Change codegen of LLVM intrinsics to be name-based, and add llvm linkage support for bf16(xN), i1xN and x86amx
#140763
Conversation
rustbot
added
S-waiting-on-review
|
Some changes occurred in compiler/rustc_codegen_ssa |
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
|
Some changes occurred in compiler/rustc_codegen_gcc |
This comment has been minimized.
This comment has been minimized.
sayantn
changed the title
x86amx for i32x256 for AMX intrinsics
sayantn
changed the title
x86amx for i32x256 for AMX intrinsicsx86amx and i32x256 for AMX intrinsics
This comment has been minimized.
This comment has been minimized.
|
I think you can use |
|
That can be used to improve performance, I am not really focusing on performance in this PR. I want to currently emphasize the correctness of the codegen. |
|
Oh wait, I probably misunderstood your comment, you meant using the llvm declaration by itself. Yeah, that would be better, thanks for the info. I will update the impl when I get the chance |
I think you can just focus on non-overloaded functions for this PR. Overloaded functions and type checking that checking Rust function signatures using LLVM defined can be subsequent PRs. @rustbot author |
rustbot
added
S-waiting-on-author
|
Reminder, once the PR becomes ready for a review, use |
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
|
@sayantn Taking the address of an intrinsic is invalid LLVM IR. |
|
As @workingjubilee suggested I will split this PR into 2, this will only add bypasses for |
sayantn
changed the title
x86amx, bf16(xN) and i1xNbf16(xN) and i1xN
| TypeKind::Struct if self.type_kind(rust_ty) == TypeKind::Struct => { | ||
| let rust_element_tys = self.struct_element_types(rust_ty); | ||
| let llvm_element_tys = self.struct_element_types(llvm_ty); | ||
|
|
||
| if rust_element_tys.len() != llvm_element_tys.len() { | ||
| return false; | ||
| } | ||
|
|
||
| iter::zip(rust_element_tys, llvm_element_tys).all( | ||
| |(rust_element_ty, llvm_element_ty)| { | ||
| self.equate_ty(rust_element_ty, llvm_element_ty) | ||
| }, | ||
| ) | ||
| } |
There was a problem hiding this comment.
a little more context for why we destructure structs - LLVM typically returns literal non-packed structs. So to match them, Rust code often uses repr(packed) structs. LLVM autoupgrade understands that there is no functional difference between {T, U} and <{T, U}>, and auto-injects some destructurings. But as here we are trying to match the types exactly, it would error as packed structs are not "equal" to non-packed ones. Moreover there is no Rust-native way to creating non-packed LLVM structs with the exact fields we want (in general), because Rust might add extra fields to ensure alignment. Which leaves us with the only option being packed structs, which requires this workaround.
It would have been nice if LLVM offered some way to "pack"/"un-pack" structs, i.e. convert between <{T, U}> and {T, U}, but as it doesn't, we have no way other than simply destructure and restructure them (which is, kinda good actually, as it lets us make these autocasts "deep"
| let name = llvm::get_value_name(llfn); | ||
| if name.starts_with(b"llvm.") | ||
| && let Some(intrinsic) = llvm::Intrinsic::lookup(name) | ||
| { | ||
| // FIXME: also do this for overloaded intrinsics | ||
| if !intrinsic.is_overloaded() { | ||
| return; | ||
| } | ||
| } |
There was a problem hiding this comment.
Do we need to add attributes even if the signature is getting AutoUpgraded (because at this point we can safely assume that the function is getting upgraded, we would have detected it earlier if it was invalid? I assume the sext/zext will matter if LLVM is autoupgrading i32 to i1x8 or sth, but cc @nikic to confirm. If they don't matter even for upgradable intrinsics, we can reduce this to just a name check
- Remove redundant bitcasts at callsite edit (squash with struct)
- Correct usage of invalid intrinsics in tests
sayantn
changed the title
bf16(xN) and i1xNbf16(xN), i1xN and x86amx
|
I added back the AMX casts, because I was able to separate the intrinsic changes. Some tests were also changed because of #141309 |
Simplify implementation of Rust intrinsics by using type parameters in the cache The current implementation of intrinsics have a lot of duplication to handle different overloads of overloaded LLVM intrinsic. This PR uses the **base name and the type parameters** in the cache instead of the full, overloaded name. This has the benefit that `call_intrinsic` doesn't need to provide the full name, rather the type parameters (which is most of the time more available). This uses `LLVMIntrinsicCopyOverloadedName2` to get the overloaded name from the base name and the type parameters, and only uses it to declare the function. (originally was part of #140763, split off later) `@rustbot` label A-codegen A-LLVM r? codegen
…error messages ss
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This comment has been minimized.
This PR changes how LLVM intrinsics are codegen
Explanation of the changes
Current procedure
This is the same for all functions, LLVM intrinsics are not treated specially
f32 (f32)due to the Rust signaturePros
Cons
-Zverify-llvm-irto it will fail compilation). I would expect this code to not compile at all instead of generating invalid IR.x86amxtype, and (almost) all intrinsics that have vectors ofi1types) can't be linked to at all. This is a (major?) roadblock in the AMX and AVX512 support in stdarch.-Zverify-llvm-irwon't complain. Eventually it will error out due to the non-existing function (courtesy of the linker). I don't think this is a behavior we want.What this PR does
LLVMIntrinsicGetTypeto directly get the function type of the intrinsic from LLVM.Note
This PR only focuses on non-overloaded intrinsics, overloaded can be done in a future PR
Regardless, the undermentioned functionalities work for all intrinsics
AutoUpgraded by LLVM. If not, that means it is an invalid intrinsic, and we error out.Pros
x86amxand injectingllvm.x86.cast.vector.to.tileandllvm.x86.cast.tile.to.vectors in callsite)Note
I don't intend for these bypasses to be permanent (at least the
bf16andi1ones, thex86amxbypass seems inevitable). A better approach will be introducing abf16type in Rust, and allowingrepr(simd)withbools to get Rust-nativei1xNs. These are meant to be short-time, as I mentioned, "bypass"es. They shouldn't cause any major breakage even if removed, aslink_llvm_intrinsicsis perma-unstable.This PR adds bypasses for
bf16(viai16),bf16xN(viai16xN),i1xN(viaiM, whereMis the smallest power of 2 s.t.M >= N, unlessN <= 4, where we useM = 8), andx86amx(via 8192-bit vectors). This will unblock AVX512-VP2INTERSECT, AMX and a lot of bf16 intrinsics in stdarch. This PR also automatically destructures structs if the types don't exactly match (this is required for us to start emitting hard errors on mismmatches).Cons
Possible ways to extend this to overloaded intrinsics (future)
Parse the mangled intrinsic name to get the type parameters
LLVM has a stable mangling of intrinsic names with type parameters (in
LLVMIntrinsicCopyOverloadedName2), so we can parse the name to get the type parameters, and then just do the same thing.Pros
Cons
TargetExttypes or identified structs, their name is a part of the mangling, making it impossible to reverse. Even more complexities arise when there are unnamed identified structs, as LLVM adds more mangling to the names.Use the
IITDescriptortable and the Rust function signatureWe can use the base name to get the
IITDescriptors of the corresponding intrinsic, and then manually implement the matching logic based on the Rust signature.Pros
TargetExttypes. Also, fun fact, Rust exports all struct types as literal structs (unless it is emitting LLVM IR, then it always uses named identified structs, with mangled names)Cons
llvm.sqrt.bf16until we havebf16types in Rust. Because if we are usingu16s (or any other type) asbf16s, then the matcher will deduce that the signature isu16 (u16)notbf16 (bf16)(which would lead to an error becauseu16is not a valid type parameter forllvm.sqrt), even though the intended type parameter is specified in the name.IITDescriptorKindsThese 2 approaches might give different results for same function. Let's take
The name-based approach will decide that the type parameter is
bf16, and the LLVM signature isi1 (bf16)and will inject some bitcasts at callsite.The
IITDescriptor-based approach will decide that the LLVM signature isi1 (u16), and will see that the name given doesn't match the expected name (llvm.is.constant.u16), and will error out.Other things that this PR does
unadjustedABI to facilitate the implementation of AMX (otherwise passing 8192-bit vectors to the intrinsic won't be allowed). This is "safe" because this ABI is only used to link to LLVM intrinsics, and passing vectors of any lengths to LLVM intrinsics is fine, because they don't exist in machine level.bitcasts incg_llvm/builder::check_call(now renamed ascast_argumentsdue to its new counterpartcast_return). This was old code from when Rust used to pass non-erased lifetimes to LLVM.Reviews are welcome, as this is my first time actually contributing to
rustcAfter CI is green, we would need a try build and a rustc-perf run.
@rustbot label T-compiler A-codegen A-LLVM
r? codegen