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.
Add a Stack() class for specifying operand constraints for values on the
stack.
Add encoding recipes for RISC-V spill and fill instructions. Don't
implement the encoding recipe functions yet since we don't have the
stack slot layout yet.
Two new pieces of information are available for all encoding recipes:
- The size in bytes of an encoded instruction, and
- The range of a branch encoded with the recipe, if any.
In the meta language, EncRecipe takes two new constructor arguments. The
size is required for all encodings and branch_range is required for all
recipes used to encode branches.
Not all br_icmp opcodes are present in the ISA. The missing ones can be
reached by commuting operands.
Don't attempt to encode EBB offsets yet. For now just emit an EBB
relocation for the branch instruction.
Allow some flexibility in the signature matching for instruction
formats. In particular, look for a value list format as a second chance
option.
The Return, ReturnReg, and TernaryOverflow formats all fit the single
MultiAry catch-all format for instructions without immediate operands.
Every encoding recipe must specify register constraints on input and
output values.
Generate recipe constraint tables along with the other encoding tables.
The 'lib/cretonne' directory will be the new root of a stand-alone
cretonne crate containg both Python and Rust sources.
This is in preparation for publishing crates on crates.io.
