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- Lean.Meta.SynthInstance.instInhabitedInstance = { default := { val := default, synthOrder := default } }
- mvar : Lean.Expr
- key : Lean.Expr
- mctx : Lean.MetavarContext
- instances : Array Lean.Meta.SynthInstance.Instance
- currInstanceIdx : Nat
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- Lean.Meta.SynthInstance.instInhabitedGeneratorNode = { default := { mvar := default, key := default, mctx := default, instances := default, currInstanceIdx := default } }
- mvar : Lean.Expr
- key : Lean.Expr
- mctx : Lean.MetavarContext
- size : Nat
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- Lean.Meta.SynthInstance.instInhabitedConsumerNode = { default := { mvar := default, key := default, mctx := default, subgoals := default, size := default } }
- consumerNode: Lean.Meta.SynthInstance.ConsumerNode → Lean.Meta.SynthInstance.Waiter
- root: Lean.Meta.SynthInstance.Waiter
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- Lean.Meta.SynthInstance.Waiter.isRoot x = match x with | Lean.Meta.SynthInstance.Waiter.consumerNode a => false | Lean.Meta.SynthInstance.Waiter.root => true
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In tabled resolution, we creating a mapping from goals (e.g., Coe Nat ?x
) to
answers and waiters. Waiters are consumer nodes that are waiting for answers for a
particular node.
We implement this mapping using a HashMap
where the keys are
normalized expressions. That is, we replace assignable metavariables
with auxiliary free variables of the form _tc.
. We do
not declare these free variables in any local context, and we should
view them as "normalized names" for metavariables. For example, the
term f ?m ?m ?n
is normalized as
f _tc.0 _tc.0 _tc.1
.
This approach is structural, and we may visit the same goal more than once if the different occurrences are just definitionally equal, but not structurally equal.
Remark: a metavariable is assignable only if its depth is equal to the metavar context depth.
- nextIdx : Nat
- lmap : Lean.HashMap Lean.LMVarId Lean.Level
- emap : Lean.HashMap Lean.MVarId Lean.Expr
- mctx : Lean.MetavarContext
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Remark: mkTableKey
assumes e
does not contain assigned metavariables.
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- result : Lean.Meta.AbstractMVarsResult
- resultType : Lean.Expr
- size : Nat
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- Lean.Meta.SynthInstance.instInhabitedAnswer = { default := { result := default, resultType := default, size := default } }
- waiters : Array Lean.Meta.SynthInstance.Waiter
- answers : Array Lean.Meta.SynthInstance.Answer
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- result? : Option Lean.Meta.AbstractMVarsResult
- generatorStack : Array Lean.Meta.SynthInstance.GeneratorNode
- resumeStack : Array (Lean.Meta.SynthInstance.ConsumerNode × Lean.Meta.SynthInstance.Answer)
- tableEntries : Lean.HashMap Lean.Expr Lean.Meta.SynthInstance.TableEntry
Remark: the SynthInstance.State is not really an extension of Meta.State
.
The field postponed
is not needed, and the field mctx
is misleading since
synthInstance
methods operate over different MetavarContext
s simultaneously.
That being said, we still use extends
because it makes it simpler to move from
M
to MetaM
.
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- Lean.Meta.SynthInstance.checkMaxHeartbeats = do let __do_lift ← read liftM (Lean.Core.checkMaxHeartbeatsCore "typeclass" `synthInstance.maxHeartbeats __do_lift.maxHeartbeats)
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- Lean.Meta.SynthInstance.instInhabitedSynthM = { default := fun x x => default }
Return globals and locals instances that may unify with type
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Create a new generator node for mvar
and add waiter
as its waiter.
key
must be mkTableKey mctx mvarType
.
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- Lean.Meta.SynthInstance.findEntry? key = do let __do_lift ← get pure (Lean.HashMap.find? __do_lift.tableEntries key)
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Create a key
for the goal associated with the given metavariable.
That is, we create a key for the type of the metavariable.
We must instantiate assigned metavariables before we invoke mkTableKey
.
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See getSubgoals
and getSubgoalsAux
We use the parameter j
to reduce the number of instantiate*
invocations.
It is the same approach we use at forallTelescope
and lambdaTelescope
.
Given getSubgoalsAux args j subgoals instVal type
,
we have that type.instantiateRevRange j args.size args
does not have loose bound variables.
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getSubgoals lctx localInsts xs inst
creates the subgoals for the instance inst
.
The subgoals are in the context of the free variables xs
, and
(lctx, localInsts)
is the local context and instances before we added the free variables to it.
This extra complication is required because
1- We want all metavariables created by synthInstance
to share the same local context.
2- We want to ensure that applications such as mvar xs
are higher order patterns.
The method getGoals
create a new metavariable for each parameter of inst
.
For example, suppose the type of inst
is forall (x_1 : A_1) ... (x_n : A_n), B x_1 ... x_n
.
Then, we create the metavariables ?m_i : forall xs, A_i
, and return the subset of these
metavariables that are instance implicit arguments, and the expressions:
inst (?m_1 xs) ... (?m_n xs)
(akainstVal
)B (?m_1 xs) ... (?m_n xs)
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Try to synthesize metavariable mvar
using the instance inst
.
Remark: mctx
is set using withMCtx
.
If it succeeds, the result is a new updated metavariable context and a new list of subgoals.
A subgoal is created for each instance implicit parameter of inst
.
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Assign a precomputed answer to mvar
.
If it succeeds, the result is a new updated metavariable context and a new list of subgoals.
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Move waiters that are waiting for the given answer to the resume stack.
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- Lean.Meta.SynthInstance.isNewAnswer oldAnswers answer = Array.all oldAnswers (fun oldAnswer => oldAnswer.resultType != answer.resultType) 0 (Array.size oldAnswers)
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Create a new answer after cNode
resolved all subgoals.
That is, cNode.subgoals == []
.
And then, store it in the tabled entries map, and wakeup waiters.
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Process the next subgoal in the given consumer node.
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- Lean.Meta.SynthInstance.getTop = do let __do_lift ← get pure (Array.back __do_lift.generatorStack)
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Try the next instance in the node on the top of the generator stack.
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Given (cNode, answer)
on the top of the resume stack, continue execution by using answer
to solve the
next subgoal.
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- Lean.Meta.SynthInstance.getResult = do let __do_lift ← get pure __do_lift.result?
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Type class parameters can be annotated with outParam
annotations.
Given C a_1 ... a_n
, we replace a_i
with a fresh metavariable ?m_i
IF
a_i
is an outParam
.
The result is type correct because we reject type class declarations IF
it contains a regular parameter X that depends on an out
parameter Y.
Then, we execute type class resolution as usual.
If it succeeds, and metavariables ?m_i have been assigned, we try to unify
the original type C a_1 ... a_n
witht the normalized one.
Remark: when maxResultSize? == none
, the configuration option synthInstance.maxResultSize
is used.
Remark: we use a different option for controlling the maximum result size for coercions.
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Return LOption.some r
if succeeded, LOption.none
if it failed, and LOption.undef
if
instance cannot be synthesized right now because type
contains metavariables.
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