empty []

Description

General [ ] properties

Empty brackets [] represent the empty matrix. Its general properties are now described.

It has only two dimensions. Any dimension > #2 is automatically squeezed:

--> e = ones(1,2,0,2); size(e)
 ans  =
   0.   0.

--> e == []
 ans  =
  T

It is always of real decimal type. There is no empty matrix of integer types (int8, uint8, int16, uint16, int32, uint32, int64, uint64), nor of string type, etc:

--> type(uint8([]))  // not of type 8 (encoded integers)
 ans  =
   1.

--> a = [1 2 ; 3 4] + %i;
--> a(1,:) = []
 a  =
   3. + i     4. + i

--> a(1,:) = [], isreal(a)
 a  =
    []
 ans  =
  T

--> t = "abcd efg", type(t)
 t  =
 abcd efg

 ans  =
   10.

--> t(1) = [], type(t)
 t  =
    []

 ans  =
   1.

However, it is distinct from the sparse empty matrix:

--> se = sparse([])
 se  =
(  0,  0) zero sparse matrix

--> size(se)
 ans  =
   0.   0.

--> se == []
 ans  =
  F

It is also distinct from all empty heterogeneous containers list(), struct() or cell() :

--> L = list()
 L  =
     ()
--> L == []
 ans  =
  F

--> s = struct()
 s  =
0x0 struct array with no fields.
--> s == []
 ans  =
  F

--> c = cell()
 c  =
   {}
--> c == []
 ans  =
  F

[ ] as operand or input argument

As operand of usual predefined non-boolean operators, [] sets the result to []. All the following operations yield []:

Unary operators
[]', [].', -[], ~[]

Binary numerical operators
addition:	[] + [1 2], [1 2] + []
subtraction:	[] - [1 2], [1 2] - []
division:	[]/[1 2], []./[1 2], [1 2]/[], [1 2]./[]
left division:	[]\[1 2], [].\[1 2], [1 2]\[], [1 2].\[]
multiplication:	[][1 2], [].[1 2], [1 2][], [1 2].[]
kronecker:	[]..[1 2], [1 2]..[]
power:	[]^[1 2], [].^[1 2], [1 2]^[], [1 2].^[]

Inequality comparisons
greater:	[]>[1 2], []>=[1 2], [1 2]>[], [1 2]>=[]
less:	[]<[1 2], []<=[1 2], [1 2]<[], [1 2]<=[]

As operand of boolean binary operators, [] is equivalent to %T:
Binary numerical operators

or: [] | [%T %F], [%T %F] | [] → [%T %T]

and: [] & [%T %F], [%T %F] & [] → [%T %F]
But, noticeably:
- or([]) is %F.
- As the condition of any if or while statement, [] is %F:
```
--> if []
-->     r = "[] is %T as any if condition";
--> else
-->     r = "[] is %F as any if condition";
--> end
--> r
 r  =
 [] is %F as any if condition
```
In concatenations, [] is simply ignored: [A,[]] == [[],A] == [A ; []] == [[] ; A] == A
In text concatenations, +[] yields []: []+["a" "bc"] == ["a" "bc"]+[] == []

As special input matrix of linear algebra or common functions, the answer depends on the considered function. It is documented in the page dedicated to each function. Examples:

`det([])`	`1`
`rank([])`	`0`
`trace([])`	`0`
`norm([])`	`0`
`cond([])`	`0`
`rcond([])`	`Inf`

`diag([])`	`[]`
`tril([])`	`[]`
`triu([])`	`[]`
`min([])`	`[]`
`max([])`	`[]`
`sign([])`	`[]`
`clean([])`	`[]`
`svd([])`	`[]`

`cumprod([])`	`[]`
`cumsum([])`	`[]`
`sum([])`	`0`
`prod([])`	`1`
`mean([])`	`Nan`
`median([])`	`Nan`
`stdev([])`	`Nan`
`mad([])`	`Nan`
`variance([])`	`Nan`

As general input argument of functions, [] is often used to choose the default value of an input argument (to somewhat skip it, to avoid providing an actual explicit value). However, this is not a strict rule.

Assigning [ ] to delete ranges in arrays

Considering an array of any number of dimensions and of any size, that can be a matrix or hypermatrix of any datatype, an array of structures, or an array of cells, [] can be assigned to delete the addressed ranges (rows, columns, etc). These ones must cover the full size of the array at least along one of its dimensions.

Examples:

With a matrix of decimal numbers:

a = grand(3,5,"uin",0,9)

--> a = grand(3,5,"uin",0,9)
 a  =
   2.   4.   8.   0.   9.
   2.   1.   3.   6.   4.
   4.   9.   5.   9.   7.

--> a(:,[3 5]) = []
 a  =
   2.   4.   0.
   2.   1.   6.
   4.   9.   9.

--> a(2,:) = []
 a  =
   2.   4.   0.
   4.   9.   9.

With an hypermatrix of texts:

cs = cumsum(grand(2,4,3,"uin",1,3));
t = matrix(strsplit(ascii(grand(1,cs($),"uin",ascii("a"),ascii("c"))),cs(1:$-1)),2,4,3)

--> cs = cumsum(grand(2,4,3,"uin",1,3));
--> t = matrix(strsplit(ascii(grand(1,cs($),"uin",ascii("a"),ascii("c"))),cs(1:$-1)),2,4,3)
 t  =
(:,:,1)
!ccc  b    b   b  !
!bbb  bcc  bc  c  !

(:,:,2)
!aa  aab  bc  a   !
!ab  a    cc  ba  !

(:,:,3)
!c   aba  c    abb  !
!bc  cc   acb  c    !

--> t(:,3,:) = []  // Deleting all 3rd columns
 t  =
(:,:,1)
!ccc  b    b  !
!bbb  bcc  c  !

(:,:,2)
!aa  aab  a   !
!ab  a    ba  !

(:,:,3)
!c   aba  abb  !
!bc  cc   c    !

--> t(:,:,2) = []   // Deleting the 2nd page
 t  =
(:,:,1)
!ccc  b    b  !
!bbb  bcc  c  !

(:,:,2)
!c   aba  abb  !
!bc  cc   c    !

With an array of cells:

c = cat(3, {"start", -1.23, %f  ; (1-%s)^2, gda(), list(2,,%z)}, ..
           {%t     , "abc", 5.2 ; int8(21), []   , %z})

--> c = cat(3, {"start", -1.23, %f  ; (1-%s)^2, gda(), list(2,,%z)}, ..
               {%t     , "abc", 5.2 ; int8(21), []   , %z})
 c  =
(:,:,1)
  [1x1 string    ]  [1x1 constant]  [1x1 boolean]
  [1x1 polynomial]  [1x1 handle  ]  [    list   ]

(:,:,2)
  [1x1 boolean]  [1x1 string  ]  [1x1 constant  ]
  [1x1 int8   ]  [0x0 constant]  [1x1 polynomial]

--> c(:,2,:) = []                   // Deleting all 2nd columns
 c  =
(:,:,1)
  [1x1 string    ]  [1x1 boolean]
  [1x1 polynomial]  [    list   ]

(:,:,2)
  [1x1 boolean]  [1x1 constant  ]
  [1x1 int8   ]  [1x1 polynomial]

--> c(1,:,:) = []                   // Deleting all 1st rows
 c  =
(:,:,1)
  [1x1 polynomial]  [ list]

(:,:,2)
  [1x1 int8]  [1x1 polynomial]

With an array of structures:

--> s(4,5).r = %pi;
--> s.b = %t
 s  =
4x5 struct array with fields:
   r
   b

--> s([1 3],:) = []
 s  =
2x5 struct array with fields:
   r
   b

--> s(:,2) = []
 s  =
2x4 struct array with fields:
   r
   b

Other examples

type(string([]))
[type(int8([])) , type(int16([])) , type(int32([])) , type(int64([]))]
[type(uint8([])), type(uint16([])), type(uint32([])), type(uint64([]))]
[] * %F

--> type(string([]))
 ans  =
   1.

--> [type(int8([])) , type(int16([])) , type(int32([])) , type(int64([]))]
 ans  =
   1.   1.   1.   1.

--> [type(uint8([])), type(uint16([])), type(uint32([])), type(uint64([]))]
 ans  =
   1.   1.   1.   1.

--> [] * %F
 ans  =
    []

A = [%s-1, %s^2]
A + []
A - []
A * []

--> A = [%s-1, %s^2]
 A  =
           2
  -1 +s   s

--> A + []
 ans  =
    []

--> A - []
 ans  =
    []

--> A * []
 ans  =
    []

string([]) == []
["a" "bc"] + []
[] + ["a" "bc"]

--> string([]) == []
 ans  =
  T

--> ["a" "bc"] + []
 ans  =
    []

--> [] + ["a" "bc"]
 ans  =
    []

A = rand(2,2);
A([],:)

--> A = rand(2,2);
--> A([],:)
 ans  =
    []

[det([]) rank([]) trace([]) norm([]) cond([]) rcond([])]

--> [det([]) rank([]) trace([]) norm([]) cond([]) rcond([])]
 ans  =
   1.   0.   0.   0.   0.   Inf

[sum([]) prod([]) mean([]) median([]) stdev([]) mad([])]

--> [sum([]) prod([]) mean([]) median([]) stdev([]) mad([])]
 ans  =
   0.   1.   Nan   Nan   Nan   Nan

History

Versão	Descrição
6.0.0	`A+[]`, `[]+A` and `A-[]` now return `[]` instead of `A`. `[]-A` now returns `[]` instead of `-A`. `A>[]`, `A>=[]`, `A<[]`, `A<=[]`, `[]>A`, `[]>=A`, `[]<A`, and `[]<=A` now return `[]` instead of an error.

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