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powerset.lean
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powerset.lean
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/-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro
-/
import data.finset.lattice
import data.multiset.powerset
/-!
# The powerset of a finset
> THIS FILE IS SYNCHRONIZED WITH MATHLIB4.
> Any changes to this file require a corresponding PR to mathlib4.
-/
namespace finset
open function multiset
variables {α : Type*} {s t : finset α}
/-! ### powerset -/
section powerset
/-- When `s` is a finset, `s.powerset` is the finset of all subsets of `s` (seen as finsets). -/
def powerset (s : finset α) : finset (finset α) :=
⟨s.1.powerset.pmap finset.mk $ λ t h, nodup_of_le (mem_powerset.1 h) s.nodup,
s.nodup.powerset.pmap $ λ a ha b hb, congr_arg finset.val⟩
@[simp] theorem mem_powerset {s t : finset α} : s ∈ powerset t ↔ s ⊆ t :=
by cases s; simp only [powerset, mem_mk, mem_pmap, mem_powerset, exists_prop, exists_eq_right];
rw ← val_le_iff
@[simp, norm_cast] lemma coe_powerset (s : finset α) :
(s.powerset : set (finset α)) = coe ⁻¹' (s : set α).powerset :=
by { ext, simp }
@[simp] theorem empty_mem_powerset (s : finset α) : ∅ ∈ powerset s :=
mem_powerset.2 (empty_subset _)
@[simp] lemma mem_powerset_self (s : finset α) : s ∈ powerset s := mem_powerset.2 subset.rfl
lemma powerset_nonempty (s : finset α) : s.powerset.nonempty := ⟨∅, empty_mem_powerset _⟩
@[simp] theorem powerset_mono {s t : finset α} : powerset s ⊆ powerset t ↔ s ⊆ t :=
⟨λ h, (mem_powerset.1 $ h $ mem_powerset_self _),
λ st u h, mem_powerset.2 $ subset.trans (mem_powerset.1 h) st⟩
lemma powerset_injective : injective (powerset : finset α → finset (finset α)) :=
injective_of_le_imp_le _ $ λ s t, powerset_mono.1
@[simp] lemma powerset_inj : powerset s = powerset t ↔ s = t := powerset_injective.eq_iff
@[simp] lemma powerset_empty : (∅ : finset α).powerset = {∅} := rfl
@[simp] lemma powerset_eq_singleton_empty : s.powerset = {∅} ↔ s = ∅ :=
by rw [←powerset_empty, powerset_inj]
/-- **Number of Subsets of a Set** -/
@[simp] theorem card_powerset (s : finset α) :
card (powerset s) = 2 ^ card s :=
(card_pmap _ _ _).trans (card_powerset s.1)
lemma not_mem_of_mem_powerset_of_not_mem {s t : finset α} {a : α}
(ht : t ∈ s.powerset) (h : a ∉ s) : a ∉ t :=
by { apply mt _ h, apply mem_powerset.1 ht }
lemma powerset_insert [decidable_eq α] (s : finset α) (a : α) :
powerset (insert a s) = s.powerset ∪ s.powerset.image (insert a) :=
begin
ext t,
simp only [exists_prop, mem_powerset, mem_image, mem_union, subset_insert_iff],
by_cases h : a ∈ t,
{ split,
{ exact λH, or.inr ⟨_, H, insert_erase h⟩ },
{ intros H,
cases H,
{ exact subset.trans (erase_subset a t) H },
{ rcases H with ⟨u, hu⟩,
rw ← hu.2,
exact subset.trans (erase_insert_subset a u) hu.1 } } },
{ have : ¬ ∃ (u : finset α), u ⊆ s ∧ insert a u = t,
by simp [ne.symm (ne_insert_of_not_mem _ _ h)],
simp [finset.erase_eq_of_not_mem h, this] }
end
/-- For predicate `p` decidable on subsets, it is decidable whether `p` holds for any subset. -/
instance decidable_exists_of_decidable_subsets {s : finset α} {p : Π t ⊆ s, Prop}
[Π t (h : t ⊆ s), decidable (p t h)] : decidable (∃ t (h : t ⊆ s), p t h) :=
decidable_of_iff (∃ t (hs : t ∈ s.powerset), p t (mem_powerset.1 hs))
⟨(λ ⟨t, _, hp⟩, ⟨t, _, hp⟩), (λ ⟨t, hs, hp⟩, ⟨t, mem_powerset.2 hs, hp⟩)⟩
/-- For predicate `p` decidable on subsets, it is decidable whether `p` holds for every subset. -/
instance decidable_forall_of_decidable_subsets {s : finset α} {p : Π t ⊆ s, Prop}
[Π t (h : t ⊆ s), decidable (p t h)] : decidable (∀ t (h : t ⊆ s), p t h) :=
decidable_of_iff (∀ t (h : t ∈ s.powerset), p t (mem_powerset.1 h))
⟨(λ h t hs, h t (mem_powerset.2 hs)), (λ h _ _, h _ _)⟩
/-- A version of `finset.decidable_exists_of_decidable_subsets` with a non-dependent `p`.
Typeclass inference cannot find `hu` here, so this is not an instance. -/
def decidable_exists_of_decidable_subsets' {s : finset α} {p : finset α → Prop}
(hu : Π t (h : t ⊆ s), decidable (p t)) : decidable (∃ t (h : t ⊆ s), p t) :=
@finset.decidable_exists_of_decidable_subsets _ _ _ hu
/-- A version of `finset.decidable_forall_of_decidable_subsets` with a non-dependent `p`.
Typeclass inference cannot find `hu` here, so this is not an instance. -/
def decidable_forall_of_decidable_subsets' {s : finset α} {p : finset α → Prop}
(hu : Π t (h : t ⊆ s), decidable (p t)) : decidable (∀ t (h : t ⊆ s), p t) :=
@finset.decidable_forall_of_decidable_subsets _ _ _ hu
end powerset
section ssubsets
variables [decidable_eq α]
/-- For `s` a finset, `s.ssubsets` is the finset comprising strict subsets of `s`. -/
def ssubsets (s : finset α) : finset (finset α) :=
erase (powerset s) s
@[simp] lemma mem_ssubsets {s t : finset α} : t ∈ s.ssubsets ↔ t ⊂ s :=
by rw [ssubsets, mem_erase, mem_powerset, ssubset_iff_subset_ne, and.comm]
lemma empty_mem_ssubsets {s : finset α} (h : s.nonempty) : ∅ ∈ s.ssubsets :=
by { rw [mem_ssubsets, ssubset_iff_subset_ne], exact ⟨empty_subset s, h.ne_empty.symm⟩, }
/-- For predicate `p` decidable on ssubsets, it is decidable whether `p` holds for any ssubset. -/
instance decidable_exists_of_decidable_ssubsets {s : finset α} {p : Π t ⊂ s, Prop}
[Π t (h : t ⊂ s), decidable (p t h)] : decidable (∃ t h, p t h) :=
decidable_of_iff (∃ t (hs : t ∈ s.ssubsets), p t (mem_ssubsets.1 hs))
⟨(λ ⟨t, _, hp⟩, ⟨t, _, hp⟩), (λ ⟨t, hs, hp⟩, ⟨t, mem_ssubsets.2 hs, hp⟩)⟩
/-- For predicate `p` decidable on ssubsets, it is decidable whether `p` holds for every ssubset. -/
instance decidable_forall_of_decidable_ssubsets {s : finset α} {p : Π t ⊂ s, Prop}
[Π t (h : t ⊂ s), decidable (p t h)] : decidable (∀ t h, p t h) :=
decidable_of_iff (∀ t (h : t ∈ s.ssubsets), p t (mem_ssubsets.1 h))
⟨(λ h t hs, h t (mem_ssubsets.2 hs)), (λ h _ _, h _ _)⟩
/-- A version of `finset.decidable_exists_of_decidable_ssubsets` with a non-dependent `p`.
Typeclass inference cannot find `hu` here, so this is not an instance. -/
def decidable_exists_of_decidable_ssubsets' {s : finset α} {p : finset α → Prop}
(hu : Π t (h : t ⊂ s), decidable (p t)) : decidable (∃ t (h : t ⊂ s), p t) :=
@finset.decidable_exists_of_decidable_ssubsets _ _ _ _ hu
/-- A version of `finset.decidable_forall_of_decidable_ssubsets` with a non-dependent `p`.
Typeclass inference cannot find `hu` here, so this is not an instance. -/
def decidable_forall_of_decidable_ssubsets' {s : finset α} {p : finset α → Prop}
(hu : Π t (h : t ⊂ s), decidable (p t)) : decidable (∀ t (h : t ⊂ s), p t) :=
@finset.decidable_forall_of_decidable_ssubsets _ _ _ _ hu
end ssubsets
section powerset_len
/-- Given an integer `n` and a finset `s`, then `powerset_len n s` is the finset of subsets of `s`
of cardinality `n`. -/
def powerset_len (n : ℕ) (s : finset α) : finset (finset α) :=
⟨(s.1.powerset_len n).pmap finset.mk $ λ t h, nodup_of_le (mem_powerset_len.1 h).1 s.2,
s.2.powerset_len.pmap $ λ a ha b hb, congr_arg finset.val⟩
/-- **Formula for the Number of Combinations** -/
theorem mem_powerset_len {n} {s t : finset α} :
s ∈ powerset_len n t ↔ s ⊆ t ∧ card s = n :=
by cases s; simp [powerset_len, val_le_iff.symm]; refl
@[simp] theorem powerset_len_mono {n} {s t : finset α} (h : s ⊆ t) :
powerset_len n s ⊆ powerset_len n t :=
λ u h', mem_powerset_len.2 $
and.imp (λ h₂, subset.trans h₂ h) id (mem_powerset_len.1 h')
/-- **Formula for the Number of Combinations** -/
@[simp] theorem card_powerset_len (n : ℕ) (s : finset α) :
card (powerset_len n s) = nat.choose (card s) n :=
(card_pmap _ _ _).trans (card_powerset_len n s.1)
@[simp] lemma powerset_len_zero (s : finset α) : finset.powerset_len 0 s = {∅} :=
begin
ext, rw [mem_powerset_len, mem_singleton, card_eq_zero],
refine ⟨λ h, h.2, λ h, by { rw h, exact ⟨empty_subset s, rfl⟩ }⟩,
end
@[simp] theorem powerset_len_empty (n : ℕ) {s : finset α} (h : s.card < n) :
powerset_len n s = ∅ :=
finset.card_eq_zero.mp (by rw [card_powerset_len, nat.choose_eq_zero_of_lt h])
theorem powerset_len_eq_filter {n} {s : finset α} :
powerset_len n s = (powerset s).filter (λ x, x.card = n) :=
by { ext, simp [mem_powerset_len] }
lemma powerset_len_succ_insert [decidable_eq α] {x : α} {s : finset α} (h : x ∉ s) (n : ℕ) :
powerset_len n.succ (insert x s) = powerset_len n.succ s ∪ (powerset_len n s).image (insert x) :=
begin
rw [powerset_len_eq_filter, powerset_insert, filter_union, ←powerset_len_eq_filter],
congr,
rw [powerset_len_eq_filter, image_filter],
congr' 1,
ext t,
simp only [mem_powerset, mem_filter, function.comp_app, and.congr_right_iff],
intro ht,
have : x ∉ t := λ H, h (ht H),
simp [card_insert_of_not_mem this, nat.succ_inj']
end
lemma powerset_len_nonempty {n : ℕ} {s : finset α} (h : n ≤ s.card) :
(powerset_len n s).nonempty :=
begin
classical,
induction s using finset.induction_on with x s hx IH generalizing n,
{ rw [card_empty, le_zero_iff] at h,
rw [h, powerset_len_zero],
exact finset.singleton_nonempty _, },
{ cases n,
{ simp },
{ rw [card_insert_of_not_mem hx, nat.succ_le_succ_iff] at h,
rw powerset_len_succ_insert hx,
refine nonempty.mono _ ((IH h).image (insert x)),
convert (subset_union_right _ _) } }
end
@[simp] lemma powerset_len_self (s : finset α) :
powerset_len s.card s = {s} :=
begin
ext,
rw [mem_powerset_len, mem_singleton],
split,
{ exact λ ⟨hs, hc⟩, eq_of_subset_of_card_le hs hc.ge },
{ rintro rfl,
simp }
end
lemma pairwise_disjoint_powerset_len (s : finset α) :
_root_.pairwise (λ i j, disjoint (s.powerset_len i) (s.powerset_len j)) :=
λ i j hij, finset.disjoint_left.mpr $ λ x hi hj, hij $
(mem_powerset_len.mp hi).2.symm.trans (mem_powerset_len.mp hj).2
lemma powerset_card_disj_Union (s : finset α) :
finset.powerset s =
(range (s.card + 1)).disj_Union (λ i, powerset_len i s)
(s.pairwise_disjoint_powerset_len.set_pairwise _) :=
begin
refine ext (λ a, ⟨λ ha, _, λ ha, _ ⟩),
{ rw mem_disj_Union,
exact ⟨a.card, mem_range.mpr (nat.lt_succ_of_le (card_le_of_subset (mem_powerset.mp ha))),
mem_powerset_len.mpr ⟨mem_powerset.mp ha, rfl⟩⟩ },
{ rcases mem_disj_Union.mp ha with ⟨i, hi, ha⟩,
exact mem_powerset.mpr (mem_powerset_len.mp ha).1, }
end
lemma powerset_card_bUnion [decidable_eq (finset α)] (s : finset α) :
finset.powerset s = (range (s.card + 1)).bUnion (λ i, powerset_len i s) :=
by simpa only [disj_Union_eq_bUnion] using powerset_card_disj_Union s
lemma powerset_len_sup [decidable_eq α] (u : finset α) (n : ℕ) (hn : n < u.card) :
(powerset_len n.succ u).sup id = u :=
begin
apply le_antisymm,
{ simp_rw [finset.sup_le_iff, mem_powerset_len],
rintros x ⟨h, -⟩,
exact h },
{ rw [sup_eq_bUnion, le_iff_subset, subset_iff],
cases (nat.succ_le_of_lt hn).eq_or_lt with h' h',
{ simp [h'] },
{ intros x hx,
simp only [mem_bUnion, exists_prop, id.def],
obtain ⟨t, ht⟩ : ∃ t, t ∈ powerset_len n (u.erase x) := powerset_len_nonempty _,
{ refine ⟨insert x t, _, mem_insert_self _ _⟩,
rw [←insert_erase hx, powerset_len_succ_insert (not_mem_erase _ _)],
exact mem_union_right _ (mem_image_of_mem _ ht) },
{ rw [card_erase_of_mem hx],
exact nat.le_pred_of_lt hn, } } }
end
@[simp]
lemma powerset_len_card_add (s : finset α) {i : ℕ} (hi : 0 < i) :
s.powerset_len (s.card + i) = ∅ :=
finset.powerset_len_empty _ (lt_add_of_pos_right (finset.card s) hi)
@[simp] theorem map_val_val_powerset_len (s : finset α) (i : ℕ) :
(s.powerset_len i).val.map finset.val = s.1.powerset_len i :=
by simp [finset.powerset_len, map_pmap, pmap_eq_map, map_id']
theorem powerset_len_map {β : Type*} (f : α ↪ β) (n : ℕ) (s : finset α) :
powerset_len n (s.map f) = (powerset_len n s).map (map_embedding f).to_embedding :=
eq_of_veq $ multiset.map_injective (@eq_of_veq _) $
by simp_rw [map_val_val_powerset_len, map_val, multiset.map_map, function.comp,
rel_embedding.coe_fn_to_embedding, map_embedding_apply, map_val, ←multiset.map_map _ val,
map_val_val_powerset_len, multiset.powerset_len_map]
end powerset_len
end finset