Treat integer range for vector type as union of ranges of individual
elements. With this semantics, most arith ops on vectors will work out
of the box, the only special handling needed for constants and vector
elements manipulation ops.
The end goal of these changes is to be able to optimize vectorized index
calculations.
The concept of a 'program point' in the original data flow framework is
ambiguous. It can refer to either an operation or a block itself. This
representation has different interpretations in forward and backward
data-flow analysis. In forward data-flow analysis, the program point of
an operation represents the state after the operation, while in backward
data flow analysis, it represents the state before the operation. When
using forward or backward data-flow analysis, it is crucial to carefully
handle this distinction to ensure correctness.
This patch refactors the definition of program point, unifying the
interpretation of program points in both forward and backward data-flow
analysis.
How to integrate this patch?
For dense forward data-flow analysis and other analysis (except dense
backward data-flow analysis), the program point corresponding to the
original operation can be obtained by `getProgramPointAfter(op)`, and
the program point corresponding to the original block can be obtained by
`getProgramPointBefore(block)`.
For dense backward data-flow analysis, the program point corresponding
to the original operation can be obtained by
`getProgramPointBefore(op)`, and the program point corresponding to the
original block can be obtained by `getProgramPointAfter(block)`.
NOTE: If you need to get the lattice of other data-flow analyses in
dense backward data-flow analysis, you should still use the dense
forward data-flow approach. For example, to get the Executable state of
a block in dense backward data-flow analysis and add the dependency of
the current operation, you should write:
``getOrCreateFor<Executable>(getProgramPointBefore(op),
getProgramPointBefore(block))``
In case above, we use getProgramPointBefore(op) because the analysis we
rely on is dense backward data-flow, and we use
getProgramPointBefore(block) because the lattice we query is the result
of a non-dense backward data flow computation.
related dsscussion:
https://discourse.llvm.org/t/rfc-unify-the-semantics-of-program-points/80671/8
corresponding PSA:
https://discourse.llvm.org/t/psa-program-point-semantics-change/81479
When the integer range analysis was first develop, a pass that did
integer range-based constant folding was developed and used as a test
pass. There was an intent to add such a folding to SCCP, but that hasn't
happened.
Meanwhile, -int-range-optimizations was added to the arith dialect's
transformations. The cmpi simplification in that pass is a strict subset
of the constant folding that lived in
-test-int-range-inference.
This commit moves the former test pass into -int-range-optimizaitons,
subsuming its previous contents. It also adds an optimization from
rocMLIR where `rem{s,u}i` operations that are noops are replaced by
their left operands.
The pass runs a `DataFlowSolver` and collects state information on the
input IR. Then, the rewrite driver and folding is applied. During
pattern application and folding it can happen that an Op from the input
IR is deleted and a new Op is created at the same address. When the
newly created Ops is looked up in the `DataFlowSolver` state memory, the
state of the original Op is returned.
This patch adds a method to `DataFlowSolver` which removes all state
related to a `ProgramPoint`. It also adds a listener to the Pass which
clears the state information of deleted Ops from the `DataFlowSolver`.
Fix https://github.com/llvm/llvm-project/issues/81228
Add a pass which do arith dialect ops optimization based on integer range analysis (only cmpi for now).
Differential Revision: https://reviews.llvm.org/D140629
