This situation could be triggered that can_add_var would return true
while a variable was already added for the given register.
For instance, when we have a reassignment (because of a fixed register
input requirement) and a fixed input conflict on the same fixed
register, this register will not be available in the regs_in set after
inputs_done (because of the fixed input conflict diversion) but will
have its own variable.
Only the shifts with applicable SSE2 instructions are implemented here: PSRL* (for ushr) only has 16-64 bit instructions and PSRA* (for sshr) only has 16-32 bit instructions.
Previously, ConstantData was a type alias for `Vec<u8>` which prevented it from having an implementation; this meant that `V128Imm` and `&[u8; 16]` were used in places that otherwise could have accepted types of different byte lengths.
This avoids doing multiple unpacking of the InstructionData for a single
legalization, improving readability and reducing size of the generated
code. For instance, icmp had to unpack the format once per IntCC
condition code.
This adds a `DummyConstant` structure that is converted to something like `let const0 = pos.func.dfg.constants.insert(...)` in `gen_legalizer.rs`. This allows us to create constants during legalization with something like `let ones = constant(vec![0xff; 16])` and then use `ones` within a `def!` block, e.g.: `def!(a = vconst(ones))`. One unfortunate side-effect of this change is that, because the names of the constants in `ConstPool` are dynamic, the `VarPool` and `SymbolTable` structures that previously operated on `&'static str` types now must operate on `String` types; however, since this is a change to the meta code-generation, it should result in no runtime performance impact.
There are two reasons for this change:
1. it reduces confusion; using the `POR` encoding will match the future encodings of `band` and `bxor` and the `ORPS` encoding may be confusing as it is intended for floating-point operations
2. `POR` has slightly more throughput: it only has to wait 0.33 cycles to execute again on all Intel architectures above Core whereas `ORPS` must wait 1 cycle on architectures older than Skylake (Intel Optimization Reference Manual, C.3)
`POR` does add one additional byte to the encoding and requires SSE2 so the `ORPS` opcode is left in for future use.
This change should make the code more clear (and less code) when adding encodings for instructions with specific immediates; e.g., a constant with a 0 immediate could be encoded as an XOR with something like `const.bind(...)` without explicitly creating the necessary predicates. It has several parts:
* Introduce Bindable trait to instructions
* Convert all instruction bindings to use Bindable::bind()
* Add ability to bind immediates to BoundInstruction
This is an attempt to reduce some of the issues in #955.
Add legalizations for icmp and icmp_imm for i64 and i128 operands for
the narrow legalization set, allowing 32-bit ISAs (like x86-32) to
compare 64-bit integers and all ISAs to compare 128-bit integers.
Fixes: https://github.com/bnjbvr/cranelift-x86/issues/2
RedundantReloadRemover participates in the state-recycling machinery
implemented in cranelift-codegen/src/context.rs, whose goal it is to cache
per-pass state so it can be used for compilation of multiple functions without
reallocation. Unfortunately RedundantReloadRemover::run simply ignores the
cached state and reallocates it new for each function. This patch fixes that.
This reduces the number of malloc'd blocks by about 2%.
ReplaceBuilder is available in the public API through
`DataFlowGraph::replace`, however it's documentation is not available
through rustdoc as the type isn't publicly importable.
Only i16x8 and i32x4 are encoded in this commit mainly because i8x16 and i64x2 do not have simple encodings in x86. i64x2 is not required by the SIMD spec and there is discussion (https://github.com/WebAssembly/simd/pull/98#issuecomment-530092217) about removing i8x16.
The x86 ISA has (at least) two encodings for PEXTRW:
1. in the SSE2 opcode (66 0f c5) the XMM operand uses r/m and the GPR operand uses reg
2. in the SSE4.1 opcode (66 0f 3a 15) the XMM operand uses reg and the GPR operand uses r/m
This changes the 16-bit x86_pextr encoding from 1 to 2 to match the other PEXTR* implementations (all #2 style).
