This PR adds `BitVec.[toInt|toFin]_concat` and moves a couple of
theorems into the concat section, as `BitVec.msb_concat` is needed for
the `toInt_concat` proof.
We also add `Bool.toInt`.
This PR adds the theorems
```
@[simp]
theorem divRec_zero (qr : DivModState w) :
divRec w w 0 n d qr = qr
@[simp]
theorem divRec_succ' (wn : Nat) (qr : DivModState w) :
divRec w wr (wn + 1) n d qr =
let r' := shiftConcat qr.r (n.getLsbD wn)
let input : DivModState w :=
if r' < d then ⟨qr.q.shiftConcat false, r'⟩ else ⟨qr.q.shiftConcat true, r' - d⟩
divRec w (wr + 1) wn n d input
```
The final statements may need some masasging to interoperate with
`bv_decide`. We prove the recurrence for unsigned division by building a
shift-subtract circuit, and then showing that this circuit obeys the
division algorithm's invariant.
---
A `DivModState` is lawful if the remainder width `wr` plus the dividend
width `wn` equals `w`,
and the bitvectors `r` and `n` have values in the bounds given by
bitwidths `wr`, resp. `wn`.
This is a proof engineering choice: An alternative world could have
`r : BitVec wr` and `n : BitVec wn`, but this required much more
dependent typing coercions.
Instead, we choose to declare all involved bitvectors as length `w`, and
then prove that
the values are within their respective bounds.
---------
Co-authored-by: Tobias Grosser <github@grosser.es>
Co-authored-by: Alex Keizer <alex@keizer.dev>
Co-authored-by: Kim Morrison <scott@tqft.net>
Co-authored-by: Tobias Grosser <tobias@grosser.es>
This PR also pulls in some mathlib theorems on testBit and Nat and establishes facts about 2^w that are needed here and which are generally useful for bitvector reasoning.
The following theorem is not generalized to arbitrary x instead of 2, as this would require a condition to be added for x > 1 which would have to be passed to simp each time this theorem should fire.
chore: derive from testBit_two_pow
chore: convert first to prop and then decide
chore: move intMax down as well
chore: add simp set
Add simp-set into this PR
chore: fix simp extension
Move file to src/Lean to fix build
Add prelude
update date
Add university of cambridge as copyright holder
improve naming
use whitespace uniformly
use decide (n = m)
Drop the 'Nat.' namespace
Update src/Init/Data/BitVec/Lemmas.lean
Co-authored-by: Siddharth <siddu.druid@gmail.com>
Update src/Init/Data/BitVec/Lemmas.lean
Co-authored-by: Siddharth <siddu.druid@gmail.com>
Fix build
add some theorems
Revert "add some theorems"
This reverts commit fb97bc2007e371854b40badb3d6014da034c1f5e.
WIP
Shorten proof
Update src/Init/Data/Nat/Lemmas.lean
finish proofs
Update src/Init/Data/BitVec/Lemmas.lean
Co-authored-by: Kim Morrison <scott@tqft.net>
Update src/Init/Data/Nat/Lemmas.lean
Co-authored-by: Kim Morrison <scott@tqft.net>
chore: move BoolToPropSimps
Defines `mergeSort`, a naive stable merge sort algorithm, replaces it
via a `@[csimp]` lemma with something faster at runtime, and proves the
following results:
* `mergeSort_sorted`: `mergeSort` produces a sorted list.
* `mergeSort_perm`: `mergeSort` is a permutation of the input list.
* `mergeSort_of_sorted`: `mergeSort` does not change a sorted list.
* `mergeSort_cons`: proves `mergeSort le (x :: xs) = l₁ ++ x :: l₂` for
some `l₁, l₂`
so that `mergeSort le xs = l₁ ++ l₂`, and no `a ∈ l₁` satisfies `le a
x`.
* `mergeSort_stable`: if `c` is a sorted sublist of `l`, then `c` is
still a sublist of `mergeSort le l`.
Previously the `ac_rfl` tactic was only really usable when depending on
mathlib. With these instances, `ac_rfl` can deal with the various
operations defined in Lean.
---------
Co-authored-by: Scott Morrison <scott.morrison@gmail.com>
This removes simp attributes from `Nat.succ.injEq` and
`Nat.succ_sub_succ_eq_sub` to replace them with simprocs. This is
because any reductions involving `Nat.succ` has a high risk of leading
proof performance problems when dealing with even moderately large
numbers.
Here are a couple examples that will both report a maximum recursion
depth error currently. These examples are fixed by this PR.
```
example : (123456: Nat) = 12345667 := by
simp
example (x : Nat) (p : x = 0) : 1000 - (x + 1000) = 0 := by
simp
```
This adds a number of lemmas for simplification of `Bool` and `Prop`
terms. It pulls lemmas from Mathlib and adds additional lemmas where
confluence or consistency suggested they are needed.
It has been tested against Mathlib using some automated test
infrastructure.
That testing module is not yet included in this PR, but will be included
as part of this.
Note. There are currently some comments saying the origin of the simp
rule. These will be removed prior to merging, but are added to clarify
where the rule came from during review.
---------
Co-authored-by: Scott Morrison <scott.morrison@gmail.com>
First (baby)-step to a `concat`-based `bitblast`: a characterization of
`concat` in terms of `getLsb`.
The proof might benefit slightly from a `toNat_concat` lemma, but I
wasn't sure what the normal form there should be, so I avoided it.
---------
Co-authored-by: Scott Morrison <scott@tqft.net>
