Instead, create a mul24 with a 64 bit result and let ISel take care of
it.
This allows patterns to simply match mul24 even for 64-bit muls instead of having to match both mul/mulhi and a buildvector/bitconvert/etc.
The @llvm.amdgcn.cs.chain intrinsic is essentially a call. The call
parameters are bundled up into 2 intrinsic arguments, one for those that
should go in the SGPRs (the 3rd intrinsic argument), and one for those
that should go in the VGPRs (the 4th intrinsic argument). Both will
often be some kind of aggregate.
Both instruction selection frameworks have some internal representation
for intrinsics (G_INTRINSIC[_WITH_SIDE_EFFECTS] for GlobalISel,
ISD::INTRINSIC_[VOID|WITH_CHAIN] for DAGISel), but we can't use those
because aggregates are dissolved very early on during ISel and we'd lose
the inreg information. Therefore, this patch shortcircuits both the
IRTranslator and SelectionDAGBuilder to lower this intrinsic as a call
from the very start. It tries to use the existing infrastructure as much
as possible, by calling into the code for lowering tail calls.
This has already gone through a few rounds of review in Phab:
Differential Revision: https://reviews.llvm.org/D153761
We previously directly codegened to v_log_f32, which is broken for
denormals. The lowering isn't complicated, you simply need to scale
denormal inputs and adjust the result. Note log and log10 are still
not accurate enough, and will be fixed separately.
Provide direct access to v_exp_f32 and v_exp_f16, so we can start
correctly lowering the generic exp intrinsics.
Unfortunately have to break from the usual naming convention of
matching the instruction name and stripping the v_ prefix. exp is
already taken by the export intrinsic. On the clang builtin side, we
have a choice of maintaining the convention to the instruction name,
or following the intrinsic name.
This will map directly to the hardware instruction which does not
handle denormals for f32. This will allow moving the generic intrinsic
to be lowered correctly. Also handles selecting the f16 version, but
there's no reason to use it over the generic intrinsic.
This was inserting an s_endpgm in the middle of the block when it has
to be a terminator. Split the block and insert a branch to a new block
with the trap if it's not in a terminator position.
Fixes verifier error on LDS in function with no trap support (and
other trap sources).
AMDGPU has native instructions and target intrinsics for this, but
these really should be subject to legalization and generic
optimizations. This will enable legalization of f16->f32 on targets
without f16 support.
Implement a somewhat horrible inline expansion for targets without
libcall support. This could be better if we could introduce control
flow (GlobalISel version not yet implemented). Support for strictfp
legalization is less complete but works for the simple cases.
Summary:
Registers for tail call return should not be clobbered by callee.
So we need a sub-class of SGPR_64 (excluding callee saved registers (CSR)) to hold
the tail call return address.
Because GFX and C calling conventions have different CSR, we need to define
the sub-class separately. This work is an extension of D147096 with the
consideration of GFX calling convention.
Based on the calling conventions, different instructions will be selected with
different sub-class of SGPR_64 as the input.
Reviewers: arsenm, cdevadas and sebastian-ne
Differential Revision: https://reviews.llvm.org/D148824
class support and introduce GlobalISel implementation for AMDGPU
Uses existing SelectionDAG lowering of the llvm.amdgcn.class intrinsic
for llvm.is.fpclass
Currently the return address ABI registers s[30:31], which fall in the call
clobbered register range, are added as a live-in on the function entry to
preserve its value when we have calls so that it gets saved and restored
around the calls.
But the DWARF unwind information (CFI) needs to track where the return address
resides in a frame and the above approach makes it difficult to track the
return address when the CFI information is emitted during the frame lowering,
due to the involvment of understanding the control flow.
This patch moves the return address ABI registers s[30:31] into callee saved
registers range and stops adding live-in for return address registers, so that
the CFI machinery will know where the return address resides when CSR
save/restore happen during the frame lowering.
And doing the above poses an issue that now the return instruction uses undefined
register `sgpr30_sgpr31`. This is resolved by hiding the return address register
use by the return instruction through the `SI_RETURN` pseudo instruction, which
doesn't take any input operands, until the `SI_RETURN` pseudo gets lowered to the
`S_SETPC_B64_return` during the `expandPostRAPseudo()`.
As an added benefit, this patch simplifies overall return instruction handling.
Note: The AMDGPU CFI changes are there only in the downstream code and another
version of this patch will be posted for review for the downstream code.
Reviewed By: arsenm, ronlieb
Differential Revision: https://reviews.llvm.org/D114652
Currently the return address ABI registers s[30:31], which fall in the call
clobbered register range, are added as a live-in on the function entry to
preserve its value when we have calls so that it gets saved and restored
around the calls.
But the DWARF unwind information (CFI) needs to track where the return address
resides in a frame and the above approach makes it difficult to track the
return address when the CFI information is emitted during the frame lowering,
due to the involvment of understanding the control flow.
This patch moves the return address ABI registers s[30:31] into callee saved
registers range and stops adding live-in for return address registers, so that
the CFI machinery will know where the return address resides when CSR
save/restore happen during the frame lowering.
And doing the above poses an issue that now the return instruction uses undefined
register `sgpr30_sgpr31`. This is resolved by hiding the return address register
use by the return instruction through the `SI_RETURN` pseudo instruction, which
doesn't take any input operands, until the `SI_RETURN` pseudo gets lowered to the
`S_SETPC_B64_return` during the `expandPostRAPseudo()`.
As an added benefit, this patch simplifies overall return instruction handling.
Note: The AMDGPU CFI changes are there only in the downstream code and another
version of this patch will be posted for review for the downstream code.
Reviewed By: arsenm
Differential Revision: https://reviews.llvm.org/D114652
This patch changes the AMDGPU_Gfx calling convention. It defines the SGPR registers s[4:29] as callee-save and leaves some SGPRs usable for callers. The intention is to avoid unneccessary s_mov instructions for arguments the caller would otherwise save and restore in these registers.
Reviewed By: sebastian-ne
Differential Revision: https://reviews.llvm.org/D111637
These intrinsics maps to the 24-bit v_mul_hi instructions.
This change also fixes an incorrect assumption on the associativity of
24-bit mulhi in its SDNode record in tblgen.
Differential Revision: https://reviews.llvm.org/D112394
1. Splitted out some parts of R600 target to separate modules/headers.
2. Reduced some include lists in headers.
3. Found and fixed issue with override `GCNTargetMachine::getSubtargetImpl()`
and `R600TargetMachine::getSubtargetImpl()` had different return value type
than base class.
4. Minor forward declarations cleanup.
Reviewed By: foad
Differential Revision: https://reviews.llvm.org/D108596
When running the tests on PowerPC and x86, the lit test GlobalISel/trunc.ll fails at the memory sanitize step. This seems to be due to wrong invalid logic (which matches even if it shouldn't) and likely missing variable initialisation."
Reviewed By: arsenm
Differential Revision: https://reviews.llvm.org/D95878
This reverts commits 62af0305b7cc..677a3529d3e6 from D93708.
They cause failures in the sanitizer builds because of uninitialized
values.
A fix is in D95878, but it might take some time until this is pushed,
so reverting the changes for now.
Try to handle arbitrary scalar BFEs by packing the operands. The DAG
gives up on non-constant arguments. We're still missing any constant
folding, so we end up with pretty ugly code most of the time. Also
handle the 64-bit scalar case, which the DAG doesn't try to do.
Manually select this is as a tablegen workraound. Both SelectionDAG
and GlobalISel end up misplacing the copy to m0 when both instructions
in the output need it. Neither considers that both output instructions
depend on m0. I don't know of any other pattern we need to handle this
case, so it's less effort to just workaround this for now.
I'm mildly worried about potentially reordering exp/exp_done with
IntrWriteMem on the intrinsic.
Requires hacking out the illegal type on SI, so manually select that
case during lowering.
This enables GlobalISel to handle various intrinsics. The custom node
pattern will be ignored, and the intrinsic will work. This will also
allow SelectionDAG to directly select the intrinsics, but as they are
all custom lowered to the nodes, this ends up leaving dead code in the
table.
Eventually either GlobalISel should add the equivalent of custom nodes
equivalent, or intrinsics should be directly used. These each have
different tradeoffs.
There are a few more to handle, but these are easy to handle
ones. Some others fail for other reasons.
llvm-svn: 371432
