When an instruction doesn't have a valid encoding for the target ISA, it
needs to be legalized. Different legalization strategies can be
expressed as separate XFormGroup objects.
Make the choice of XFormGroup configurable per CPU mode, rather than
depending on a hard-coded default.
Add a CPUMode.legalize_type() method which assigns an XFormGroup to
controlling type variables and lets you set a default.
Add a `legalize` field to Level1Entry so the first-level hash table
lookup gives us the configured default legalization action for the
instruction's controlling type variable.
The encoding tables contain references to numbered ISA predicates.
- Give the ISA Flags types a predicate_view() method which returns a
PredicateView.
- Delete the old predicate_bytes() method which returned a raw &[u8].
- Use a 'static lifetime for the encoding list slice in the Encodings
iterator, and a single 'a lifetime for everything else.
ARM has all of these as scalar integer instructions. Intel has band_not
in SSE and as a scalar in BMI1.
Add the trivial legalization patterns that use a bnot instruction.
These map to single Intel instructions.
The i64 to float conversions are not tested yet. The encoding tables
can't yet differentiate instructions on a secondary type variable alone.
This instruction returns a `b1` value which is represented as the output
of a setCC instruction which is the low 8 bits of a GPR register. Use a
cmp+setCC macro recipe to encode this. That is not ideal, but we can't
represent CPU flags yet.
A fallthrough jump is actually represented as 0 bytes, so no encoding is
needed.
Also allow for unencoded instructions in the generated emit_inst
implementations. The verifier has stricter rules for when this is
allowed.
Register locations can change throughout an EBB. Make sure the
emit_inst() function considers this when encoding instructions and
update the register diversion tracker.
Add instructions representing Intel's division instructions which use a
numerator that is twice as wide as the denominator and produce both the
quotient and remainder.
Add encodings for the x86_[su]divmodx instructions.
Fixes#11.
Presets are groups of settings and values applied at once. This is used
as a shorthand in test files, so for example "isa intel nehalem" enables
all of the CPUID bits that the Nehalem micro-architecture provides.
Change the result type for the bit-counting instructions from a fixed i8
to the iB type variable which is the type of the input. This matches the
convention in WebAssembly, and at least Intel's instructions will set a
full register's worth of count result, even if it is always < 64.
Duplicate the Intel 'ur' encoding recipe into 'umr' and 'urm' variants
corresponding to the RM and MR encoding variants. The difference is
which register is encoded as 'reg' and which is 'r/m' in the ModR/M
byte. A 'mov' register copy uses the MR variant, a unary popcnt uses the
RM variant.
* Reduce code duplication in TypeConstraint subclasses; Add ConstrainWiderOrEqual to ti and to ireduce,{s,u}extend and f{promote,demote}; Fix bug in emitting constraint edges in TypeEnv.dot(); Modify runtime constraint checks to reject match when they encounter overflow
* Rename Constrain types to something shorter; Move lane_bits/lane_counts in subclasses of ValueType; Add wider_or_eq function in rust and python;
Add a TailRecipe.rex() method which creates an encoding recipe with a
REX prefix.
Define I64 encodings with REX.W for i64 operations and with/without REX
for i32 ops. Only test the with-REX encodings for now. We don't yet have
an instruction shrinking pass that can select the non-REX encodings.
Use a PUT_OP macro in the TailRecipe Python class to replace the code
snippet that emits the prefixes + opcode part of the instruction encoding.
Prepare for the addition of REX prefixes by giving the PUT_OP functions
a third argument representing the REX prefix. For the non-REX encodings,
verify that no REX bits wold be needed.
Generate code to:
- Unwrap the instruction and generate an error if the instruction format
doesn't match the recipe.
- Look up the value locations of register and stack arguments.
The recipe_* functions in the ISA binemit modules now take these
unwrapped items as arguments.
Also add an optional `emit` argument to the EncRecipe constructor which
makes it possible to provide inline Rust code snippets for code
emission. This requires a lot less boilerplate than recipe_* functions.
As per the comment in TypeEnv.normalize_tv about cancellation, whenever we create a TypeVar we must assert that there is no under/overflow. To make sure this always happen move the safety checks to TypeVar.derived() from the other helper methods
* Add more rigorous type inference and encapsulate the type inferece code in its own file (ti.py).
Add constraints accumulation during type inference, to represent constraints that cannot be expressed
using bijective derivation functions between typevars.
Add testing for new type inference code.
* Additional annotations to appease mypy
* Convert TypeSet fields to sets; Add BitSet<T> type to rust; Encode ValueTypeSets using BitSet; (still need mypy cleanup)
* nits
* cleanup nits
* forgot mypy type annotations
* rustfmt fixes
* Round 1 comments: filer b2, b4; doc comments in python; move bitset in its own toplevel module; Use Into<u32>
* fixes
* Revert comment to appease rustfmt
* Clarify that extended basic blocks are abbreviated as EBB.
* Fix typo.
* Fix a typo.
* Fix typos.
* Use the same phrase to indicate scalar-only as other places in the doc.
* Mention that `band_imm` and friends are scalar-only.
And mention that they're equivalent to their respective
non-immediate-form counterparts.
* Implement an iterator over encodings
* Implement TargetIsa::legal_encodings
* Exclude non-boolean settings of isa flags bytes
* Address flake8 long line error
