path: root/tests/lean/Hashmap/Funs.lean

-- THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS
-- [hashmap]: function definitions
import Base
import Hashmap.Types
open Primitives
namespace hashmap

/- [hashmap::hash_key] -/
def hash_key_fwd (k : Usize) : Result Usize :=
  Result.ret k

/- [hashmap::HashMap::{0}::allocate_slots] -/
divergent def HashMap.allocate_slots_loop_fwd
  (T : Type) (slots : Vec (List T)) (n : Usize) : Result (Vec (List T)) :=
  if n > (Usize.ofInt 0 (by intlit))
  then
    do
      let slots0 ← vec_push_back (List T) slots List.Nil
      let n0 ← n - (Usize.ofInt 1 (by intlit))
      HashMap.allocate_slots_loop_fwd T slots0 n0
  else Result.ret slots

/- [hashmap::HashMap::{0}::allocate_slots] -/
def HashMap.allocate_slots_fwd
  (T : Type) (slots : Vec (List T)) (n : Usize) : Result (Vec (List T)) :=
  HashMap.allocate_slots_loop_fwd T slots n

/- [hashmap::HashMap::{0}::new_with_capacity] -/
def HashMap.new_with_capacity_fwd
  (T : Type) (capacity : Usize) (max_load_dividend : Usize)
  (max_load_divisor : Usize) :
  Result (HashMap T)
  :=
  do
    let v := vec_new (List T)
    let slots ← HashMap.allocate_slots_fwd T v capacity
    let i ← capacity * max_load_dividend
    let i0 ← i / max_load_divisor
    Result.ret
      {
        hash_map_num_entries := (Usize.ofInt 0 (by intlit)),
        hash_map_max_load_factor := (max_load_dividend, max_load_divisor),
        hash_map_max_load := i0,
        hash_map_slots := slots
      }

/- [hashmap::HashMap::{0}::new] -/
def HashMap.new_fwd (T : Type) : Result (HashMap T) :=
  HashMap.new_with_capacity_fwd T (Usize.ofInt 32 (by intlit))
    (Usize.ofInt 4 (by intlit)) (Usize.ofInt 5 (by intlit))

/- [hashmap::HashMap::{0}::clear] -/
divergent def HashMap.clear_loop_fwd_back
  (T : Type) (slots : Vec (List T)) (i : Usize) : Result (Vec (List T)) :=
  let i0 := vec_len (List T) slots
  if i < i0
  then
    do
      let i1 ← i + (Usize.ofInt 1 (by intlit))
      let slots0 ← vec_index_mut_back (List T) slots i List.Nil
      HashMap.clear_loop_fwd_back T slots0 i1
  else Result.ret slots

/- [hashmap::HashMap::{0}::clear] -/
def HashMap.clear_fwd_back
  (T : Type) (self : HashMap T) : Result (HashMap T) :=
  do
    let v ←
      HashMap.clear_loop_fwd_back T self.hash_map_slots
        (Usize.ofInt 0 (by intlit))
    Result.ret
      {
        self
          with
          hash_map_num_entries := (Usize.ofInt 0 (by intlit)),
          hash_map_slots := v
      }

/- [hashmap::HashMap::{0}::len] -/
def HashMap.len_fwd (T : Type) (self : HashMap T) : Result Usize :=
  Result.ret self.hash_map_num_entries

/- [hashmap::HashMap::{0}::insert_in_list] -/
divergent def HashMap.insert_in_list_loop_fwd
  (T : Type) (key : Usize) (value : T) (ls : List T) : Result Bool :=
  match ls with
  | List.Cons ckey cvalue tl =>
    if ckey = key
    then Result.ret false
    else HashMap.insert_in_list_loop_fwd T key value tl
  | List.Nil => Result.ret true

/- [hashmap::HashMap::{0}::insert_in_list] -/
def HashMap.insert_in_list_fwd
  (T : Type) (key : Usize) (value : T) (ls : List T) : Result Bool :=
  HashMap.insert_in_list_loop_fwd T key value ls

/- [hashmap::HashMap::{0}::insert_in_list] -/
divergent def HashMap.insert_in_list_loop_back
  (T : Type) (key : Usize) (value : T) (ls : List T) : Result (List T) :=
  match ls with
  | List.Cons ckey cvalue tl =>
    if ckey = key
    then Result.ret (List.Cons ckey value tl)
    else
      do
        let tl0 ← HashMap.insert_in_list_loop_back T key value tl
        Result.ret (List.Cons ckey cvalue tl0)
  | List.Nil => let l := List.Nil
                Result.ret (List.Cons key value l)

/- [hashmap::HashMap::{0}::insert_in_list] -/
def HashMap.insert_in_list_back
  (T : Type) (key : Usize) (value : T) (ls : List T) : Result (List T) :=
  HashMap.insert_in_list_loop_back T key value ls

/- [hashmap::HashMap::{0}::insert_no_resize] -/
def HashMap.insert_no_resize_fwd_back
  (T : Type) (self : HashMap T) (key : Usize) (value : T) :
  Result (HashMap T)
  :=
  do
    let hash ← hash_key_fwd key
    let i := vec_len (List T) self.hash_map_slots
    let hash_mod ← hash % i
    let l ← vec_index_mut_fwd (List T) self.hash_map_slots hash_mod
    let inserted ← HashMap.insert_in_list_fwd T key value l
    if inserted
    then
      do
        let i0 ← self.hash_map_num_entries + (Usize.ofInt 1 (by intlit))
        let l0 ← HashMap.insert_in_list_back T key value l
        let v ← vec_index_mut_back (List T) self.hash_map_slots hash_mod l0
        Result.ret
          { self with hash_map_num_entries := i0, hash_map_slots := v }
    else
      do
        let l0 ← HashMap.insert_in_list_back T key value l
        let v ← vec_index_mut_back (List T) self.hash_map_slots hash_mod l0
        Result.ret { self with hash_map_slots := v }

/- [core::num::u32::{9}::MAX] -/
def core_num_u32_max_body : Result U32 :=
  Result.ret (U32.ofInt 4294967295 (by intlit))
def core_num_u32_max_c : U32 := eval_global core_num_u32_max_body (by simp)

/- [hashmap::HashMap::{0}::move_elements_from_list] -/
divergent def HashMap.move_elements_from_list_loop_fwd_back
  (T : Type) (ntable : HashMap T) (ls : List T) : Result (HashMap T) :=
  match ls with
  | List.Cons k v tl =>
    do
      let ntable0 ← HashMap.insert_no_resize_fwd_back T ntable k v
      HashMap.move_elements_from_list_loop_fwd_back T ntable0 tl
  | List.Nil => Result.ret ntable

/- [hashmap::HashMap::{0}::move_elements_from_list] -/
def HashMap.move_elements_from_list_fwd_back
  (T : Type) (ntable : HashMap T) (ls : List T) : Result (HashMap T) :=
  HashMap.move_elements_from_list_loop_fwd_back T ntable ls

/- [hashmap::HashMap::{0}::move_elements] -/
divergent def HashMap.move_elements_loop_fwd_back
  (T : Type) (ntable : HashMap T) (slots : Vec (List T)) (i : Usize) :
  Result ((HashMap T) × (Vec (List T)))
  :=
  let i0 := vec_len (List T) slots
  if i < i0
  then
    do
      let l ← vec_index_mut_fwd (List T) slots i
      let ls := mem_replace_fwd (List T) l List.Nil
      let ntable0 ← HashMap.move_elements_from_list_fwd_back T ntable ls
      let i1 ← i + (Usize.ofInt 1 (by intlit))
      let l0 := mem_replace_back (List T) l List.Nil
      let slots0 ← vec_index_mut_back (List T) slots i l0
      HashMap.move_elements_loop_fwd_back T ntable0 slots0 i1
  else Result.ret (ntable, slots)

/- [hashmap::HashMap::{0}::move_elements] -/
def HashMap.move_elements_fwd_back
  (T : Type) (ntable : HashMap T) (slots : Vec (List T)) (i : Usize) :
  Result ((HashMap T) × (Vec (List T)))
  :=
  HashMap.move_elements_loop_fwd_back T ntable slots i

/- [hashmap::HashMap::{0}::try_resize] -/
def HashMap.try_resize_fwd_back
  (T : Type) (self : HashMap T) : Result (HashMap T) :=
  do
    let max_usize ← Scalar.cast .Usize core_num_u32_max_c
    let capacity := vec_len (List T) self.hash_map_slots
    let n1 ← max_usize / (Usize.ofInt 2 (by intlit))
    let (i, i0) := self.hash_map_max_load_factor
    let i1 ← n1 / i
    if capacity <= i1
    then
      do
        let i2 ← capacity * (Usize.ofInt 2 (by intlit))
        let ntable ← HashMap.new_with_capacity_fwd T i2 i i0
        let (ntable0, _) ←
          HashMap.move_elements_fwd_back T ntable self.hash_map_slots
            (Usize.ofInt 0 (by intlit))
        Result.ret
          {
            ntable0
              with
              hash_map_num_entries := self.hash_map_num_entries,
              hash_map_max_load_factor := (i, i0)
          }
    else Result.ret { self with hash_map_max_load_factor := (i, i0) }

/- [hashmap::HashMap::{0}::insert] -/
def HashMap.insert_fwd_back
  (T : Type) (self : HashMap T) (key : Usize) (value : T) :
  Result (HashMap T)
  :=
  do
    let self0 ← HashMap.insert_no_resize_fwd_back T self key value
    let i ← HashMap.len_fwd T self0
    if i > self0.hash_map_max_load
    then HashMap.try_resize_fwd_back T self0
    else Result.ret self0

/- [hashmap::HashMap::{0}::contains_key_in_list] -/
divergent def HashMap.contains_key_in_list_loop_fwd
  (T : Type) (key : Usize) (ls : List T) : Result Bool :=
  match ls with
  | List.Cons ckey t tl =>
    if ckey = key
    then Result.ret true
    else HashMap.contains_key_in_list_loop_fwd T key tl
  | List.Nil => Result.ret false

/- [hashmap::HashMap::{0}::contains_key_in_list] -/
def HashMap.contains_key_in_list_fwd
  (T : Type) (key : Usize) (ls : List T) : Result Bool :=
  HashMap.contains_key_in_list_loop_fwd T key ls

/- [hashmap::HashMap::{0}::contains_key] -/
def HashMap.contains_key_fwd
  (T : Type) (self : HashMap T) (key : Usize) : Result Bool :=
  do
    let hash ← hash_key_fwd key
    let i := vec_len (List T) self.hash_map_slots
    let hash_mod ← hash % i
    let l ← vec_index_fwd (List T) self.hash_map_slots hash_mod
    HashMap.contains_key_in_list_fwd T key l

/- [hashmap::HashMap::{0}::get_in_list] -/
divergent def HashMap.get_in_list_loop_fwd
  (T : Type) (key : Usize) (ls : List T) : Result T :=
  match ls with
  | List.Cons ckey cvalue tl =>
    if ckey = key
    then Result.ret cvalue
    else HashMap.get_in_list_loop_fwd T key tl
  | List.Nil => Result.fail Error.panic

/- [hashmap::HashMap::{0}::get_in_list] -/
def HashMap.get_in_list_fwd
  (T : Type) (key : Usize) (ls : List T) : Result T :=
  HashMap.get_in_list_loop_fwd T key ls

/- [hashmap::HashMap::{0}::get] -/
def HashMap.get_fwd (T : Type) (self : HashMap T) (key : Usize) : Result T :=
  do
    let hash ← hash_key_fwd key
    let i := vec_len (List T) self.hash_map_slots
    let hash_mod ← hash % i
    let l ← vec_index_fwd (List T) self.hash_map_slots hash_mod
    HashMap.get_in_list_fwd T key l

/- [hashmap::HashMap::{0}::get_mut_in_list] -/
divergent def HashMap.get_mut_in_list_loop_fwd
  (T : Type) (ls : List T) (key : Usize) : Result T :=
  match ls with
  | List.Cons ckey cvalue tl =>
    if ckey = key
    then Result.ret cvalue
    else HashMap.get_mut_in_list_loop_fwd T tl key
  | List.Nil => Result.fail Error.panic

/- [hashmap::HashMap::{0}::get_mut_in_list] -/
def HashMap.get_mut_in_list_fwd
  (T : Type) (ls : List T) (key : Usize) : Result T :=
  HashMap.get_mut_in_list_loop_fwd T ls key

/- [hashmap::HashMap::{0}::get_mut_in_list] -/
divergent def HashMap.get_mut_in_list_loop_back
  (T : Type) (ls : List T) (key : Usize) (ret0 : T) : Result (List T) :=
  match ls with
  | List.Cons ckey cvalue tl =>
    if ckey = key
    then Result.ret (List.Cons ckey ret0 tl)
    else
      do
        let tl0 ← HashMap.get_mut_in_list_loop_back T tl key ret0
        Result.ret (List.Cons ckey cvalue tl0)
  | List.Nil => Result.fail Error.panic

/- [hashmap::HashMap::{0}::get_mut_in_list] -/
def HashMap.get_mut_in_list_back
  (T : Type) (ls : List T) (key : Usize) (ret0 : T) : Result (List T) :=
  HashMap.get_mut_in_list_loop_back T ls key ret0

/- [hashmap::HashMap::{0}::get_mut] -/
def HashMap.get_mut_fwd
  (T : Type) (self : HashMap T) (key : Usize) : Result T :=
  do
    let hash ← hash_key_fwd key
    let i := vec_len (List T) self.hash_map_slots
    let hash_mod ← hash % i
    let l ← vec_index_mut_fwd (List T) self.hash_map_slots hash_mod
    HashMap.get_mut_in_list_fwd T l key

/- [hashmap::HashMap::{0}::get_mut] -/
def HashMap.get_mut_back
  (T : Type) (self : HashMap T) (key : Usize) (ret0 : T) :
  Result (HashMap T)
  :=
  do
    let hash ← hash_key_fwd key
    let i := vec_len (List T) self.hash_map_slots
    let hash_mod ← hash % i
    let l ← vec_index_mut_fwd (List T) self.hash_map_slots hash_mod
    let l0 ← HashMap.get_mut_in_list_back T l key ret0
    let v ← vec_index_mut_back (List T) self.hash_map_slots hash_mod l0
    Result.ret { self with hash_map_slots := v }

/- [hashmap::HashMap::{0}::remove_from_list] -/
divergent def HashMap.remove_from_list_loop_fwd
  (T : Type) (key : Usize) (ls : List T) : Result (Option T) :=
  match ls with
  | List.Cons ckey t tl =>
    if ckey = key
    then
      let mv_ls := mem_replace_fwd (List T) (List.Cons ckey t tl) List.Nil
      match mv_ls with
      | List.Cons i cvalue tl0 => Result.ret (Option.some cvalue)
      | List.Nil => Result.fail Error.panic
    else HashMap.remove_from_list_loop_fwd T key tl
  | List.Nil => Result.ret Option.none

/- [hashmap::HashMap::{0}::remove_from_list] -/
def HashMap.remove_from_list_fwd
  (T : Type) (key : Usize) (ls : List T) : Result (Option T) :=
  HashMap.remove_from_list_loop_fwd T key ls

/- [hashmap::HashMap::{0}::remove_from_list] -/
divergent def HashMap.remove_from_list_loop_back
  (T : Type) (key : Usize) (ls : List T) : Result (List T) :=
  match ls with
  | List.Cons ckey t tl =>
    if ckey = key
    then
      let mv_ls := mem_replace_fwd (List T) (List.Cons ckey t tl) List.Nil
      match mv_ls with
      | List.Cons i cvalue tl0 => Result.ret tl0
      | List.Nil => Result.fail Error.panic
    else
      do
        let tl0 ← HashMap.remove_from_list_loop_back T key tl
        Result.ret (List.Cons ckey t tl0)
  | List.Nil => Result.ret List.Nil

/- [hashmap::HashMap::{0}::remove_from_list] -/
def HashMap.remove_from_list_back
  (T : Type) (key : Usize) (ls : List T) : Result (List T) :=
  HashMap.remove_from_list_loop_back T key ls

/- [hashmap::HashMap::{0}::remove] -/
def HashMap.remove_fwd
  (T : Type) (self : HashMap T) (key : Usize) : Result (Option T) :=
  do
    let hash ← hash_key_fwd key
    let i := vec_len (List T) self.hash_map_slots
    let hash_mod ← hash % i
    let l ← vec_index_mut_fwd (List T) self.hash_map_slots hash_mod
    let x ← HashMap.remove_from_list_fwd T key l
    match x with
    | Option.none => Result.ret Option.none
    | Option.some x0 =>
      do
        let _ ← self.hash_map_num_entries - (Usize.ofInt 1 (by intlit))
        Result.ret (Option.some x0)

/- [hashmap::HashMap::{0}::remove] -/
def HashMap.remove_back
  (T : Type) (self : HashMap T) (key : Usize) : Result (HashMap T) :=
  do
    let hash ← hash_key_fwd key
    let i := vec_len (List T) self.hash_map_slots
    let hash_mod ← hash % i
    let l ← vec_index_mut_fwd (List T) self.hash_map_slots hash_mod
    let x ← HashMap.remove_from_list_fwd T key l
    match x with
    | Option.none =>
      do
        let l0 ← HashMap.remove_from_list_back T key l
        let v ← vec_index_mut_back (List T) self.hash_map_slots hash_mod l0
        Result.ret { self with hash_map_slots := v }
    | Option.some x0 =>
      do
        let i0 ← self.hash_map_num_entries - (Usize.ofInt 1 (by intlit))
        let l0 ← HashMap.remove_from_list_back T key l
        let v ← vec_index_mut_back (List T) self.hash_map_slots hash_mod l0
        Result.ret
          { self with hash_map_num_entries := i0, hash_map_slots := v }

/- [hashmap::test1] -/
def test1_fwd : Result Unit :=
  do
    let hm ← HashMap.new_fwd U64
    let hm0 ←
      HashMap.insert_fwd_back U64 hm (Usize.ofInt 0 (by intlit))
        (U64.ofInt 42 (by intlit))
    let hm1 ←
      HashMap.insert_fwd_back U64 hm0 (Usize.ofInt 128 (by intlit))
        (U64.ofInt 18 (by intlit))
    let hm2 ←
      HashMap.insert_fwd_back U64 hm1 (Usize.ofInt 1024 (by intlit))
        (U64.ofInt 138 (by intlit))
    let hm3 ←
      HashMap.insert_fwd_back U64 hm2 (Usize.ofInt 1056 (by intlit))
        (U64.ofInt 256 (by intlit))
    let i ← HashMap.get_fwd U64 hm3 (Usize.ofInt 128 (by intlit))
    if not (i = (U64.ofInt 18 (by intlit)))
    then Result.fail Error.panic
    else
      do
        let hm4 ←
          HashMap.get_mut_back U64 hm3 (Usize.ofInt 1024 (by intlit))
            (U64.ofInt 56 (by intlit))
        let i0 ← HashMap.get_fwd U64 hm4 (Usize.ofInt 1024 (by intlit))
        if not (i0 = (U64.ofInt 56 (by intlit)))
        then Result.fail Error.panic
        else
          do
            let x ← HashMap.remove_fwd U64 hm4 (Usize.ofInt 1024 (by intlit))
            match x with
            | Option.none => Result.fail Error.panic
            | Option.some x0 =>
              if not (x0 = (U64.ofInt 56 (by intlit)))
              then Result.fail Error.panic
              else
                do
                  let hm5 ←
                    HashMap.remove_back U64 hm4 (Usize.ofInt 1024 (by intlit))
                  let i1 ←
                    HashMap.get_fwd U64 hm5 (Usize.ofInt 0 (by intlit))
                  if not (i1 = (U64.ofInt 42 (by intlit)))
                  then Result.fail Error.panic
                  else
                    do
                      let i2 ←
                        HashMap.get_fwd U64 hm5 (Usize.ofInt 128 (by intlit))
                      if not (i2 = (U64.ofInt 18 (by intlit)))
                      then Result.fail Error.panic
                      else
                        do
                          let i3 ←
                            HashMap.get_fwd U64 hm5
                              (Usize.ofInt 1056 (by intlit))
                          if not (i3 = (U64.ofInt 256 (by intlit)))
                          then Result.fail Error.panic
                          else Result.ret ()

/- Unit test for [hashmap::test1] -/
#assert (test1_fwd == .ret ())

end hashmap