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.
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
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
* 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
This is just a rough sketch to get us started. There are bound to be
some issues.
This also legalizes signatures for x86-32, but probably not correctly.
It's basically implementing the x86-64 ABI for 32-bit.
This is just a rough sketch to get us started. There are bound to be
some issues.
This also legalizes signatures for x86-32, but probably not correctly.
It's basically implementing the x86-64 ABI for 32-bit.
The following constraints may need to be resolved during spilling
because the resolution increases register pressure:
- A tied operand whose value is live through the instruction.
- A fixed register constraint for a value used more than once.
- A register use of a spilled value needs to account for the reload
register.
The following constraints may need to be resolved during spilling
because the resolution increases register pressure:
- A tied operand whose value is live through the instruction.
- A fixed register constraint for a value used more than once.
- A register use of a spilled value needs to account for the reload
register.
It is possible to pass a register value as an argument to an EBB that
expects a "None" affinity. In that case, the destination EBB value
should not be colored.
It is possible to pass a register value as an argument to an EBB that
expects a "None" affinity. In that case, the destination EBB value
should not be colored.
We'll need to pick a spill candidate from a set and allow for the search
to fail to find anything.
This also allows slightly better panic messages when we run out of
registers.
We'll need to pick a spill candidate from a set and allow for the search
to fail to find anything.
This also allows slightly better panic messages when we run out of
registers.
A priory, an EBB argument value only gets an affinity if it is used
directly by a non-ghost instruction. A use by a branch passing arguments
to an EBB doesn't count.
When an EBB argument value does have an affinity, the values passed by
all the predecessors must also have affinities. This can cause EBB
argument values to get affinities recursively.
- Add a second pass to the liveness computation for propagating EBB
argument affinities, possibly recursively.
- Verify EBB argument affinities correctly: A value passed to a branch
must have an affinity only if the corresponding EBB argument value in
the destination has an affinity.
A priory, an EBB argument value only gets an affinity if it is used
directly by a non-ghost instruction. A use by a branch passing arguments
to an EBB doesn't count.
When an EBB argument value does have an affinity, the values passed by
all the predecessors must also have affinities. This can cause EBB
argument values to get affinities recursively.
- Add a second pass to the liveness computation for propagating EBB
argument affinities, possibly recursively.
- Verify EBB argument affinities correctly: A value passed to a branch
must have an affinity only if the corresponding EBB argument value in
the destination has an affinity.
