The type DHashMap.Raw
itself is defined in the module Std.Data.DHashmap.RawDef
for import
structure reasons.
Creates a new empty hash map. The optional parameter capacity
can be supplied to presize the
map so that it can hold the given number of mappings without reallocating. It is also possible to
use the empty collection notations ∅
and {}
to create an empty hash map with the default
capacity.
Equations
- Std.DHashMap.Raw.empty capacity = (Std.DHashMap.Internal.Raw₀.empty capacity).val
Instances For
Equations
- Std.DHashMap.Raw.instEmptyCollection = { emptyCollection := Std.DHashMap.Raw.empty }
Inserts the given mapping into the map, replacing an existing mapping for the key if there is one.
Equations
- m.insert a b = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.insert ⟨m, h⟩ a b).val else m
Instances For
Equations
- Std.DHashMap.Raw.instSingletonSigmaOfBEqOfHashable = { singleton := fun (x : (a : α) × β a) => match x with | ⟨a, b⟩ => Std.DHashMap.Raw.empty.insert a b }
Equations
- Std.DHashMap.Raw.instInsertSigmaOfBEqOfHashable = { insert := fun (x : (a : α) × β a) (s : Std.DHashMap.Raw α β) => match x with | ⟨a, b⟩ => s.insert a b }
Equations
- ⋯ = ⋯
If there is no mapping for the given key, inserts the given mapping into the map. Otherwise, returns the map unaltered.
Equations
- m.insertIfNew a b = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.insertIfNew ⟨m, h⟩ a b).val else m
Instances For
Checks whether a key is present in a map, and unconditionally inserts a value for the key.
Equivalent to (but potentially faster than) calling contains
followed by insert
.
Equations
- m.containsThenInsert a b = if h : 0 < m.buckets.size then match Std.DHashMap.Internal.Raw₀.containsThenInsert ⟨m, h⟩ a b with | (replaced, ⟨r, property⟩) => (replaced, r) else (false, m)
Instances For
Checks whether a key is present in a map, returning the associated value, and inserts a value for the key if it was not found.
If the returned value is some v
, then the returned map is unaltered. If it is none
, then the
returned map has a new value inserted.
Equivalent to (but potentially faster than) calling get?
followed by insertIfNew
.
Uses the LawfulBEq
instance to cast the retrieved value to the correct type.
Equations
- m.getThenInsertIfNew? a b = if h : 0 < m.buckets.size then match Std.DHashMap.Internal.Raw₀.getThenInsertIfNew? ⟨m, h⟩ a b with | (previous, ⟨r, property⟩) => (previous, r) else (none, m)
Instances For
Checks whether a key is present in a map and inserts a value for the key if it was not found.
If the returned Bool
is true
, then the returned map is unaltered. If the Bool
is false
, then
the returned map has a new value inserted.
Equivalent to (but potentially faster than) calling contains
followed by insertIfNew
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Tries to retrieve the mapping for the given key, returning none
if no such mapping is present.
Uses the LawfulBEq
instance to cast the retrieved value to the correct type.
Equations
- m.get? a = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.get? ⟨m, h⟩ a else none
Instances For
Returns true
if there is a mapping for the given key. There is also a Prop
-valued version
of this: a ∈ m
is equivalent to m.contains a = true
.
Observe that this is different behavior than for lists: for lists, ∈
uses =
and contains
uses
==
for comparisons, while for hash maps, both use ==
.
Equations
- m.contains a = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.contains ⟨m, h⟩ a else false
Instances For
Equations
- Std.DHashMap.Raw.instMembershipOfBEqOfHashable = { mem := fun (m : Std.DHashMap.Raw α β) (a : α) => m.contains a = true }
Equations
- Std.DHashMap.Raw.instDecidableMem = inferInstanceAs (Decidable (m.contains a = true))
Retrieves the mapping for the given key. Ensures that such a mapping exists by requiring a proof
of a ∈ m
.
Uses the LawfulBEq
instance to cast the retrieved value to the correct type.
Equations
- m.get a h = Std.DHashMap.Internal.Raw₀.get ⟨m, ⋯⟩ a ⋯
Instances For
Tries to retrieve the mapping for the given key, returning fallback
if no such mapping is present.
Uses the LawfulBEq
instance to cast the retrieved value to the correct type.
Equations
- m.getD a fallback = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.getD ⟨m, h⟩ a fallback else fallback
Instances For
Tries to retrieve the mapping for the given key, panicking if no such mapping is present.
Uses the LawfulBEq
instance to cast the retrieved value to the correct type.
Equations
- m.get! a = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.get! ⟨m, h⟩ a else default
Instances For
Removes the mapping for the given key if it exists.
Equations
- m.erase a = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.erase ⟨m, h⟩ a).val else m
Instances For
Tries to retrieve the mapping for the given key, returning none
if no such mapping is present.
Equations
- Std.DHashMap.Raw.Const.get? m a = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.Const.get? ⟨m, h⟩ a else none
Instances For
Retrieves the mapping for the given key. Ensures that such a mapping exists by requiring a proof of
a ∈ m
.
Equations
- Std.DHashMap.Raw.Const.get m a h = Std.DHashMap.Internal.Raw₀.Const.get ⟨m, ⋯⟩ a ⋯
Instances For
Tries to retrieve the mapping for the given key, returning fallback
if no such mapping is present.
Equations
- Std.DHashMap.Raw.Const.getD m a fallback = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.Const.getD ⟨m, h⟩ a fallback else fallback
Instances For
Tries to retrieve the mapping for the given key, panicking if no such mapping is present.
Equations
- Std.DHashMap.Raw.Const.get! m a = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.Const.get! ⟨m, h⟩ a else default
Instances For
Equivalent to (but potentially faster than) calling Const.get?
followed by insertIfNew
.
Checks whether a key is present in a map, returning the associated value, and inserts a value for the key if it was not found.
If the returned value is some v
, then the returned map is unaltered. If it is none
, then the
returned map has a new value inserted.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Checks if a mapping for the given key exists and returns the key if it does, otherwise none
.
The result in the some
case is guaranteed to be pointer equal to the key in the map.
Equations
- m.getKey? a = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.getKey? ⟨m, h⟩ a else none
Instances For
Retrieves the key from the mapping that matches a
. Ensures that such a mapping exists by
requiring a proof of a ∈ m
. The result is guaranteed to be pointer equal to the key in the map.
Equations
- m.getKey a h = Std.DHashMap.Internal.Raw₀.getKey ⟨m, ⋯⟩ a ⋯
Instances For
Checks if a mapping for the given key exists and returns the key if it does, otherwise fallback
.
If a mapping exists the result is guaranteed to be pointer equal to the key in the map.
Equations
- m.getKeyD a fallback = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.getKeyD ⟨m, h⟩ a fallback else fallback
Instances For
Checks if a mapping for the given key exists and returns the key if it does, otherwise panics. If no panic occurs the result is guaranteed to be pointer equal to the key in the map.
Equations
- m.getKey! a = if h : 0 < m.buckets.size then Std.DHashMap.Internal.Raw₀.getKey! ⟨m, h⟩ a else default
Instances For
We currently do not provide lemmas for the functions below.
Updates the values of the hash map by applying the given function to all mappings, keeping
only those mappings where the function returns some
value.
Equations
- Std.DHashMap.Raw.filterMap f m = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.filterMap f ⟨m, h⟩).val else ∅
Instances For
Updates the values of the hash map by applying the given function to all mappings.
Equations
- Std.DHashMap.Raw.map f m = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.map f ⟨m, h⟩).val else ∅
Instances For
Removes all mappings of the hash map for which the given function returns false
.
Equations
- Std.DHashMap.Raw.filter f m = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.filter f ⟨m, h⟩).val else ∅
Instances For
Monadically computes a value by folding the given function over the mappings in the hash map in some order.
Equations
- Std.DHashMap.Raw.foldM f init b = Array.foldlM (fun (acc : δ) (l : Std.DHashMap.Internal.AssocList α β) => Std.DHashMap.Internal.AssocList.foldlM f acc l) init b.buckets
Instances For
Folds the given function over the mappings in the hash map in some order.
Equations
- Std.DHashMap.Raw.fold f init b = (Std.DHashMap.Raw.foldM f init b).run
Instances For
Carries out a monadic action on each mapping in the hash map in some order.
Equations
- Std.DHashMap.Raw.forM f b = Array.forM (Std.DHashMap.Internal.AssocList.forM f) b.buckets
Instances For
Support for the for
loop construct in do
blocks.
Equations
- Std.DHashMap.Raw.forIn f init b = forIn b.buckets init fun (bucket : Std.DHashMap.Internal.AssocList α β) (acc : δ) => bucket.forInStep acc f
Instances For
Equations
- Std.DHashMap.Raw.instForMSigma = { forM := fun [Monad m] (m_1 : Std.DHashMap.Raw α β) (f : (a : α) × β a → m PUnit) => Std.DHashMap.Raw.forM (fun (a : α) (b : β a) => f ⟨a, b⟩) m_1 }
Equations
- One or more equations did not get rendered due to their size.
Transforms the hash map into a list of mappings in some order.
Equations
- m.toList = Std.DHashMap.Raw.fold (fun (acc : List ((a : α) × β a)) (k : α) (v : β k) => ⟨k, v⟩ :: acc) [] m
Instances For
Transforms the hash map into an array of mappings in some order.
Equations
- m.toArray = Std.DHashMap.Raw.fold (fun (acc : Array ((a : α) × β a)) (k : α) (v : β k) => acc.push ⟨k, v⟩) #[] m
Instances For
Transforms the hash map into a list of mappings in some order.
Equations
- Std.DHashMap.Raw.Const.toList m = Std.DHashMap.Raw.fold (fun (acc : List (α × β)) (k : α) (v : β) => (k, v) :: acc) [] m
Instances For
Transforms the hash map into an array of mappings in some order.
Equations
- Std.DHashMap.Raw.Const.toArray m = Std.DHashMap.Raw.fold (fun (acc : Array (α × β)) (k : α) (v : β) => acc.push (k, v)) #[] m
Instances For
Returns a list of all keys present in the hash map in some order.
Equations
- m.keys = Std.DHashMap.Raw.fold (fun (acc : List α) (k : α) (x : β k) => k :: acc) [] m
Instances For
Returns an array of all keys present in the hash map in some order.
Equations
- m.keysArray = Std.DHashMap.Raw.fold (fun (acc : Array α) (k : α) (x : β k) => acc.push k) #[] m
Instances For
Returns a list of all values present in the hash map in some order.
Equations
- m.values = Std.DHashMap.Raw.fold (fun (acc : List β) (x : α) (v : β) => v :: acc) [] m
Instances For
Returns an array of all values present in the hash map in some order.
Equations
- m.valuesArray = Std.DHashMap.Raw.fold (fun (acc : Array β) (x : α) (v : β) => acc.push v) #[] m
Instances For
Inserts multiple mappings into the hash map by iterating over the given collection and calling
insert
. If the same key appears multiple times, the last occurrence takes precedence.
Equations
- m.insertMany l = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.insertMany ⟨m, h⟩ l).val.val else m
Instances For
Inserts multiple mappings into the hash map by iterating over the given collection and calling
insert
. If the same key appears multiple times, the last occurrence takes precedence.
Equations
- Std.DHashMap.Raw.Const.insertMany m l = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.Const.insertMany ⟨m, h⟩ l).val.val else m
Instances For
Inserts multiple keys with the value ()
into the hash map by iterating over the given collection
and calling insert
. If the same key appears multiple times, the last occurrence takes precedence.
This is mainly useful to implement HashSet.insertMany
, so if you are considering using this,
HashSet
or HashSet.Raw
might be a better fit for you.
Equations
- Std.DHashMap.Raw.Const.insertManyUnit m l = if h : 0 < m.buckets.size then (Std.DHashMap.Internal.Raw₀.Const.insertManyUnit ⟨m, h⟩ l).val.val else m
Instances For
Creates a hash map from a list of mappings. If the same key appears multiple times, the last occurrence takes precedence.
Equations
- Std.DHashMap.Raw.ofList l = ∅.insertMany l
Instances For
Computes the union of the given hash maps, by traversing m₂
and inserting its elements into m₁
.
Equations
- m₁.union m₂ = Std.DHashMap.Raw.fold (fun (acc : Std.DHashMap.Raw α β) (x : α) => acc.insert x) m₁ m₂
Instances For
Equations
- Std.DHashMap.Raw.instUnionOfBEqOfHashable = { union := Std.DHashMap.Raw.union }
Creates a hash map from a list of mappings. If the same key appears multiple times, the last occurrence takes precedence.
Equations
Instances For
Creates a hash map from a list of keys, associating the value ()
with each key.
This is mainly useful to implement HashSet.ofList
, so if you are considering using this,
HashSet
or HashSet.Raw
might be a better fit for you.
Instances For
Creates a hash map from an array of keys, associating the value ()
with each key.
This is mainly useful to implement HashSet.ofArray
, so if you are considering using this,
HashSet
or HashSet.Raw
might be a better fit for you.
Instances For
Returns the number of buckets in the internal representation of the hash map. This function may be useful for things like monitoring system health, but it should be considered an internal implementation detail.
Equations
- Std.DHashMap.Raw.Internal.numBuckets m = m.buckets.size
Instances For
Equations
- Std.DHashMap.Raw.instRepr = { reprPrec := fun (m : Std.DHashMap.Raw α β) (prec : Nat) => Repr.addAppParen (Std.Format.text "Std.DHashMap.Raw.ofList " ++ reprArg m.toList) prec }
Well-formedness predicate for hash maps. Users of DHashMap
will not need to interact with
this. Users of DHashMap.Raw
will need to provide proofs of WF
to lemmas and should use lemmas
like WF.empty
and WF.insert
(which are always named exactly like the operations they are about)
to show that map operations preserve well-formedness. The constructors of this type are internal
implementation details and should not be accessed by users.
- wf: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α β},
0 < m.buckets.size → (∀ [inst_2 : EquivBEq α] [inst_3 : LawfulHashable α], Std.DHashMap.Internal.Raw.WFImp m) → m.WF
Internal implementation detail of the hash map
- empty₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {c : Nat},
(Std.DHashMap.Internal.Raw₀.empty c).val.WF
Internal implementation detail of the hash map
- insert₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α β} {h : 0 < m.buckets.size}
{a : α} {b : β a}, m.WF → (Std.DHashMap.Internal.Raw₀.insert ⟨m, h⟩ a b).val.WF
Internal implementation detail of the hash map
- containsThenInsert₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α β} {h : 0 < m.buckets.size}
{a : α} {b : β a}, m.WF → (Std.DHashMap.Internal.Raw₀.containsThenInsert ⟨m, h⟩ a b).snd.val.WF
Internal implementation detail of the hash map
- containsThenInsertIfNew₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α β} {h : 0 < m.buckets.size}
{a : α} {b : β a}, m.WF → (Std.DHashMap.Internal.Raw₀.containsThenInsertIfNew ⟨m, h⟩ a b).snd.val.WF
Internal implementation detail of the hash map
- erase₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α β} {h : 0 < m.buckets.size}
{a : α}, m.WF → (Std.DHashMap.Internal.Raw₀.erase ⟨m, h⟩ a).val.WF
Internal implementation detail of the hash map
- insertIfNew₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α β} {h : 0 < m.buckets.size}
{a : α} {b : β a}, m.WF → (Std.DHashMap.Internal.Raw₀.insertIfNew ⟨m, h⟩ a b).val.WF
Internal implementation detail of the hash map
- getThenInsertIfNew?₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] [inst_2 : LawfulBEq α] {m : Std.DHashMap.Raw α β}
{h : 0 < m.buckets.size} {a : α} {b : β a},
m.WF → (Std.DHashMap.Internal.Raw₀.getThenInsertIfNew? ⟨m, h⟩ a b).snd.val.WF
Internal implementation detail of the hash map
- filter₀: ∀ {α : Type u} {β : α → Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α β} {h : 0 < m.buckets.size}
{f : (a : α) → β a → Bool}, m.WF → (Std.DHashMap.Internal.Raw₀.filter f ⟨m, h⟩).val.WF
Internal implementation detail of the hash map
- constGetThenInsertIfNew?₀: ∀ {α : Type u} {β : Type v} [inst : BEq α] [inst_1 : Hashable α] {m : Std.DHashMap.Raw α fun (x : α) => β}
{h : 0 < m.buckets.size} {a : α} {b : β},
m.WF → (Std.DHashMap.Internal.Raw₀.Const.getThenInsertIfNew? ⟨m, h⟩ a b).snd.val.WF
Internal implementation detail of the hash map
Instances For
Internal implementation detail of the hash map