@semorrison, does this include all the answers to the questions I asked
in our thread? I think so!
---------
Co-authored-by: Mac Malone <tydeu@hatpress.net>
while trying to help a user who was facing an unhelpful
```
omega did not find a contradiction:
[0, 0, 0, 0, 1, -1] ∈ [1, ∞)
[0, 0, 0, 0, 0, 1] ∈ [0, ∞)
[0, 0, 0, 0, 1] ∈ [0, ∞)
[1, -1] ∈ [1, ∞)
[0, 0, 0, 1] ∈ [0, ∞)
[0, 1] ∈ [0, ∞)
[1] ∈ [0, ∞)
[0, 0, 0, 1, 1] ∈ [-1, ∞)
```
I couldn’t resist and wrote a pretty-printer for these problem that
shows the linear combination as such, and includes the recognized atoms.
This is especially useful since oftem `omega` failures stem from failure
to recognize atoms as equal. In this case, we now get:
```
omega-failure.lean:19:2-19:7: error: omega could not prove the goal:
a possible counterexample may satisfy the constraints
d - e ≥ 1
e ≥ 0
d ≥ 0
a - b ≥ 1
c ≥ 0
b ≥ 0
a ≥ 0
c + d ≥ -1
where
a := ↑(sizeOf xs)
b := ↑(sizeOf x)
c := ↑(sizeOf x.fst)
d := ↑(sizeOf x.snd)
e := ↑(sizeOf xs)
```
and this might help the user make progress (e.g. by using `case x`
first, and investingating why `sizeOf xs` shows up twice)
Reusing the best profiling UI out there
Usage:
```
lean -Dtrace.profiler=true -Dtrace.profiler.output=profile.json foo.lean ...
```
then open `profile.json` in https://profiler.firefox.com/.
See also `script/collideProfiles.lean` for minimizing and merging
profiles.
Implements a new method to generate instance names for anonymous
instances that uses a heuristic that tends to produce shorter names. A
design goal is to make them relatively unique within projects and
definitely unique across projects, while also using accessible names so
that they can be referred to as needed, both in Lean code and in
discussions.
The new method also takes into account binders provided to the instance,
and it adds project-based suffixes. Despite this, a median new name is
73% its original auto-generated length. (Compare: [old generated
names](https://gist.github.com/kmill/b72bb43f5b01dafef41eb1d2e57a8237)
and [new generated
names](https://gist.github.com/kmill/393acc82e7a8d67fc7387829f4ed547e).)
Some notes:
* The naming is sensitive to what is explicitly provided as a binder vs
what is provided via a `variable`. It does not make use of `variable`s
since, when names are generated, it is not yet known which variables are
used in the body of the instance.
* If the instance name refers to declarations in the current "project"
(given by the root module), then it does not add a suffix. Otherwise, it
adds the project name as a suffix to protect against cross-project
collisions.
* `set_option trace.Elab.instance.mkInstanceName true` can be used to
see what name the auto-generator would give, even if the instance
already has an explicit name.
There were a number of instances that were referred to explicitly in
meta code, and these have been given explicit names.
Removes the unused `Lean.Elab.mkFreshInstanceName` along with the
Command state's `nextInstIdx`.
Fixes#2343
As a special case, makes the `rcases` machinery use `Nat.casesAuxOn` so
that goal states see `0` and `n + 1` rather than `Nat.zero` and
`Nat.succ n`. This is a followup to enabling custom eliminators for
`cases` and `induction`.
This doesn't use custom eliminators in general since `rcases` uses
`Lean.MVarId.cases`, which is completely different from what `cases` and
`induction` use.
Adds options to control whitespace normalization and message ordering in
`#guard_msgs`.
Examples:
1. `#guard_msgs (whitespace := lax)` ignores differences in whitespace
completely.
2. `#guard_msgs (whitespace := exact)` requires an exact match for
whitespace (after trimming).
3. `#guard_msgs (ordering := sorted)` sorts the list of messages, to
make it insensitive to message order.
This should improve the performance of the deriving a bit since it
doesn't have to generate so many matchers. The main motivation though is
to make it easier to prove properties about the expression by using more
standard functions. The generated implementation should end up the same,
since `Ordering.then` is `@[macro_inline]`.
Part of the retreat Hackathon.
---------
Co-authored-by: David Thrane Christiansen <david@davidchristiansen.dk>
Co-authored-by: Mario Carneiro <di.gama@gmail.com>
This adds some basic lemmas to support commuting ofInt/toInt and
add/mul.
It also removes the simp annotation on `ofNat_add_ofNat` as in some
contexts the other direction or conversion to Int may be desired.
The Canonicalizer creates a “key” expression eliding certain information
(implicit parameters, levels), and `getFunInfo` can be
confused by these terms (in particular, wrong number of level
parameters).
By running `getFunInfo` on the original expression we avoid this, and
can just put `[]` as the level list in the key.
This changes how Nat typeclass checks in offset terms from syntactic
equality to definitional equality with "instances" transparency.
This may have a negative performance penalty in `isOffset?`, but it
should be small in common cases since the relevant instances are small
terms.
This closes#3836
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
```
Possibly the more principled fix is to not have `simp` invoke
dischargers under `withReducible`.
In the meantime, this ensures that `falseOrByContra` still succeeds with
`intro1` on a `Not` goal, which previously was breaking `omega` as a
simp discharger.
Closes#3805.
