This PR adds the functions `Poly.denote'`, `RelCnstr.denote'`, and
`DvdCnstr.denote'`. These functions are useful for representing the
denotation of normalized results in `simp +arith` and the `grind`
preprocessor. This PR also adjusts all auxiliary normalization theorems
to use them to represent the normalized constraints. Previously, we were
converting `RelCnstr` and `DvdCnstr` back into raw constraints. While
this overhead was reasonable for `simp +arith`, it is not for the cutsat
procedure, which has no need for raw constraints. All constraints have
already been normalized by the time they reach cutsat.
This PR cleans up the `Int.Linear` module by normalizing function and
type names and adding documentation strings. We will use it to implement
cutsat in the `grind` tactic.
This PR adds helper theorems for normalizing divisibility constraints.
They are going to be used to implement the cutsat procedure in the
`grind` tactic.
This PR introduces `Fin.toNat` as an alias for `Fin.val`. We add this
function for discoverability and consistency reasons. The normal form
for proofs remains `Fin.val`, and there is a `simp` lemma rewriting
`Fin.toNat` to `Fin.val`.
This PR adds functions `IntX.ofIntLE`, `IntX.ofIntTruncate`, which are
analogous to the unsigned counterparts `UIntX.ofNatLT` and
`UInt.ofNatTruncate`.
This PR introduces ordered map data structures, namely `DTreeMap`,
`TreeMap`, `TreeSet` and their `.Raw` variants, into the standard
library. There are still some operations missing that the hash map has.
As of now, the operations are unverified, but the corresponding lemmas
will follow in subsequent PRs. While the tree map has already been
optimized, more micro-optimization will follow as soon as the new code
generator is ready.
---------
Co-authored-by: Paul Reichert <6992158+datokrat@users.noreply.github.com>
This PR adds completes the linear integer inequality normalizer for
`grind`. The missing normalization step replaces a linear inequality of
the form `a_1*x_1 + ... + a_n*x_n + b <= 0` with `a_1/k * x_1 + ... +
a_n/k * x_n + ceil(b/k) <= 0` where `k = gcd(a_1, ..., a_n)`.
`ceil(b/k)` is implemented using the helper `cdiv b k`.
This PR extend the preprocessing of well-founded recursive definitions
to bring assumptions like `h✝ : x ∈ xs` into scope automatically.
This fixes#5471, and follows (roughly) the design written there.
See the module docs at `src/Lean/Elab/PreDefinition/WF/AutoAttach.lean`
for details on the implementation.
This only works for higher-order functions that have a suitable setup.
See for example section “Well-founded recursion preprocessing setup” in
`src/Init/Data/List/Attach.lean`.
This does not change the `decreasing_tactic`, so in some cases there is
still the need for a manual termination proof some cases. We expect a
better termination tactic in the near future.
This PR implements basic support for handling of enum inductives in
`bv_decide`. It now supports equality on enum inductive variables (or
other uninterpreted atoms) and constants.
This PR adds `simp +arith` for integers. It uses the new `grind`
normalizer for linear integer arithmetic. We still need to implement
support for dividing the coefficients by their GCD. It also fixes
several bugs in the normalizer.
This PR implements the normalizer for linear integer arithmetic
expressions. It is not connect to `simp +arith` yet because of some
spurious `[simp]` attributes.
This PR starts on the process of cleaning up variable names across
List/Array/Vector. For now, we just rename "numerical index" variables
in one file. This is driven by a custom linter.
This PR adds SMT-LIB operators to detect overflow
`BitVec.(uadd_overflow, sadd_overflow)`, according to the definitions
[here](https://github.com/SMT-LIB/SMT-LIB-2/blob/2.7/Theories/FixedSizeBitVectors.smt2),
and the theorems proving equivalence of such definitions with the
`BitVec` library functions (`uaddOverflow_eq`, `saddOverflow_eq`).
Support theorems for these proofs are `BitVec.toNat_mod_cancel_of_lt,
BitVec.toInt_lt, BitVec.le_toInt, Int.bmod_neg_iff`. The PR also
includes a set of tests.
---------
Co-authored-by: Tobias Grosser <github@grosser.es>
Co-authored-by: Alex Keizer <alex@keizer.dev>
Co-authored-by: Tobias Grosser <tobias@grosser.es>
Co-authored-by: Siddharth Bhat <siddu.druid@gmail.com>
This PR adds theorems `BitVec.(getElem_umod_of_lt, getElem_umod,
getLsbD_umod, getMsbD_umod)`. For the defiition of these theorems we
rely on `divRec`, excluding the case where `d=0#w`, which is treated
separately because there is no infrastructure to reason about this case
within `divRec`. In particular, our implementation follows the mathlib
standard [where division by 0 yields
0](c7c1e091c9/src/Init/Data/BitVec/Basic.lean (L217)),
while in [SMTLIB this yields
`allOnes`](c7c1e091c9/src/Init/Data/BitVec/Basic.lean (L237)).
Co-authored by @bollu.
---------
Co-authored-by: Siddharth <siddu.druid@gmail.com>
This PR adds `BitVec.(getMsbD, msb)_replicate, replicate_one` theorems,
corrects a non-terminal `simp` in `BitVec.getLsbD_replicate` and
simplifies the proof of `BitVec.getElem_replicate` using the `cases`
tactic.
Co-authored with @bollu.
---------
Co-authored-by: Alex Keizer <alex@keizer.dev>
