Casting by Subscripted Assignment

The following subscripted assignment statement retains the type of A and saturates the value of B to an int8:

A = int8(0);
B = int16(32767);
A(:) = B

A =

  int8

   127

class(A)

ans =

    'int8'

The same is true for fi objects:

fipref('NumericTypeDisplay', 'short');
A = fi(0, 1, 8, 0);
B = fi(32767, 1, 16, 0);
A(:) = B

A = 

   127
      numerictype(1,8,0)

Casting by Conversion Function

You can convert from one data type to another by using a conversion function. In this example, A does not have to be predefined because it is overwritten.

B = int16(32767);
A = int8(B)

A =

  int8

   127

class(A)

ans =

    'int8'

The same is true for fi objects:

B = fi(32767,1,16,0)
A = fi(B,1,8,0)

B = 

       32767
      numerictype(1,16,0)

A = 

   127
      numerictype(1,8,0)

Using a numerictype Object in the fi Conversion Function

Often a specific numerictype is used in many places, and it is convenient to predefine numerictype objects for use in the conversion functions. Predefining these objects is a good practice because it also puts the data type specification in one place.

T8 = numerictype(1,8,0)
T16 = numerictype(1,16,0)

T8 =


          DataTypeMode: Fixed-point: binary point scaling
            Signedness: Signed
            WordLength: 8
        FractionLength: 0

T16 =


          DataTypeMode: Fixed-point: binary point scaling
            Signedness: Signed
            WordLength: 16
        FractionLength: 0

B = fi(32767,T16)
A = fi(B,T8)

B = 

       32767
      numerictype(1,16,0)

A = 

   127
      numerictype(1,8,0)

Casting with the reinterpretcast Function

You can convert fixed-point and built-in data types without changing the underlying data. The Fixed-Point Designer reinterpretcast function performs this type of conversion.

In the following example, B is an unsigned fi object with a word length of 8 bits and a fraction length of 5 bits. The reinterpretcast function converts B into a signed fi object A with a word length of 8 bits and a fraction length of 1 bit. The real-world values of A and B differ, but their binary representations are the same.

B = fi([pi/4 1 pi/2 4],0,8,5)
T = numerictype(1,8,1);
A = reinterpretcast(B,T)

B = 

    0.7813    1.0000    1.5625    4.0000

          DataTypeMode: Fixed-point: binary point scaling
            Signedness: Unsigned
            WordLength: 8
        FractionLength: 5

A = 

   12.5000   16.0000   25.0000  -64.0000

          DataTypeMode: Fixed-point: binary point scaling
            Signedness: Signed
            WordLength: 8
        FractionLength: 1

To verify that the underlying data has not changed, compare the binary representations of A and B:

binary_B = bin(B)
binary_A = bin(A)

binary_B =

    '00011001   00100000   00110010   10000000'


binary_A =

    '00011001   00100000   00110010   10000000'

Casting with the cast Function

Using the cast function, you can convert the value of a variable to the same numerictype, complexity, and fimath as another variable.

In the following example, a is cast to the data type of b. The output, c, has the same numerictype and fimath properties as b, and the value of a.

a = pi;
b = fi([],1,16,13,'RoundingMethod','Floor');
c = cast(a,'like',b)

c = 

    3.1415

          DataTypeMode: Fixed-point: binary point scaling
            Signedness: Signed
            WordLength: 16
        FractionLength: 13

        RoundingMethod: Floor
        OverflowAction: Saturate
           ProductMode: FullPrecision
               SumMode: FullPrecision

Using this syntax allows you to specify data types separately from your algorithmic code as described in Manual Fixed-Point Conversion Best Practices.