIJNSt3__112basic_stringIcNS3_11char_traitsIcEENS3_9allocatorIcEEEEEEENS1_21WrapperFunctionResultEDpRKT_,
>         __ZN4llvm3orc6shared20VectorRawByteChannelD1Ev,
>        
__ZN4llvm3orc6shared21SequenceSerializationINS1_20VectorRawByteChannelEJNSt3__16vectorINS1_25MachOJITDylibInitializers13SectionExtentENS4_9allocatorIS7_EEEESA_SA_EE11deserializeISA_JSA_SA_EEENS_5ErrorERS3_RT_DpRT0_,
>        
__ZNSt3__16vectorIN4llvm3orc6shared25MachOJITDylibInitializers13SectionExtentENS_9allocatorIS5_EEE8__appendEm,
>        
__ZN4llvm3orc6shared21toWrapperFunctionBlobIJyNSt3__112basic_stringIcNS3_11char_traitsIcEENS3_9allocatorIcEEEEEEENS1_21WrapperFunctionResultEDpRKT_,
>         __ZN4llvm29VerifyEnableABIBreakingChecksE,
>        
__ZN4llvm15format_providerImvE6formatERKmRNS_11raw_ostreamENS_9StringRefE,
>        
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>         }) }
>        
/Users/staefsn/Develop/LLVM/monorepo/llvm-orc-runtime/build/bin/llvm-jitlink-executor:Response
>         has unknown sequence number 527162
>
>         On 18/01/2021 08:55, Lang Hames wrote:
>>         Hi All,
>>
>>         Happy 2021!
>>
>>         I've just posted a new Orc Runtime Preview patch:
>>        
https://github.com/lhames/llvm-project/commit/8833a7f24693f1c7a3616438718e7927c6624894
>>        
<https://github.com/lhames/llvm-project/commit/8833a7f24693f1c7a3616438718e7927c6624894>
>>
>>         Quick background:
>>
>>         To date, neither ORC nor MCJIT have had their own runtime
>>         libraries. This has limited and complicated the
>>         implementation of many features (e.g. jit re-entry functions,
>>         exception handling, JID'd initializers and
de-initializers),
>>         and more-or-less prevented the implementation of others (e.g.
>>         native thread local storage).
>>
>>         Late last year I started work on a prototype ORC runtime
>>         library to address this, and with the above commit I've
>>         finally got something worth sharing.
>>
>>         The prototype above is simultaneously limited and complex.
>>         Limited, in that it only tackles a small subset of the
>>         desired functionality. Complex in that it's one of the most
>>         involved pieces of functionality that I anticipate
>>         supporting, as it requires two-way communication between the
>>         executor and JIT processes. My aim in choosing to tackle the
>>         hard part first was to get a sense of our ultimate
>>         requirements for the project, particularly in regards to
>>         /where it should live within the LLVM Project/. It's not a
>>         perfect fit for LLVM proper: there will be lots of target
>>         specific code, including assembly, and it should be easily
>>         buildable for multiple targets (that sounds more like
>>         compiler-rt). On the other hand it's not a perfect fit for
>>         compiler-rt: it shares data structures with LLVM, and it
>>         would be very useful to be able to re-use llvm::Error  /
>>         llvm::Expected (that sounds like LLVM). At the moment I think
>>         the best way to square things would be to keep it in
>>         compiler-rt, allow inclusion of header-only code from LLVM in
>>         compiler-rt, and then make Error / Expected header-only (or
>>         copy / adapt them for this library). This will be a
>>         discussion for llvm-dev at some point in the near future.
>>
>>         On to the actual functionality though: The prototype makes
>>         significant changes to the MachOPlatform class and introduces
>>         an ORC runtime library in compiler-rt/lib/orc. Together,
>>         these changes allow us to emulate the dlopen / dlsym /
>>         dlclose in the JIT executor process. We can use this to
>>         define what it means to run a /JIT program/, rather than just
>>         running a JIT function (the way
>>         TargetProcessControl::runAsMain does):
>>
>>        
ORC_RT_INTERFACE int64_t __orc_rt_macho_run_program(int argc, char *argv[])
>>         {
>>           using MainTy = int (*)(int, char *[]);
>>
>>           void *H = __orc_rt_macho_jit_dlopen("Main",
ORC_RT_RTLD_LAZY);
>>           if (!H) {
>>             __orc_rt_log_error(__orc_rt_macho_jit_dlerror());
>>             return -1;
>>           }
>>
>>        
  auto *Main = reinterpret_cast<MainTy>(__orc_rt_macho_jit_dlsym(H, "main"));
>>           if (!Main) {
>>             __orc_rt_log_error(__orc_rt_macho_jit_dlerror());
>>             return -1;
>>           }
>>
>>           int Result = Main(argc, argv);
>>
>>           if (__orc_rt_macho_jit_dlclose(H) == -1)
>>             __orc_rt_log_error(__orc_rt_macho_jit_dlerror());
>>
>>           return Result;
>>         }
>>
>>         The
>>         functions __orc_rt_macho_jit_dlopen, __orc_rt_macho_jit_dlsym,
>>         and __orc_rt_macho_jit_dlclose behave the same as their
>>         dlfcn.h counterparts (dlopen, dlsym, dlclose), but operate on
>>         JITDylibs rather than regular dylibs. This includes running
>>         static initializers and registering with language runtimes
>>         (e.g. ObjC).
>>
>>         While we could run static initializers before (e.g. via
>>         LLJIT::runConstructors), we had to initiate this from the JIT
>>         process side, which has two significant drawbacks: (1) Extra
>>         RPC round trips, and (2) in the out-of-process case:
>>         initializers not running on the executor thread that
>>         requested them, since that thread will be blocked waiting for
>>         its call to return. Issue (1) only affects performance, but
>>         (2) can affect correctness if the initializers modify thread
>>         local values, or interact with locks or threads. Interacting
>>         with threads from initializers is generally best avoided, but
>>         nonetheless is done by real-world code, so we want to support
>>         it. By using the runtime we can improve both performance and
>>         correctness (or at least consistency with current behavior). 
>>
>>         The effect of this is that we can now load C++, Objective-C
>>         and Swift programs in the JIT and expect them to run
>>         correctly, at least for simple cases. This works regardless
>>         of whether the JIT'd code runs in-process or
out-of-process.
>>         To test all this I have integrated support for the prototype
>>         runtime into llvm-jitlink. You can demo output from this tool
>>         below for two simple input programs: One swift, one C++. All
>>         of this is MachO specific at the moment, but provides a
>>         template that could be easily re-used to support this on ELF
>>         platforms, and likely on COFF platforms too.
>>
>>         While the discussion on where the runtime should live plays
>>         out I will continue adding / moving functionality to the
>>         prototype runtime. Next up will be eh-frame registration and
>>         resolver functions (both currently in OrcTargetProcess).
>>         After that I'll try to tackle support for native MachO
thread
>>         local storage.
>>
>>         As always: Questions and comments are very welcome.
>>
>>         -- Lang.
>>
>>         lhames at Langs-MacBook-Pro scratch % cat foo.swift
>>         class MyClass {
>>           func foo() {
>>             print("foo")
>>           }
>>         }
>>
>>         let m = MyClass()
>>         m.foo();
>>
>>         lhames at Langs-MacBook-Pro scratch % xcrun swiftc -emit-object
>>         -o foo.o foo.swift                                    
>>         lhames at Langs-MacBook-Pro scratch % llvm-jitlink -dlopen
>>         /usr/lib/swift/libswiftCore.dylib foo.o              
>>         foo
>>         lhames at Langs-MacBook-Pro scratch % llvm-jitlink
-oop-executor
>>         -dlopen /usr/lib/swift/libswiftCore.dylib foo.o
>>         foo
>>         lhames at Langs-MacBook-Pro scratch % cat inits.cpp 
>>         #include <iostream>
>>
>>         class Foo {
>>         public:
>>           Foo() { std::cout << "Foo::Foo()\n"; }
>>           ~Foo() { std::cout << "Foo::~Foo()\n"; }
>>           void foo() { std::cout << "Foo::foo()\n"; }
>>         };
>>
>>         Foo F;
>>
>>         int main(int argc, char *argv[]) {
>>           F.foo();
>>           return 0;
>>         }
>>         lhames at Langs-MacBook-Pro scratch % xcrun clang++ -c -o
>>         inits.o inits.cpp
>>         lhames at Langs-MacBook-Pro scratch % llvm-jitlink inits.o    
 
>>                                                        
>>         Foo::Foo()
>>         Foo::foo()
>>         Foo::~Foo()
>>         lhames at Langs-MacBook-Pro scratch % llvm-jitlink
-oop-executor
>>         inits.o
>>         Foo::Foo()
>>         Foo::foo()
>>         Foo::~Foo()
>
>         -- 
>         https://flowcrypt.com/pub/stefan.graenitz at gmail.com
<https://flowcrypt.com/pub/stefan.graenitz at gmail.com>
>
-- 
https://flowcrypt.com/pub/stefan.graenitz at gmail.com

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