Source Edit

The tables module implements variants of an efficient hash table (also often named dictionary in other programming languages) that is a mapping from keys to values.

There are several different types of hash tables available:

  • Table is the usual hash table,
  • OrderedTable is like Table but remembers insertion order,
  • CountTable is a mapping from a key to its number of occurrences

For consistency with every other data type in Nim these have value semantics, this means that \= performs a copy of the hash table.

For ref semantics use their Ref variants: TableRef, OrderedTableRef, and CountTableRef.

To give an example, when a is a Table, then var b = a gives b as a new independent table. b is initialised with the contents of a. Changing b does not affect a and vice versa:

Example:

  1. import std/tables
  2. var
  3. a = {1: "one", 2: "two"}.toTable # creates a Table
  4. b = a
  5. assert a == b
  6. b[3] = "three"
  7. assert 3 notin a
  8. assert 3 in b
  9. assert a != b

On the other hand, when a is a TableRef instead, then changes to b also affect a. Both a and b ref the same data structure:

Example:

  1. import std/tables
  2. var
  3. a = {1: "one", 2: "two"}.newTable # creates a TableRef
  4. b = a
  5. assert a == b
  6. b[3] = "three"
  7. assert 3 in a
  8. assert 3 in b
  9. assert a == b

Basic usage

Table

Example:

  1. import std/tables
  2. from std/sequtils import zip
  3. let
  4. names = ["John", "Paul", "George", "Ringo"]
  5. years = [1940, 1942, 1943, 1940]
  6. var beatles = initTable[string, int]()
  7. for pairs in zip(names, years):
  8. let (name, birthYear) = pairs
  9. beatles[name] = birthYear
  10. assert beatles == {"George": 1943, "Ringo": 1940, "Paul": 1942, "John": 1940}.toTable
  11. var beatlesByYear = initTable[int, seq[string]]()
  12. for pairs in zip(years, names):
  13. let (birthYear, name) = pairs
  14. if not beatlesByYear.hasKey(birthYear):
  15. # if a key doesn't exist, we create one with an empty sequence
  16. # before we can add elements to it
  17. beatlesByYear[birthYear] = @[]
  18. beatlesByYear[birthYear].add(name)
  19. assert beatlesByYear == {1940: @["John", "Ringo"], 1942: @["Paul"], 1943: @["George"]}.toTable

OrderedTable

OrderedTable is used when it is important to preserve the insertion order of keys.

Example:

  1. import std/tables
  2. let
  3. a = [('z', 1), ('y', 2), ('x', 3)]
  4. ot = a.toOrderedTable # ordered tables
  5. assert $ot == """{'z': 1, 'y': 2, 'x': 3}"""

CountTable

CountTable is useful for counting number of items of some container (e.g. string, sequence or array), as it is a mapping where the items are the keys, and their number of occurrences are the values. For that purpose toCountTable proc comes handy:

Example:

  1. import std/tables
  2. let myString = "abracadabra"
  3. let letterFrequencies = toCountTable(myString)
  4. assert $letterFrequencies == "{'a': 5, 'd': 1, 'b': 2, 'r': 2, 'c': 1}"

The same could have been achieved by manually iterating over a container and increasing each key’s value with inc proc:

Example:

  1. import std/tables
  2. let myString = "abracadabra"
  3. var letterFrequencies = initCountTable[char]()
  4. for c in myString:
  5. letterFrequencies.inc(c)
  6. assert $letterFrequencies == "{'d': 1, 'r': 2, 'c': 1, 'a': 5, 'b': 2}"

Hashing

If you are using simple standard types like int or string for the keys of the table you won’t have any problems, but as soon as you try to use a more complex object as a key you will be greeted by a strange compiler error:

  1. Error: type mismatch: got (Person)
  2. but expected one of:
  3. hashes.hash(x: openArray[A]): Hash
  4. hashes.hash(x: int): Hash
  5. hashes.hash(x: float): Hash

What is happening here is that the types used for table keys require to have a hash() proc which will convert them to a Hash value, and the compiler is listing all the hash functions it knows. Additionally there has to be a \== operator that provides the same semantics as its corresponding hash proc.

After you add hash and \== for your custom type everything will work. Currently, however, hash for objects is not defined, whereas system.== for objects does exist and performs a “deep” comparison (every field is compared) which is usually what you want. So in the following example implementing only hash suffices:

Example:

  1. import std/tables
  2. import std/hashes
  3. type
  4. Person = object
  5. firstName, lastName: string
  6. proc hash(x: Person): Hash =
  7. ## Piggyback on the already available string hash proc.
  8. ##
  9. ## Without this proc nothing works!
  10. result = x.firstName.hash !& x.lastName.hash
  11. result = !$result
  12. var
  13. salaries = initTable[Person, int]()
  14. p1, p2: Person
  15. p1.firstName = "Jon"
  16. p1.lastName = "Ross"
  17. salaries[p1] = 30_000
  18. p2.firstName = "소진"
  19. p2.lastName = "박"
  20. salaries[p2] = 45_000

See also

  • json module for table-like structure which allows heterogeneous members
  • strtabs module for efficient hash tables mapping from strings to strings
  • hashes module for helper functions for hashing

Imports

since, hashes, math, algorithm, outparams

Types

  1. CountTable[A] = object

Hash table that counts the number of each key.

For creating an empty CountTable, use initCountTable proc.

Source Edit

  1. CountTableRef[A] = ref CountTable[A]

Ref version of CountTable.

For creating a new empty CountTableRef, use newCountTable proc.

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  1. OrderedTable[A; B] = object

Hash table that remembers insertion order.

For creating an empty OrderedTable, use initOrderedTable proc.

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  1. OrderedTableRef[A; B] = ref OrderedTable[A, B]

Ref version of OrderedTable.

For creating a new empty OrderedTableRef, use newOrderedTable proc.

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  1. Table[A; B] = object

Generic hash table, consisting of a key-value pair.

data and counter are internal implementation details which can’t be accessed.

For creating an empty Table, use initTable proc.

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  1. TableRef[A; B] = ref Table[A, B]

Ref version of Table.

For creating a new empty TableRef, use newTable proc.

Source Edit

Consts

  1. defaultInitialSize = 32

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Procs

  1. proc `$`[A, B](t: OrderedTable[A, B]): string

The $ operator for ordered hash tables. Used internally when calling echo on a table. Source Edit

  1. proc `$`[A, B](t: OrderedTableRef[A, B]): string

The $ operator for hash tables. Used internally when calling echo on a table. Source Edit

  1. proc `$`[A, B](t: Table[A, B]): string

The $ operator for hash tables. Used internally when calling echo on a table. Source Edit

  1. proc `$`[A, B](t: TableRef[A, B]): string

The $ operator for hash tables. Used internally when calling echo on a table. Source Edit

  1. proc `$`[A](t: CountTable[A]): string

The $ operator for count tables. Used internally when calling echo on a table. Source Edit

  1. proc `$`[A](t: CountTableRef[A]): string

The $ operator for count tables. Used internally when calling echo on a table. Source Edit

  1. proc `==`[A, B](s, t: OrderedTable[A, B]): bool

The \== operator for ordered hash tables. Returns true if both the content and the order are equal.

Example:

  1. let
  2. a = {'a': 5, 'b': 9, 'c': 13}.toOrderedTable
  3. b = {'b': 9, 'c': 13, 'a': 5}.toOrderedTable
  4. doAssert a != b

Source Edit

  1. proc `==`[A, B](s, t: OrderedTableRef[A, B]): bool

The \== operator for ordered hash tables. Returns true if either both tables are nil, or neither is nil and the content and the order of both are equal.

Example:

  1. let
  2. a = {'a': 5, 'b': 9, 'c': 13}.newOrderedTable
  3. b = {'b': 9, 'c': 13, 'a': 5}.newOrderedTable
  4. doAssert a != b

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  1. proc `==`[A, B](s, t: Table[A, B]): bool

The \== operator for hash tables. Returns true if the content of both tables contains the same key-value pairs. Insert order does not matter.

Example:

  1. let
  2. a = {'a': 5, 'b': 9, 'c': 13}.toTable
  3. b = {'b': 9, 'c': 13, 'a': 5}.toTable
  4. doAssert a == b

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  1. proc `==`[A, B](s, t: TableRef[A, B]): bool

The \== operator for hash tables. Returns true if either both tables are nil, or neither is nil and the content of both tables contains the same key-value pairs. Insert order does not matter.

Example:

  1. let
  2. a = {'a': 5, 'b': 9, 'c': 13}.newTable
  3. b = {'b': 9, 'c': 13, 'a': 5}.newTable
  4. doAssert a == b

Source Edit

  1. proc `==`[A](s, t: CountTable[A]): bool

The \== operator for count tables. Returns true if both tables contain the same keys with the same count. Insert order does not matter. Source Edit

  1. proc `==`[A](s, t: CountTableRef[A]): bool

The \== operator for count tables. Returns true if either both tables are nil, or neither is nil and both contain the same keys with the same count. Insert order does not matter. Source Edit

  1. proc `[]`[A, B](t: OrderedTable[A, B]; key: A): lent B

Retrieves the value at t[key].

If key is not in t, the KeyError exception is raised. One can check with hasKey proc whether the key exists.

See also:

  • getOrDefault proc to return a default value (e.g. zero for int) if the key doesn’t exist
  • getOrDefault proc to return a custom value if the key doesn’t exist
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Example:

  1. let a = {'a': 5, 'b': 9}.toOrderedTable
  2. doAssert a['a'] == 5
  3. doAssertRaises(KeyError):
  4. echo a['z']

Source Edit

  1. proc `[]`[A, B](t: OrderedTableRef[A, B]; key: A): var B

Retrieves the value at t[key].

If key is not in t, the KeyError exception is raised. One can check with hasKey proc whether the key exists.

See also:

  • getOrDefault proc to return a default value (e.g. zero for int) if the key doesn’t exist
  • getOrDefault proc to return a custom value if the key doesn’t exist
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Example:

  1. let a = {'a': 5, 'b': 9}.newOrderedTable
  2. doAssert a['a'] == 5
  3. doAssertRaises(KeyError):
  4. echo a['z']

Source Edit

  1. proc `[]`[A, B](t: Table[A, B]; key: A): lent B

Retrieves the value at t[key].

If key is not in t, the KeyError exception is raised. One can check with hasKey proc whether the key exists.

See also:

  • getOrDefault proc to return a default value (e.g. zero for int) if the key doesn’t exist
  • getOrDefault proc to return a custom value if the key doesn’t exist
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Example:

  1. let a = {'a': 5, 'b': 9}.toTable
  2. doAssert a['a'] == 5
  3. doAssertRaises(KeyError):
  4. echo a['z']

Source Edit

  1. proc `[]`[A, B](t: TableRef[A, B]; key: A): var B

Retrieves the value at t[key].

If key is not in t, the KeyError exception is raised. One can check with hasKey proc whether the key exists.

See also:

  • getOrDefault proc to return a default value (e.g. zero for int) if the key doesn’t exist
  • getOrDefault proc to return a custom value if the key doesn’t exist
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Example:

  1. let a = {'a': 5, 'b': 9}.newTable
  2. doAssert a['a'] == 5
  3. doAssertRaises(KeyError):
  4. echo a['z']

Source Edit

  1. proc `[]`[A, B](t: var OrderedTable[A, B]; key: A): var B

Retrieves the value at t[key]. The value can be modified.

If key is not in t, the KeyError exception is raised.

See also:

  • getOrDefault proc to return a default value (e.g. zero for int) if the key doesn’t exist
  • getOrDefault proc to return a custom value if the key doesn’t exist
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Source Edit

  1. proc `[]`[A, B](t: var Table[A, B]; key: A): var B

Retrieves the value at t[key]. The value can be modified.

If key is not in t, the KeyError exception is raised.

See also:

  • getOrDefault proc to return a default value (e.g. zero for int) if the key doesn’t exist
  • getOrDefault proc to return a custom value if the key doesn’t exist
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Source Edit

  1. proc `[]`[A](t: CountTable[A]; key: A): int

Retrieves the value at t[key] if key is in t. Otherwise 0 is returned.

See also:

  • getOrDefault to return a custom value if the key doesn’t exist
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Source Edit

  1. proc `[]`[A](t: CountTableRef[A]; key: A): int

Retrieves the value at t[key] if key is in t. Otherwise 0 is returned.

See also:

  • getOrDefault to return a custom value if the key doesn’t exist
  • inc proc to inc even if missing
  • []= proc for inserting a new (key, value) pair in the table
  • hasKey proc for checking if a key is in the table

Source Edit

  1. proc `[]=`[A, B](t: OrderedTableRef[A, B]; key: A; val: sink B)

Inserts a (key, value) pair into t.

See also:

Example:

  1. var a = newOrderedTable[char, int]()
  2. a['x'] = 7
  3. a['y'] = 33
  4. doAssert a == {'x': 7, 'y': 33}.newOrderedTable

Source Edit

  1. proc `[]=`[A, B](t: TableRef[A, B]; key: A; val: sink B)

Inserts a (key, value) pair into t.

See also:

Example:

  1. var a = newTable[char, int]()
  2. a['x'] = 7
  3. a['y'] = 33
  4. doAssert a == {'x': 7, 'y': 33}.newTable

Source Edit

  1. proc `[]=`[A, B](t: var OrderedTable[A, B]; key: A; val: sink B)

Inserts a (key, value) pair into t.

See also:

Example:

  1. var a = initOrderedTable[char, int]()
  2. a['x'] = 7
  3. a['y'] = 33
  4. doAssert a == {'x': 7, 'y': 33}.toOrderedTable

Source Edit

  1. proc `[]=`[A, B](t: var Table[A, B]; key: A; val: sink B)

Inserts a (key, value) pair into t.

See also:

Example:

  1. var a = initTable[char, int]()
  2. a['x'] = 7
  3. a['y'] = 33
  4. doAssert a == {'x': 7, 'y': 33}.toTable

Source Edit

  1. proc `[]=`[A](t: CountTableRef[A]; key: A; val: int)

Inserts a (key, value) pair into t.

See also:

  • [] proc for retrieving a value of a key
  • inc proc for incrementing a value of a key

Source Edit

  1. proc `[]=`[A](t: var CountTable[A]; key: A; val: int)

Inserts a (key, value) pair into t.

See also:

  • [] proc for retrieving a value of a key
  • inc proc for incrementing a value of a key

Source Edit

  1. proc add[A, B](t: OrderedTableRef[A, B]; key: A; val: sink B) {....deprecated: "Deprecated since v1.4; it was more confusing than useful, use `[]=`".}

Deprecated: Deprecated since v1.4; it was more confusing than useful, use `[]=`

Puts a new (key, value) pair into t even if t[key] already exists.

This can introduce duplicate keys into the table!

Use []= proc for inserting a new (key, value) pair in the table without introducing duplicates.

Source Edit

  1. proc add[A, B](t: TableRef[A, B]; key: A; val: sink B) {....deprecated: "Deprecated since v1.4; it was more confusing than useful, use `[]=`".}

Deprecated: Deprecated since v1.4; it was more confusing than useful, use `[]=`

Puts a new (key, value) pair into t even if t[key] already exists.

This can introduce duplicate keys into the table!

Use []= proc for inserting a new (key, value) pair in the table without introducing duplicates.

Source Edit

  1. proc add[A, B](t: var OrderedTable[A, B]; key: A; val: sink B) {....deprecated: "Deprecated since v1.4; it was more confusing than useful, use `[]=`".}

Deprecated: Deprecated since v1.4; it was more confusing than useful, use `[]=`

Puts a new (key, value) pair into t even if t[key] already exists.

This can introduce duplicate keys into the table!

Use []= proc for inserting a new (key, value) pair in the table without introducing duplicates.

Source Edit

  1. proc add[A, B](t: var Table[A, B]; key: A; val: sink B) {....deprecated: "Deprecated since v1.4; it was more confusing than useful, use `[]=`".}

Deprecated: Deprecated since v1.4; it was more confusing than useful, use `[]=`

Puts a new (key, value) pair into t even if t[key] already exists.

This can introduce duplicate keys into the table!

Use []= proc for inserting a new (key, value) pair in the table without introducing duplicates.

Source Edit

  1. proc clear[A, B](t: OrderedTableRef[A, B])

Resets the table so that it is empty.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.newOrderedTable
  2. doAssert len(a) == 3
  3. clear(a)
  4. doAssert len(a) == 0

Source Edit

  1. proc clear[A, B](t: TableRef[A, B])

Resets the table so that it is empty.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.newTable
  2. doAssert len(a) == 3
  3. clear(a)
  4. doAssert len(a) == 0

Source Edit

  1. proc clear[A, B](t: var OrderedTable[A, B])

Resets the table so that it is empty.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.toOrderedTable
  2. doAssert len(a) == 3
  3. clear(a)
  4. doAssert len(a) == 0

Source Edit

  1. proc clear[A, B](t: var Table[A, B])

Resets the table so that it is empty.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.toTable
  2. doAssert len(a) == 3
  3. clear(a)
  4. doAssert len(a) == 0

Source Edit

  1. proc clear[A](t: CountTableRef[A])

Resets the table so that it is empty.

See also:

Source Edit

  1. proc clear[A](t: var CountTable[A])

Resets the table so that it is empty.

See also:

Source Edit

  1. proc contains[A, B](t: OrderedTable[A, B]; key: A): bool

Alias of hasKey proc for use with the in operator.

Example:

  1. let a = {'a': 5, 'b': 9}.toOrderedTable
  2. doAssert 'b' in a == true
  3. doAssert a.contains('z') == false

Source Edit

  1. proc contains[A, B](t: OrderedTableRef[A, B]; key: A): bool

Alias of hasKey proc for use with the in operator.

Example:

  1. let a = {'a': 5, 'b': 9}.newOrderedTable
  2. doAssert 'b' in a == true
  3. doAssert a.contains('z') == false

Source Edit

  1. proc contains[A, B](t: Table[A, B]; key: A): bool

Alias of hasKey proc for use with the in operator.

Example:

  1. let a = {'a': 5, 'b': 9}.toTable
  2. doAssert 'b' in a == true
  3. doAssert a.contains('z') == false

Source Edit

  1. proc contains[A, B](t: TableRef[A, B]; key: A): bool

Alias of hasKey proc for use with the in operator.

Example:

  1. let a = {'a': 5, 'b': 9}.newTable
  2. doAssert 'b' in a == true
  3. doAssert a.contains('z') == false

Source Edit

  1. proc contains[A](t: CountTable[A]; key: A): bool

Alias of hasKey proc for use with the in operator. Source Edit

  1. proc contains[A](t: CountTableRef[A]; key: A): bool

Alias of hasKey proc for use with the in operator. Source Edit

  1. proc del[A, B](t: OrderedTableRef[A, B]; key: A)

Deletes key from hash table t. Does nothing if the key does not exist.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.newOrderedTable
  2. a.del('a')
  3. doAssert a == {'b': 9, 'c': 13}.newOrderedTable
  4. a.del('z')
  5. doAssert a == {'b': 9, 'c': 13}.newOrderedTable

Source Edit

  1. proc del[A, B](t: TableRef[A, B]; key: A)

Deletes key from hash table t. Does nothing if the key does not exist.

Warning: If duplicate keys were added (via the now deprecated add proc), this may need to be called multiple times.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.newTable
  2. a.del('a')
  3. doAssert a == {'b': 9, 'c': 13}.newTable
  4. a.del('z')
  5. doAssert a == {'b': 9, 'c': 13}.newTable

Source Edit

  1. proc del[A, B](t: var OrderedTable[A, B]; key: A)

Deletes key from hash table t. Does nothing if the key does not exist.

O(n) complexity.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.toOrderedTable
  2. a.del('a')
  3. doAssert a == {'b': 9, 'c': 13}.toOrderedTable
  4. a.del('z')
  5. doAssert a == {'b': 9, 'c': 13}.toOrderedTable

Source Edit

  1. proc del[A, B](t: var Table[A, B]; key: A)

Deletes key from hash table t. Does nothing if the key does not exist.

Warning: If duplicate keys were added (via the now deprecated add proc), this may need to be called multiple times.

See also:

Example:

  1. var a = {'a': 5, 'b': 9, 'c': 13}.toTable
  2. a.del('a')
  3. doAssert a == {'b': 9, 'c': 13}.toTable
  4. a.del('z')
  5. doAssert a == {'b': 9, 'c': 13}.toTable

Source Edit

  1. proc del[A](t: CountTableRef[A]; key: A)

Deletes key from table t. Does nothing if the key does not exist.

See also:

Source Edit

  1. proc del[A](t: var CountTable[A]; key: A)

Deletes key from table t. Does nothing if the key does not exist.

See also:

Example:

  1. var a = toCountTable("aabbbccccc")
  2. a.del('b')
  3. assert a == toCountTable("aaccccc")
  4. a.del('b')
  5. assert a == toCountTable("aaccccc")
  6. a.del('c')
  7. assert a == toCountTable("aa")

Source Edit

  1. proc getOrDefault[A, B](t: OrderedTable[A, B]; key: A): B

Retrieves the value at t[key] if key is in t. Otherwise, the default initialization value for type B is returned (e.g. 0 for any integer type).

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.toOrderedTable
  2. doAssert a.getOrDefault('a') == 5
  3. doAssert a.getOrDefault('z') == 0

Source Edit

  1. proc getOrDefault[A, B](t: OrderedTable[A, B]; key: A; default: B): B

Retrieves the value at t[key] if key is in t. Otherwise, default is returned.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.toOrderedTable
  2. doAssert a.getOrDefault('a', 99) == 5
  3. doAssert a.getOrDefault('z', 99) == 99

Source Edit

  1. proc getOrDefault[A, B](t: OrderedTableRef[A, B]; key: A): B

Retrieves the value at t[key] if key is in t. Otherwise, the default initialization value for type B is returned (e.g. 0 for any integer type).

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.newOrderedTable
  2. doAssert a.getOrDefault('a') == 5
  3. doAssert a.getOrDefault('z') == 0

Source Edit

  1. proc getOrDefault[A, B](t: OrderedTableRef[A, B]; key: A; default: B): B

Retrieves the value at t[key] if key is in t. Otherwise, default is returned.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.newOrderedTable
  2. doAssert a.getOrDefault('a', 99) == 5
  3. doAssert a.getOrDefault('z', 99) == 99

Source Edit

  1. proc getOrDefault[A, B](t: Table[A, B]; key: A): B

Retrieves the value at t[key] if key is in t. Otherwise, the default initialization value for type B is returned (e.g. 0 for any integer type).

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.toTable
  2. doAssert a.getOrDefault('a') == 5
  3. doAssert a.getOrDefault('z') == 0

Source Edit

  1. proc getOrDefault[A, B](t: Table[A, B]; key: A; default: B): B

Retrieves the value at t[key] if key is in t. Otherwise, default is returned.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.toTable
  2. doAssert a.getOrDefault('a', 99) == 5
  3. doAssert a.getOrDefault('z', 99) == 99

Source Edit

  1. proc getOrDefault[A, B](t: TableRef[A, B]; key: A): B

Retrieves the value at t[key] if key is in t. Otherwise, the default initialization value for type B is returned (e.g. 0 for any integer type).

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.newTable
  2. doAssert a.getOrDefault('a') == 5
  3. doAssert a.getOrDefault('z') == 0

Source Edit

  1. proc getOrDefault[A, B](t: TableRef[A, B]; key: A; default: B): B

Retrieves the value at t[key] if key is in t. Otherwise, default is returned.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.newTable
  2. doAssert a.getOrDefault('a', 99) == 5
  3. doAssert a.getOrDefault('z', 99) == 99

Source Edit

  1. proc getOrDefault[A](t: CountTable[A]; key: A; default: int = 0): int

Retrieves the value at t[key] if key is in t. Otherwise, the integer value of default is returned.

See also:

Source Edit

  1. proc getOrDefault[A](t: CountTableRef[A]; key: A; default: int): int

Retrieves the value at t[key] if key is in t. Otherwise, the integer value of default is returned.

See also:

Source Edit

  1. proc hash[K, V](s: OrderedTable[K, V]): Hash

Source Edit

  1. proc hash[K, V](s: Table[K, V]): Hash

Source Edit

  1. proc hash[V](s: CountTable[V]): Hash

Source Edit

  1. proc hasKey[A, B](t: OrderedTable[A, B]; key: A): bool

Returns true if key is in the table t.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.toOrderedTable
  2. doAssert a.hasKey('a') == true
  3. doAssert a.hasKey('z') == false

Source Edit

  1. proc hasKey[A, B](t: OrderedTableRef[A, B]; key: A): bool

Returns true if key is in the table t.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.newOrderedTable
  2. doAssert a.hasKey('a') == true
  3. doAssert a.hasKey('z') == false

Source Edit

  1. proc hasKey[A, B](t: Table[A, B]; key: A): bool

Returns true if key is in the table t.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.toTable
  2. doAssert a.hasKey('a') == true
  3. doAssert a.hasKey('z') == false

Source Edit

  1. proc hasKey[A, B](t: TableRef[A, B]; key: A): bool

Returns true if key is in the table t.

See also:

Example:

  1. let a = {'a': 5, 'b': 9}.newTable
  2. doAssert a.hasKey('a') == true
  3. doAssert a.hasKey('z') == false

Source Edit

  1. proc hasKey[A](t: CountTable[A]; key: A): bool

Returns true if key is in the table t.

See also:

Source Edit

  1. proc hasKey[A](t: CountTableRef[A]; key: A): bool

Returns true if key is in the table t.

See also:

Source Edit

  1. proc hasKeyOrPut[A, B](t: OrderedTableRef[A, B]; key: A; val: B): bool

Returns true if key is in the table, otherwise inserts value.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.newOrderedTable
  2. if a.hasKeyOrPut('a', 50):
  3. a['a'] = 99
  4. if a.hasKeyOrPut('z', 50):
  5. a['z'] = 99
  6. doAssert a == {'a': 99, 'b': 9, 'z': 50}.newOrderedTable

Source Edit

  1. proc hasKeyOrPut[A, B](t: TableRef[A, B]; key: A; val: B): bool

Returns true if key is in the table, otherwise inserts value.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.newTable
  2. if a.hasKeyOrPut('a', 50):
  3. a['a'] = 99
  4. if a.hasKeyOrPut('z', 50):
  5. a['z'] = 99
  6. doAssert a == {'a': 99, 'b': 9, 'z': 50}.newTable

Source Edit

  1. proc hasKeyOrPut[A, B](t: var OrderedTable[A, B]; key: A; val: B): bool

Returns true if key is in the table, otherwise inserts value.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.toOrderedTable
  2. if a.hasKeyOrPut('a', 50):
  3. a['a'] = 99
  4. if a.hasKeyOrPut('z', 50):
  5. a['z'] = 99
  6. doAssert a == {'a': 99, 'b': 9, 'z': 50}.toOrderedTable

Source Edit

  1. proc hasKeyOrPut[A, B](t: var Table[A, B]; key: A; val: B): bool

Returns true if key is in the table, otherwise inserts value.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.toTable
  2. if a.hasKeyOrPut('a', 50):
  3. a['a'] = 99
  4. if a.hasKeyOrPut('z', 50):
  5. a['z'] = 99
  6. doAssert a == {'a': 99, 'b': 9, 'z': 50}.toTable

Source Edit

  1. proc inc[A](t: CountTableRef[A]; key: A; val = 1)

Source Edit

  1. proc inc[A](t: var CountTable[A]; key: A; val = 1)

Source Edit

  1. proc indexBy[A, B, C](collection: A; index: proc (x: B): C): Table[C, B]

Index the collection with the proc provided. Source Edit

  1. proc initCountTable[A](initialSize = defaultInitialSize): CountTable[A]

Creates a new count table that is empty.

Starting from Nim v0.20, tables are initialized by default and it is not necessary to call this function explicitly.

See also:

Source Edit

  1. proc initOrderedTable[A, B](initialSize = defaultInitialSize): OrderedTable[A, B]

Creates a new ordered hash table that is empty.

Starting from Nim v0.20, tables are initialized by default and it is not necessary to call this function explicitly.

See also:

Example:

  1. let
  2. a = initOrderedTable[int, string]()
  3. b = initOrderedTable[char, seq[int]]()

Source Edit

  1. proc initTable[A, B](initialSize = defaultInitialSize): Table[A, B]

Creates a new hash table that is empty.

Starting from Nim v0.20, tables are initialized by default and it is not necessary to call this function explicitly.

See also:

Example:

  1. let
  2. a = initTable[int, string]()
  3. b = initTable[char, seq[int]]()

Source Edit

  1. proc largest[A](t: CountTable[A]): tuple[key: A, val: int]

Returns the (key, value) pair with the largest val. Efficiency: O(n)

See also:

Source Edit

  1. proc largest[A](t: CountTableRef[A]): tuple[key: A, val: int]

Returns the (key, value) pair with the largest val. Efficiency: O(n)

See also:

Source Edit

  1. proc len[A, B](t: OrderedTable[A, B]): int {.inline.}

Returns the number of keys in t.

Example:

  1. let a = {'a': 5, 'b': 9}.toOrderedTable
  2. doAssert len(a) == 2

Source Edit

  1. proc len[A, B](t: OrderedTableRef[A, B]): int {.inline.}

Returns the number of keys in t.

Example:

  1. let a = {'a': 5, 'b': 9}.newOrderedTable
  2. doAssert len(a) == 2

Source Edit

  1. proc len[A, B](t: Table[A, B]): int

Returns the number of keys in t.

Example:

  1. let a = {'a': 5, 'b': 9}.toTable
  2. doAssert len(a) == 2

Source Edit

  1. proc len[A, B](t: TableRef[A, B]): int

Returns the number of keys in t.

Example:

  1. let a = {'a': 5, 'b': 9}.newTable
  2. doAssert len(a) == 2

Source Edit

  1. proc len[A](t: CountTable[A]): int

Returns the number of keys in t. Source Edit

  1. proc len[A](t: CountTableRef[A]): int

Returns the number of keys in t. Source Edit

  1. proc merge[A](s, t: CountTableRef[A])

Merges the second table into the first one.

Example:

  1. let
  2. a = newCountTable("aaabbc")
  3. b = newCountTable("bcc")
  4. a.merge(b)
  5. doAssert a == newCountTable("aaabbbccc")

Source Edit

  1. proc merge[A](s: var CountTable[A]; t: CountTable[A])

Merges the second table into the first one (must be declared as var).

Example:

  1. var a = toCountTable("aaabbc")
  2. let b = toCountTable("bcc")
  3. a.merge(b)
  4. doAssert a == toCountTable("aaabbbccc")

Source Edit

  1. proc mgetOrPut[A, B](t: OrderedTableRef[A, B]; key: A; val: B): var B

Retrieves value at t[key] or puts val if not present, either way returning a value which can be modified.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.newOrderedTable
  2. doAssert a.mgetOrPut('a', 99) == 5
  3. doAssert a.mgetOrPut('z', 99) == 99
  4. doAssert a == {'a': 5, 'b': 9, 'z': 99}.newOrderedTable

Source Edit

  1. proc mgetOrPut[A, B](t: TableRef[A, B]; key: A; val: B): var B

Retrieves value at t[key] or puts val if not present, either way returning a value which can be modified.

Note that while the value returned is of type var B, it is easy to accidentally create an copy of the value at t[key]. Remember that seqs and strings are value types, and therefore cannot be copied into a separate variable for modification. See the example below.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.newTable
  2. doAssert a.mgetOrPut('a', 99) == 5
  3. doAssert a.mgetOrPut('z', 99) == 99
  4. doAssert a == {'a': 5, 'b': 9, 'z': 99}.newTable
  5. # An example of accidentally creating a copy
  6. var t = newTable[int, seq[int]]()
  7. # In this example, we expect t[10] to be modified,
  8. # but it is not.
  9. var copiedSeq = t.mgetOrPut(10, @[10])
  10. copiedSeq.add(20)
  11. doAssert t[10] == @[10]
  12. # Correct
  13. t.mgetOrPut(25, @[25]).add(35)
  14. doAssert t[25] == @[25, 35]

Source Edit

  1. proc mgetOrPut[A, B](t: var OrderedTable[A, B]; key: A; val: B): var B

Retrieves value at t[key] or puts val if not present, either way returning a value which can be modified.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.toOrderedTable
  2. doAssert a.mgetOrPut('a', 99) == 5
  3. doAssert a.mgetOrPut('z', 99) == 99
  4. doAssert a == {'a': 5, 'b': 9, 'z': 99}.toOrderedTable

Source Edit

  1. proc mgetOrPut[A, B](t: var Table[A, B]; key: A; val: B): var B

Retrieves value at t[key] or puts val if not present, either way returning a value which can be modified.

Note that while the value returned is of type var B, it is easy to accidentally create a copy of the value at t[key]. Remember that seqs and strings are value types, and therefore cannot be copied into a separate variable for modification. See the example below.

See also:

Example:

  1. var a = {'a': 5, 'b': 9}.toTable
  2. doAssert a.mgetOrPut('a', 99) == 5
  3. doAssert a.mgetOrPut('z', 99) == 99
  4. doAssert a == {'a': 5, 'b': 9, 'z': 99}.toTable
  5. # An example of accidentally creating a copy
  6. var t = initTable[int, seq[int]]()
  7. # In this example, we expect t[10] to be modified,
  8. # but it is not.
  9. var copiedSeq = t.mgetOrPut(10, @[10])
  10. copiedSeq.add(20)
  11. doAssert t[10] == @[10]
  12. # Correct
  13. t.mgetOrPut(25, @[25]).add(35)
  14. doAssert t[25] == @[25, 35]

Source Edit

  1. proc newCountTable[A](initialSize = defaultInitialSize): CountTableRef[A]

Creates a new ref count table that is empty.

See also:

Source Edit

  1. proc newCountTable[A](keys: openArray[A]): CountTableRef[A]

Creates a new ref count table with every member of a container keys having a count of how many times it occurs in that container. Source Edit

  1. proc newOrderedTable[A, B](initialSize = defaultInitialSize): OrderedTableRef[A,
  2. B]

Creates a new ordered ref hash table that is empty.

See also:

Example:

  1. let
  2. a = newOrderedTable[int, string]()
  3. b = newOrderedTable[char, seq[int]]()

Source Edit

  1. proc newOrderedTable[A, B](pairs: openArray[(A, B)]): OrderedTableRef[A, B]

Creates a new ordered ref hash table that contains the given pairs.

pairs is a container consisting of (key, value) tuples.

See also:

Example:

  1. let a = [('a', 5), ('b', 9)]
  2. let b = newOrderedTable(a)
  3. assert b == {'a': 5, 'b': 9}.newOrderedTable

Source Edit

  1. proc newTable[A, B](initialSize = defaultInitialSize): TableRef[A, B]

Creates a new ref hash table that is empty.

See also:

Example:

  1. let
  2. a = newTable[int, string]()
  3. b = newTable[char, seq[int]]()

Source Edit

  1. proc newTable[A, B](pairs: openArray[(A, B)]): TableRef[A, B]

Creates a new ref hash table that contains the given pairs.

pairs is a container consisting of (key, value) tuples.

See also:

Example:

  1. let a = [('a', 5), ('b', 9)]
  2. let b = newTable(a)
  3. assert b == {'a': 5, 'b': 9}.newTable

Source Edit

  1. proc newTableFrom[A, B, C](collection: A; index: proc (x: B): C): TableRef[C, B]

Index the collection with the proc provided. Source Edit

  1. proc pop[A, B](t: OrderedTableRef[A, B]; key: A; val: var B): bool

Deletes the key from the table. Returns true, if the key existed, and sets val to the mapping of the key. Otherwise, returns false, and the val is unchanged.

See also:

Example:

  1. var
  2. a = {'c': 5, 'b': 9, 'a': 13}.newOrderedTable
  3. i: int
  4. doAssert a.pop('b', i) == true
  5. doAssert a == {'c': 5, 'a': 13}.newOrderedTable
  6. doAssert i == 9
  7. i = 0
  8. doAssert a.pop('z', i) == false
  9. doAssert a == {'c': 5, 'a': 13}.newOrderedTable
  10. doAssert i == 0

Source Edit

  1. proc pop[A, B](t: TableRef[A, B]; key: A; val: var B): bool

Deletes the key from the table. Returns true, if the key existed, and sets val to the mapping of the key. Otherwise, returns false, and the val is unchanged.

Warning: If duplicate keys were added (via the now deprecated add proc), this may need to be called multiple times.

See also:

Example:

  1. var
  2. a = {'a': 5, 'b': 9, 'c': 13}.newTable
  3. i: int
  4. doAssert a.pop('b', i) == true
  5. doAssert a == {'a': 5, 'c': 13}.newTable
  6. doAssert i == 9
  7. i = 0
  8. doAssert a.pop('z', i) == false
  9. doAssert a == {'a': 5, 'c': 13}.newTable
  10. doAssert i == 0

Source Edit

  1. proc pop[A, B](t: var OrderedTable[A, B]; key: A; val: var B): bool

Deletes the key from the table. Returns true, if the key existed, and sets val to the mapping of the key. Otherwise, returns false, and the val is unchanged.

O(n) complexity.

See also:

Example:

  1. var
  2. a = {'c': 5, 'b': 9, 'a': 13}.toOrderedTable
  3. i: int
  4. doAssert a.pop('b', i) == true
  5. doAssert a == {'c': 5, 'a': 13}.toOrderedTable
  6. doAssert i == 9
  7. i = 0
  8. doAssert a.pop('z', i) == false
  9. doAssert a == {'c': 5, 'a': 13}.toOrderedTable
  10. doAssert i == 0

Source Edit

  1. proc pop[A, B](t: var Table[A, B]; key: A; val: var B): bool

Deletes the key from the table. Returns true, if the key existed, and sets val to the mapping of the key. Otherwise, returns false, and the val is unchanged.

Warning: If duplicate keys were added (via the now deprecated add proc), this may need to be called multiple times.

See also:

Example:

  1. var
  2. a = {'a': 5, 'b': 9, 'c': 13}.toTable
  3. i: int
  4. doAssert a.pop('b', i) == true
  5. doAssert a == {'a': 5, 'c': 13}.toTable
  6. doAssert i == 9
  7. i = 0
  8. doAssert a.pop('z', i) == false
  9. doAssert a == {'a': 5, 'c': 13}.toTable
  10. doAssert i == 0

Source Edit

  1. proc pop[A](t: CountTableRef[A]; key: A; val: var int): bool

Deletes the key from the table. Returns true, if the key existed, and sets val to the mapping of the key. Otherwise, returns false, and the val is unchanged.

See also:

Source Edit

  1. proc pop[A](t: var CountTable[A]; key: A; val: var int): bool

Deletes the key from the table. Returns true, if the key existed, and sets val to the mapping of the key. Otherwise, returns false, and the val is unchanged.

See also:

Example:

  1. var a = toCountTable("aabbbccccc")
  2. var i = 0
  3. assert a.pop('b', i)
  4. assert i == 3
  5. i = 99
  6. assert not a.pop('b', i)
  7. assert i == 99

Source Edit

  1. proc smallest[A](t: CountTable[A]): tuple[key: A, val: int]

Returns the (key, value) pair with the smallest val. Efficiency: O(n)

See also:

Source Edit

  1. proc smallest[A](t: CountTableRef[A]): tuple[key: A, val: int]

Returns the (key, value) pair with the smallest val. Efficiency: O(n)

See also:

Source Edit

  1. proc sort[A, B](t: OrderedTableRef[A, B]; cmp: proc (x, y: (A, B)): int;
  2. order = SortOrder.Ascending) {.effectsOf: cmp.}

Sorts t according to the function cmp.

This modifies the internal list that kept the insertion order, so insertion order is lost after this call but key lookup and insertions remain possible after sort (in contrast to the sort proc for count tables).

Example:

  1. import std/[algorithm]
  2. var a = newOrderedTable[char, int]()
  3. for i, c in "cab":
  4. a[c] = 10*i
  5. doAssert a == {'c': 0, 'a': 10, 'b': 20}.newOrderedTable
  6. a.sort(system.cmp)
  7. doAssert a == {'a': 10, 'b': 20, 'c': 0}.newOrderedTable
  8. a.sort(system.cmp, order = SortOrder.Descending)
  9. doAssert a == {'c': 0, 'b': 20, 'a': 10}.newOrderedTable

Source Edit

  1. proc sort[A, B](t: var OrderedTable[A, B]; cmp: proc (x, y: (A, B)): int;
  2. order = SortOrder.Ascending) {.effectsOf: cmp.}

Sorts t according to the function cmp.

This modifies the internal list that kept the insertion order, so insertion order is lost after this call but key lookup and insertions remain possible after sort (in contrast to the sort proc for count tables).

Example:

  1. import std/[algorithm]
  2. var a = initOrderedTable[char, int]()
  3. for i, c in "cab":
  4. a[c] = 10*i
  5. doAssert a == {'c': 0, 'a': 10, 'b': 20}.toOrderedTable
  6. a.sort(system.cmp)
  7. doAssert a == {'a': 10, 'b': 20, 'c': 0}.toOrderedTable
  8. a.sort(system.cmp, order = SortOrder.Descending)
  9. doAssert a == {'c': 0, 'b': 20, 'a': 10}.toOrderedTable

Source Edit

  1. proc sort[A](t: CountTableRef[A]; order = SortOrder.Descending)

Sorts the count table so that, by default, the entry with the highest counter comes first.

This is destructive! You must not modify `t` afterwards!

You can use the iterators pairs, keys, and values to iterate over t in the sorted order.

Source Edit

  1. proc sort[A](t: var CountTable[A]; order = SortOrder.Descending)

Sorts the count table so that, by default, the entry with the highest counter comes first.

Warning: This is destructive! Once sorted, you must not modify t afterwards!

You can use the iterators pairs, keys, and values to iterate over t in the sorted order.

Example:

  1. import std/[algorithm, sequtils]
  2. var a = toCountTable("abracadabra")
  3. doAssert a == "aaaaabbrrcd".toCountTable
  4. a.sort()
  5. doAssert toSeq(a.values) == @[5, 2, 2, 1, 1]
  6. a.sort(SortOrder.Ascending)
  7. doAssert toSeq(a.values) == @[1, 1, 2, 2, 5]

Source Edit

  1. proc take[A, B](t: TableRef[A, B]; key: A; val: var B): bool {.inline.}

Alias for:

Source Edit

  1. proc take[A, B](t: var Table[A, B]; key: A; val: var B): bool {.inline.}

Alias for:

Source Edit

  1. proc toCountTable[A](keys: openArray[A]): CountTable[A]

Creates a new count table with every member of a container keys having a count of how many times it occurs in that container. Source Edit

  1. proc toOrderedTable[A, B](pairs: openArray[(A, B)]): OrderedTable[A, B]

Creates a new ordered hash table that contains the given pairs.

pairs is a container consisting of (key, value) tuples.

See also:

Example:

  1. let a = [('a', 5), ('b', 9)]
  2. let b = toOrderedTable(a)
  3. assert b == {'a': 5, 'b': 9}.toOrderedTable

Source Edit

  1. proc toTable[A, B](pairs: openArray[(A, B)]): Table[A, B]

Creates a new hash table that contains the given pairs.

pairs is a container consisting of (key, value) tuples.

See also:

Example:

  1. let a = [('a', 5), ('b', 9)]
  2. let b = toTable(a)
  3. assert b == {'a': 5, 'b': 9}.toTable

Source Edit

Iterators

  1. iterator allValues[A, B](t: Table[A, B]; key: A): B {....deprecated: "Deprecated since v1.4; tables with duplicated keys are deprecated".}

Deprecated: Deprecated since v1.4; tables with duplicated keys are deprecated

Iterates over any value in the table t that belongs to the given key.

Used if you have a table with duplicate keys (as a result of using add proc).

Example:

  1. import std/[sequtils, algorithm]
  2. var a = {'a': 3, 'b': 5}.toTable
  3. for i in 1..3: a.add('z', 10*i)
  4. doAssert toSeq(a.pairs).sorted == @[('a', 3), ('b', 5), ('z', 10), ('z', 20), ('z', 30)]
  5. doAssert sorted(toSeq(a.allValues('z'))) == @[10, 20, 30]

Source Edit

  1. iterator keys[A, B](t: OrderedTable[A, B]): lent A

Iterates over any key in the table t in insertion order.

See also:

Example:

  1. var a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toOrderedTable
  5. for k in a.keys:
  6. a[k].add(99)
  7. doAssert a == {'o': @[1, 5, 7, 9, 99],
  8. 'e': @[2, 4, 6, 8, 99]}.toOrderedTable

Source Edit

  1. iterator keys[A, B](t: OrderedTableRef[A, B]): lent A

Iterates over any key in the table t in insertion order.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newOrderedTable
  5. for k in a.keys:
  6. a[k].add(99)
  7. doAssert a == {'o': @[1, 5, 7, 9, 99], 'e': @[2, 4, 6, 8,
  8. 99]}.newOrderedTable

Source Edit

  1. iterator keys[A, B](t: Table[A, B]): lent A

Iterates over any key in the table t.

See also:

Example:

  1. var a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toTable
  5. for k in a.keys:
  6. a[k].add(99)
  7. doAssert a == {'e': @[2, 4, 6, 8, 99], 'o': @[1, 5, 7, 9, 99]}.toTable

Source Edit

  1. iterator keys[A, B](t: TableRef[A, B]): lent A

Iterates over any key in the table t.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newTable
  5. for k in a.keys:
  6. a[k].add(99)
  7. doAssert a == {'e': @[2, 4, 6, 8, 99], 'o': @[1, 5, 7, 9, 99]}.newTable

Source Edit

  1. iterator keys[A](t: CountTable[A]): lent A

Iterates over any key in the table t.

See also:

Example:

  1. var a = toCountTable("abracadabra")
  2. for k in keys(a):
  3. a[k] = 2
  4. doAssert a == toCountTable("aabbccddrr")

Source Edit

  1. iterator keys[A](t: CountTableRef[A]): A

Iterates over any key in the table t.

See also:

Example:

  1. let a = newCountTable("abracadabra")
  2. for k in keys(a):
  3. a[k] = 2
  4. doAssert a == newCountTable("aabbccddrr")

Source Edit

  1. iterator mpairs[A, B](t: OrderedTableRef[A, B]): (A, var B)

Iterates over any (key, value) pair in the table t in insertion order. The values can be modified.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newOrderedTable
  5. for k, v in a.mpairs:
  6. v.add(v[0] + 10)
  7. doAssert a == {'o': @[1, 5, 7, 9, 11],
  8. 'e': @[2, 4, 6, 8, 12]}.newOrderedTable

Source Edit

  1. iterator mpairs[A, B](t: TableRef[A, B]): (A, var B)

Iterates over any (key, value) pair in the table t. The values can be modified.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newTable
  5. for k, v in a.mpairs:
  6. v.add(v[0] + 10)
  7. doAssert a == {'e': @[2, 4, 6, 8, 12], 'o': @[1, 5, 7, 9, 11]}.newTable

Source Edit

  1. iterator mpairs[A, B](t: var OrderedTable[A, B]): (A, var B)

Iterates over any (key, value) pair in the table t (must be declared as var) in insertion order. The values can be modified.

See also:

Example:

  1. var a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toOrderedTable
  5. for k, v in a.mpairs:
  6. v.add(v[0] + 10)
  7. doAssert a == {'o': @[1, 5, 7, 9, 11],
  8. 'e': @[2, 4, 6, 8, 12]}.toOrderedTable

Source Edit

  1. iterator mpairs[A, B](t: var Table[A, B]): (A, var B)

Iterates over any (key, value) pair in the table t (must be declared as var). The values can be modified.

See also:

Example:

  1. var a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toTable
  5. for k, v in a.mpairs:
  6. v.add(v[0] + 10)
  7. doAssert a == {'e': @[2, 4, 6, 8, 12], 'o': @[1, 5, 7, 9, 11]}.toTable

Source Edit

  1. iterator mpairs[A](t: CountTableRef[A]): (A, var int)

Iterates over any (key, value) pair in the table t. The values can be modified.

See also:

Example:

  1. let a = newCountTable("abracadabra")
  2. for k, v in mpairs(a):
  3. v = 2
  4. doAssert a == newCountTable("aabbccddrr")

Source Edit

  1. iterator mpairs[A](t: var CountTable[A]): (A, var int)

Iterates over any (key, value) pair in the table t (must be declared as var). The values can be modified.

See also:

Example:

  1. var a = toCountTable("abracadabra")
  2. for k, v in mpairs(a):
  3. v = 2
  4. doAssert a == toCountTable("aabbccddrr")

Source Edit

  1. iterator mvalues[A, B](t: OrderedTableRef[A, B]): var B

Iterates over any value in the table t in insertion order. The values can be modified.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newOrderedTable
  5. for v in a.mvalues:
  6. v.add(99)
  7. doAssert a == {'o': @[1, 5, 7, 9, 99],
  8. 'e': @[2, 4, 6, 8, 99]}.newOrderedTable

Source Edit

  1. iterator mvalues[A, B](t: TableRef[A, B]): var B

Iterates over any value in the table t. The values can be modified.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newTable
  5. for v in a.mvalues:
  6. v.add(99)
  7. doAssert a == {'e': @[2, 4, 6, 8, 99], 'o': @[1, 5, 7, 9, 99]}.newTable

Source Edit

  1. iterator mvalues[A, B](t: var OrderedTable[A, B]): var B

Iterates over any value in the table t (must be declared as var) in insertion order. The values can be modified.

See also:

Example:

  1. var a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toOrderedTable
  5. for v in a.mvalues:
  6. v.add(99)
  7. doAssert a == {'o': @[1, 5, 7, 9, 99],
  8. 'e': @[2, 4, 6, 8, 99]}.toOrderedTable

Source Edit

  1. iterator mvalues[A, B](t: var Table[A, B]): var B

Iterates over any value in the table t (must be declared as var). The values can be modified.

See also:

Example:

  1. var a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toTable
  5. for v in a.mvalues:
  6. v.add(99)
  7. doAssert a == {'e': @[2, 4, 6, 8, 99], 'o': @[1, 5, 7, 9, 99]}.toTable

Source Edit

  1. iterator mvalues[A](t: CountTableRef[A]): var int

Iterates over any value in the table t. The values can be modified.

See also:

Example:

  1. var a = newCountTable("abracadabra")
  2. for v in mvalues(a):
  3. v = 2
  4. doAssert a == newCountTable("aabbccddrr")

Source Edit

  1. iterator mvalues[A](t: var CountTable[A]): var int

Iterates over any value in the table t (must be declared as var). The values can be modified.

See also:

Example:

  1. var a = toCountTable("abracadabra")
  2. for v in mvalues(a):
  3. v = 2
  4. doAssert a == toCountTable("aabbccddrr")

Source Edit

  1. iterator pairs[A, B](t: OrderedTable[A, B]): (A, B)

Iterates over any (key, value) pair in the table t in insertion order.

See also:

Examples:

  1. let a = {
  2. 'o': [1, 5, 7, 9],
  3. 'e': [2, 4, 6, 8]
  4. }.toOrderedTable
  5. for k, v in a.pairs:
  6. echo "key: ", k
  7. echo "value: ", v
  8. # key: o
  9. # value: [1, 5, 7, 9]
  10. # key: e
  11. # value: [2, 4, 6, 8]

Source Edit

  1. iterator pairs[A, B](t: OrderedTableRef[A, B]): (A, B)

Iterates over any (key, value) pair in the table t in insertion order.

See also:

Examples:

  1. let a = {
  2. 'o': [1, 5, 7, 9],
  3. 'e': [2, 4, 6, 8]
  4. }.newOrderedTable
  5. for k, v in a.pairs:
  6. echo "key: ", k
  7. echo "value: ", v
  8. # key: o
  9. # value: [1, 5, 7, 9]
  10. # key: e
  11. # value: [2, 4, 6, 8]

Source Edit

  1. iterator pairs[A, B](t: Table[A, B]): (A, B)

Iterates over any (key, value) pair in the table t.

See also:

Examples:

  1. let a = {
  2. 'o': [1, 5, 7, 9],
  3. 'e': [2, 4, 6, 8]
  4. }.toTable
  5. for k, v in a.pairs:
  6. echo "key: ", k
  7. echo "value: ", v
  8. # key: e
  9. # value: [2, 4, 6, 8]
  10. # key: o
  11. # value: [1, 5, 7, 9]

Source Edit

  1. iterator pairs[A, B](t: TableRef[A, B]): (A, B)

Iterates over any (key, value) pair in the table t.

See also:

Examples:

  1. let a = {
  2. 'o': [1, 5, 7, 9],
  3. 'e': [2, 4, 6, 8]
  4. }.newTable
  5. for k, v in a.pairs:
  6. echo "key: ", k
  7. echo "value: ", v
  8. # key: e
  9. # value: [2, 4, 6, 8]
  10. # key: o
  11. # value: [1, 5, 7, 9]

Source Edit

  1. iterator pairs[A](t: CountTable[A]): (A, int)

Iterates over any (key, value) pair in the table t.

See also:

Examples:

  1. let a = toCountTable("abracadabra")
  2. for k, v in pairs(a):
  3. echo "key: ", k
  4. echo "value: ", v
  5. # key: a
  6. # value: 5
  7. # key: b
  8. # value: 2
  9. # key: c
  10. # value: 1
  11. # key: d
  12. # value: 1
  13. # key: r
  14. # value: 2

Source Edit

  1. iterator pairs[A](t: CountTableRef[A]): (A, int)

Iterates over any (key, value) pair in the table t.

See also:

Examples:

  1. let a = newCountTable("abracadabra")
  2. for k, v in pairs(a):
  3. echo "key: ", k
  4. echo "value: ", v
  5. # key: a
  6. # value: 5
  7. # key: b
  8. # value: 2
  9. # key: c
  10. # value: 1
  11. # key: d
  12. # value: 1
  13. # key: r
  14. # value: 2

Source Edit

  1. iterator values[A, B](t: OrderedTable[A, B]): lent B

Iterates over any value in the table t in insertion order.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toOrderedTable
  5. for v in a.values:
  6. doAssert v.len == 4

Source Edit

  1. iterator values[A, B](t: OrderedTableRef[A, B]): lent B

Iterates over any value in the table t in insertion order.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newOrderedTable
  5. for v in a.values:
  6. doAssert v.len == 4

Source Edit

  1. iterator values[A, B](t: Table[A, B]): lent B

Iterates over any value in the table t.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.toTable
  5. for v in a.values:
  6. doAssert v.len == 4

Source Edit

  1. iterator values[A, B](t: TableRef[A, B]): lent B

Iterates over any value in the table t.

See also:

Example:

  1. let a = {
  2. 'o': @[1, 5, 7, 9],
  3. 'e': @[2, 4, 6, 8]
  4. }.newTable
  5. for v in a.values:
  6. doAssert v.len == 4

Source Edit

  1. iterator values[A](t: CountTable[A]): int

Iterates over any value in the table t.

See also:

Example:

  1. let a = toCountTable("abracadabra")
  2. for v in values(a):
  3. assert v < 10

Source Edit

  1. iterator values[A](t: CountTableRef[A]): int

Iterates over any value in the table t.

See also:

Example:

  1. let a = newCountTable("abracadabra")
  2. for v in values(a):
  3. assert v < 10

Source Edit

Templates

  1. template withValue[A, B](t: var Table[A, B]; key: A;
  2. value, body1, body2: untyped)

Retrieves the value at t[key].

value can be modified in the scope of the withValue call.

Example:

  1. type
  2. User = object
  3. name: string
  4. uid: int
  5. var t = initTable[int, User]()
  6. let u = User(name: "Hello", uid: 99)
  7. t[1] = u
  8. t.withValue(1, value):
  9. # block is executed only if `key` in `t`
  10. value.name = "Nim"
  11. value.uid = 1314
  12. t.withValue(521, value):
  13. doAssert false
  14. do:
  15. # block is executed when `key` not in `t`
  16. t[1314] = User(name: "exist", uid: 521)
  17. assert t[1].name == "Nim"
  18. assert t[1].uid == 1314
  19. assert t[1314].name == "exist"
  20. assert t[1314].uid == 521

Source Edit

  1. template withValue[A, B](t: var Table[A, B]; key: A; value, body: untyped)

Retrieves the value at t[key].

value can be modified in the scope of the withValue call.

Example:

  1. type
  2. User = object
  3. name: string
  4. uid: int
  5. var t = initTable[int, User]()
  6. let u = User(name: "Hello", uid: 99)
  7. t[1] = u
  8. t.withValue(1, value):
  9. # block is executed only if `key` in `t`
  10. value.name = "Nim"
  11. value.uid = 1314
  12. t.withValue(2, value):
  13. value.name = "No"
  14. value.uid = 521
  15. assert t[1].name == "Nim"
  16. assert t[1].uid == 1314

Source Edit