Convert the given goal Ctx |- target
into Ctx |- targetNew
using an equality proof eqProof : target = targetNew
.
It assumes eqProof
has type target = targetNew
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- Lean.Meta.replaceTargetEq mvarId targetNew eqProof = mvarId.replaceTargetEq targetNew eqProof
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Convert the given goal Ctx |- target
into Ctx |- targetNew
. It assumes the goals are definitionally equal.
We use the proof term
@id target mvarNew
to create a checkpoint.
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- Lean.Meta.replaceTargetDefEq mvarId targetNew = mvarId.replaceTargetDefEq targetNew
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Replace type of the local declaration with id fvarId
with one with the same user-facing name, but with type typeNew
.
This method assumes eqProof
is a proof that the type of fvarId
is equal to typeNew
.
This tactic actually adds a new declaration and (tries to) clear the old one.
If the old one cannot be cleared, then at least its user-facing name becomes inaccessible.
The new local declaration is inserted at the soonest point after fvarId
at which it is
well-formed. That is, if typeNew
involves declarations which occur later than fvarId
in the
local context, the new local declaration will be inserted immediately after the latest-occurring
one. Otherwise, it will be inserted immediately after fvarId
.
Note: replaceLocalDecl
should not be used when unassigned pending mvars might be present in
typeNew
, as these may later be synthesized to fvars which occur after fvarId
(by e.g.
Term.withSynthesize
or Term.synthesizeSyntheticMVars
) .
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- mvarId.replaceLocalDecl fvarId typeNew eqProof = Lean.Meta.replaceLocalDeclCore mvarId fvarId typeNew eqProof
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- Lean.Meta.replaceLocalDecl mvarId fvarId typeNew eqProof = mvarId.replaceLocalDecl fvarId typeNew eqProof
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Replace the type of fvarId
at mvarId
with typeNew
.
Remark: this method assumes that typeNew
is definitionally equal to the current type of fvarId
.
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- Lean.Meta.replaceLocalDeclDefEq mvarId fvarId typeNew = mvarId.replaceLocalDeclDefEq fvarId typeNew
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Replace the target type of mvarId
with typeNew
.
If checkDefEq = false
, this method assumes that typeNew
is definitionally equal to the current target type.
If checkDefEq = true
, throw an error if typeNew
is not definitionally equal to the current target type.
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- Lean.Meta.change mvarId targetNew checkDefEq = mvarId.withContext (mvarId.change targetNew checkDefEq)
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Executes the revert/intro pattern, running the continuation k
after temporarily reverting
the given local variables from the local context of the metavariable mvarId
,
and then re-introducing the local variables specified by k
.
mvarId
is the goal metavariable to operate on.fvarIds
is an array offvarIds
to revert in the order specified. An error is thrown if they cannot be reverted in order.clearAuxDeclsInsteadOfRevert
is configuration passed toLean.MVarId.revert
.k
is the continuation run once the local variables have been reverted. It is providedmvarId
after the requested variables have been reverted along with the array of reverted variables. This array always containsfvarIds
, but it may contain additional variables that were reverted due to dependencies. The continuation returns a value, a new goal, and an aliasing array.
Once k
has completed, one variable is introduced per entry in the aliasing array.
- If the entry is
none
, the variable is just introduced. - If the entry is
some fv
(wherefv
is a variable fromfvarIds
), the variable is introduced and then recorded as an alias offv
in the info tree. This for example causes the unused variable linter as seeingfv
and this newly introduced variable as being "the same".
For example, if k
leaves all the reverted variables in the same order,
having it return fvars.map .some
as the aliasing array causes those variables to be re-introduced and aliased
to the original local variables.
Returns the value returned by k
along with the resulting goal after variable introduction.
See Lean.MVarId.changeLocalDecl
for an example. The motivation is that to work on a local variable,
you need to move it into the goal, alter the goal, and then bring it back into the local context,
all while keeping track of any other local variables that depend on this one.
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Replaces the type of the free variable fvarId
with typeNew
.
If checkDefEq
is true
then an error is thrown if typeNew
is not definitionally
equal to the type of fvarId
. Otherwise this function assumes typeNew
and the type
of fvarId
are definitionally equal.
This function is the same as Lean.MVarId.changeLocalDecl
but makes sure to push substitution
information into the info tree.
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- Lean.Meta.changeLocalDecl mvarId fvarId typeNew checkDefEq = mvarId.changeLocalDecl fvarId typeNew checkDefEq
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Modify mvarId
target type using f
.
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- Lean.Meta.modifyTarget mvarId f = mvarId.modifyTarget f
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Modify mvarId
target type left-hand-side using f
.
Throw an error if target type is not an equality.
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- Lean.Meta.modifyTargetEqLHS mvarId f = mvarId.modifyTargetEqLHS f