This patch makes the parser
- reject higher vector registers (>=16) in operands where they should not
be accepted.
- accept higher integers (>=16) in vector register operands.
Review: Ulrich Weigand
Differential Revision: https://reviews.llvm.org/D88888
Support VRI, VRR, VRS, VRV, VRX, VSI instruction formats with the .insn
directive.
Review: Ulrich Weigand
Differential Revision: https://reviews.llvm.org/D88357
Revision e1de2773a5 provided support for
accepting integer registers in inline asm i.e.
__asm("lhi %r0, 5") -> lhi %r0, 5
__asm("lhi 0, 5") -> lhi 0,5
This patch aims to extend this support to instructions which compute
addresses as well. (i.e instructions of type BDMem and BD[X|R|V|L]Mem)
Author: anirudhp
Differential Revision: https://reviews.llvm.org/D83251
For compatibility with other assemblers on the platform, allow
using just plain integer register numbers in all places where a
register operand is expected.
Bug: llvm.org/PR45582
Registers used in any address (as well as in a few other contexts)
have special semantics when a "zero" register is used, which is
why the back-end defines extra register classes ADDR32, ADDR64 etc
to be used to prevent the register allocator from using %r0 there.
However, when writing assembler code "by hand", you sometimes need
to trigger that special semantics. However, currently the AsmParser
will reject %r0 in those places. In some cases it may be possible
to write that instruction differently - but in others it is currently
not possible at all.
This check in AsmParser simply seems overly strict, so this patch
just removes the check completely. This brings the behaviour of
AsmParser in line with the GNU assembler as well.
Bugzilla: https://bugs.llvm.org/show_bug.cgi?id=45092
The new behavior matches GNU objdump. A pair of angle brackets makes tests slightly easier.
`.foo:` is not unique and thus cannot be used in a `CHECK-LABEL:` directive.
Without `-LABEL`, the CHECK line can match the `Disassembly of section`
line and causes the next `CHECK-NEXT:` to fail.
```
Disassembly of section .foo:
0000000000001634 .foo:
```
Bdragon: <> has metalinguistic connotation. it just "feels right"
Reviewed By: rupprecht
Differential Revision: https://reviews.llvm.org/D75713
Demand that an immediate offset to a PC relative address fits in 32 bits, or
else load it into a register and perform a separate add.
Verify in the assembler that such immediate offsets fit the bitwidth.
Even though the final address of a Load Address Relative Long may fit in 32
bits even with a >32 bit offset (depending on where the symbol lives relative
to PC), the GNU toolchain demands the offset by itself to be in range. This
patch adapts the same behavior for llvm.
Review: Ulrich Weigand
https://reviews.llvm.org/D69749
The recently announced IBM z15 processor implements the architecture
already supported as "arch13" in LLVM. This patch adds support for
"z15" as an alternate architecture name for arch13.
The patch also uses z15 in a number of places where we used arch13
as long as the official name was not yet announced.
llvm-svn: 372435
This patch series adds support for the next-generation arch13
CPU architecture to the SystemZ backend.
This includes:
- Basic support for the new processor and its features.
- Assembler/disassembler support for new instructions.
- CodeGen for new instructions, including new LLVM intrinsics.
- Scheduler description for the new processor.
- Detection of arch13 as host processor.
Note: No currently available Z system supports the arch13
architecture. Once new systems become available, the
official system name will be added as supported -march name.
llvm-svn: 365932
Vector load/store instructions support an optional alignment field
that the compiler can use to provide known alignment info to the
hardware. If the field is used (and the information is correct),
the hardware may be able (on some models) to perform faster memory
accesses than otherwise.
This patch adds support for alignment hints in the assembler and
disassembler, and fills in known alignment during codegen.
llvm-svn: 363806
We use both -long-option and --long-option in tests. Switch to --long-option for consistency.
In the "llvm-readelf" mode, -long-option is discouraged as it conflicts with grouped short options and it is not accepted by GNU readelf.
While updating the tests, change llvm-readobj -s to llvm-readobj -S to reduce confusion ("s" is --section-headers in llvm-readobj but --symbols in llvm-readelf).
llvm-svn: 359649
SystemZAsmParser can now handle -debug by printing the operands neatly to the
output stream. Before this patch this lead to an llvm_unreachable().
It seems that now '-mllvm -debug' does not cause any crashes anywhere (at
least not on SPEC).
Review: Ulrich Weigand
https://reviews.llvm.org/D53328
llvm-svn: 345349
This adds support for the new 128-bit vector float instructions of z14.
Note that these instructions actually only operate on the f128 type,
since only each 128-bit vector register can hold only one 128-bit
float value. However, this is still preferable to the legacy 128-bit
float instructions, since those operate on pairs of floating-point
registers (so we can hold at most 8 values in registers), while the
new instructions use single vector registers (so we hold up to 32
value in registers).
Adding support includes:
- Enabling the instructions for the assembler/disassembler.
- CodeGen for the instructions. This includes allocating the f128
type now to the VR128BitRegClass instead of FP128BitRegClass.
- Scheduler description support for the instructions.
Note that for a small number of operations, we have no new vector
instructions (like integer <-> 128-bit float conversions), and so
we use the legacy instruction and then reformat the operand
(i.e. copy between a pair of floating-point registers and a
vector register).
llvm-svn: 308196
This adds support for the new 32-bit vector float instructions of z14.
This includes:
- Enabling the instructions for the assembler/disassembler.
- CodeGen for the instructions, including new LLVM intrinsics.
- Scheduler description support for the instructions.
- Update to the vector cost function calculations.
In general, CodeGen support for the new v4f32 instructions closely
matches support for the existing v2f64 instructions.
llvm-svn: 308195
This patch series adds support for the IBM z14 processor. This part includes:
- Basic support for the new processor and its features.
- Support for new instructions (except vector 32-bit float and 128-bit float).
- CodeGen for new instructions, including new LLVM intrinsics.
- Scheduler description for the new processor.
- Detection of z14 as host processor.
Support for the new 32-bit vector float and 128-bit vector float
instructions is provided by separate patches.
llvm-svn: 308194
This adds all remaining instructions that were still missing, mostly
privileged and semi-privileged system-level instructions. These are
provided for use with the assembler and disassembler only.
This brings the LLVM assembler / disassembler to parity with the
GNU binutils tools.
llvm-svn: 306876
There are a few instructions provided by the high-word facility (z196)
that we cannot easily exploit for code generation. This patch at least
adds those missing instructions for the assembler and disassembler.
This means that now all nonprivileged instructions up to z13 are
supported by the LLVM assembler / disassembler.
llvm-svn: 306821
This adds assembler / disassembler support for the decimal
floating-point instructions. Since LLVM does not yet have
support for decimal float types, these cannot be used for
codegen at this point.
llvm-svn: 304203
This adds assembler / disassembler support for the hexadecimal
floating-point instructions. Since the Linux ABI does not use
any hex float data types, these are not useful for codegen.
llvm-svn: 304202
This adds a few missing instructions for the assembler and
disassembler. Those should be the last missing general-
purpose (Chapter 7) instructions for the z10 ISA.
llvm-svn: 302667
This adds the remaining general arithmetic instructions
for assembler / disassembler use. Most of these are not
useful for codegen; a few might be, and those are listed
in the README.txt for future improvements.
llvm-svn: 302665
The assembler and disassmebler test cases started out formatted and
sorted in a particular way, but this got lost over time as patches
were added. Reformat them again. NFC.
llvm-svn: 302642
Add assembler support for all atomic instructions that weren't already
supported. Some of those could be used to implement codegen for 128-bit
atomic operations, but this isn't done here yet.
llvm-svn: 288526
Add assembler support for instructions manipulating the FPC.
Also add codegen support via the GCC compatibility builtins:
__builtin_s390_sfpc
__builtin_s390_efpc
llvm-svn: 288525
This adds assembler support for the instructions provided by the
execution-hint facility (NIAI and BP(R)P). This required adding
support for the new relocation types for 12-bit and 24-bit PC-
relative offsets used by the BP(R)P instructions.
llvm-svn: 288031
This patch adds assembler support for the remaining branch instructions:
the non-relative branch on count variants, and all variants of branch
on index.
The only one of those that can be readily exploited for code generation
is BRCTH (branch on count using a high 32-bit register as count). Do
use it, however, it is necessary to also introduce a hew CHIMux pseudo
to allow comparisons of a 32-bit value agains a short immediate to go
into a high register as well (implemented via CHI/CIH).
This causes a bit of codegen changes overall, but those have proven to
be neutral (or even beneficial) in performance measurements.
llvm-svn: 288029
This patch moves formation of LOC-type instructions from (late)
IfConversion to the early if-conversion pass, and in some cases
additionally creates them directly from select instructions
during DAG instruction selection.
To make early if-conversion work, the patch implements the
canInsertSelect / insertSelect callbacks. It also implements
the commuteInstructionImpl and FoldImmediate callbacks to
enable generation of the full range of LOC instructions.
Finally, the patch adds support for all instructions of the
load-store-on-condition-2 facility, which allows using LOC
instructions also for high registers.
Due to the use of the GRX32 register class to enable high registers,
we now also have to handle the cases where there are still no single
hardware instructions (conditional move from a low register to a high
register or vice versa). These are converted back to a branch sequence
after register allocation. Since the expandRAPseudos callback is not
allowed to create new basic blocks, this requires a simple new pass,
modelled after the ARM/AArch64 ExpandPseudos pass.
Overall, this patch causes significantly more LOC-type instructions
to be used, and results in a measurable performance improvement.
llvm-svn: 288028
This adds support for the compare logical and trap (memory)
instructions that were added as part of the miscellaneous
instruction extensions feature with zEC12.
llvm-svn: 286587
This adds support for the LZRF/LZRG/LLZRGF instructions that were
added on z13, and uses them for code generation were appropriate.
SystemZDAGToDAGISel::tryRISBGZero is updated again to prefer LLZRGF
over RISBG where both would be possible.
llvm-svn: 286586
This adds support for the 31-to-64-bit zero extension instructions
LLGT and LLGTR and uses them for code generation where appropriate.
Since this operation can also be performed via RISBG, we have to
update SystemZDAGToDAGISel::tryRISBGZero so that we prefer LLGT
over RISBG in case both are possible. The patch includes some
simplification to the tryRISBGZero code; this is not intended
to cause any (further) functional change in codegen.
llvm-svn: 286585
This completes assembler / disassembler support for all BFP
instructions provided by the floating-point extensions facility.
The instructions added here are not currently used for codegen.
llvm-svn: 286285
Add several instructions that operate on the program mask
or the addressing mode. These are not really needed for
code generation under Linux, but are provided for completeness
for the assembler/disassembler.
llvm-svn: 286284
Add the 16 access registers as LLVM registers. This allows removing
a lot of special cases in the assembler and disassembler where we
were handling access registers; this can all just use the generic
register code now.
Also add a bunch of instructions to operate on access registers,
for assembler/disassembler use only. No change in code generation
intended.
llvm-svn: 286283
Rework patterns for branches, call & return instructions,
compare-and-branch, compare-and-trap, and conditional move
instructions.
In particular, simplify creation of patterns for the extended
opcodes of instructions that take a CC mask.
Also, use semantical instruction classes for all the instructions
instead of open-coding them in SystemZInstrInfo.td.
Adds a couple of the basic branch instructions (that are unused
for codegen) for the assembler/disassembler.
llvm-svn: 286263
This patch implements two changes:
- Move processor feature definition into a new file SystemZFeatures.td,
and provide explicit lists of supported and unsupported features for
each level of the z/Architecture. This allows specifying unsupported
features in the scheduler definition files for each processor.
- Add optional aliases for the -mcpu processor names according to the
level of the z/Architecture, for compatibility with other compilers
on the platform. The supported aliases are:
-mcpu=arch8 equals -mcpu=z10
-mcpu=arch9 equals -mcpu=z196
-mcpu=arch10 equals -mcpu=zEC12
-mcpu=arch11 equals -mcpu=z13
llvm-svn: 285577
Currently, when using an instruction that is not supported on the
currently selected architecture, the LLVM assembler is likely to
diagnose an "invalid operand" instead of a "missing feature".
This is because many operands require a custom parser in order to
be processed correctly, and if an instruction is not available
according to the current feature set, the generated parser code
will also not detect the associated custom operand parsers.
Fixed by temporarily enabling all features while parsing operands.
The missing features will then be correctly detected when actually
parsing the instruction itself.
llvm-svn: 285575
LLVM currently treats the first operand of MVCK as if it were a
regular base+index+displacement address. However, it is in fact
a base+displacement combined with a length register field.
While the two might look syntactically similar, there are two
semantic differences:
- %r0 is a valid length register, even though it cannot be used
as an index register.
- In an expression with just a single register like 0(%rX), the
register is treated as base with normal addresses, while it is
treated as the length register (with an empty base) for MVCK.
Fixed by adding a new operand parser class BDRAddr and reworking
the assembler parser to distinguish between address + length
register operands and regular addresses.
llvm-svn: 285574
Most z13 vector instructions have a base form where the data type of
the operation (whether to consider the vector to be 16 bytes, 8
halfwords, 4 words, or 2 doublewords) is encoded into a mask field,
and then a set of extended mnemonics where the mask field is not
present but the data type is encoded into the mnemonic name.
Currently, LLVM only supports the type-specific forms (since those
are really the ones needed for code generation), but not the base
type-generic forms.
To complete the assembler support and make it fully compatible with
the GNU assembler, this commit adds assembler aliases for all the
base forms of the various vector instructions.
It also adds two more alias forms that are documented in the PoP:
VFPSO/VFPSODB/WFPSODB -- generic form of VFLCDB etc.
VNOT -- special variant of VNO
llvm-svn: 284586
The vfee[bhf], vfene[bhf], and vistr[bhf] assembler mnemonics are
documented in the Principles of Operation to have an optional last
operand to encode arbitrary values in a mask field.
This commit adds support for those optional operands, and cleans up
the patterns to generate vector string instruction as bit. No change
to code generation intended.
llvm-svn: 284585
Summary:
Add support for the .insn directive.
.insn is an s390 specific directive that allows encoding of an instruction
instead of using a mnemonic. The motivating case is some code in node.js that
requires support for the .insn directive.
Reviewers: koriakin, uweigand
Subscribers: koriakin, llvm-commits
Differential Revision: https://reviews.llvm.org/D21809
llvm-svn: 278012
Jonas Paulsson