Define Input Properties at the Command Line
Define Input Properties by Example at the Command Line
Command-Line Option -args
The
fiaccel function provides a
command-line option -args for specifying the properties of
primary (entry-point) function inputs as a cell array of example values or types.
The cell array can be a variable or literal array of constant values. Using this
option, you specify the properties of inputs at the same time as you generate code
for the MATLAB® function with fiaccel.
You can also create coder.Type objects interactively by using the
Coder Type Editor. See Create and Edit Input Types by Using the Coder Type Editor (MATLAB Coder).
Rules for Using the -args Option
When using the -args command-line option to define properties
by example, follow these rules:
The order of elements in the cell array must correspond to the order in which inputs appear in the primary function signature. For example, the first element in the cell array defines the properties of the first primary function input.
To generate fewer arguments than those arguments that occur in the MATLAB function, specify properties for only the number of arguments that you want in the generated function.
If the MATLAB function has input arguments, to generate a function that has no input arguments, pass an empty cell array to
-args.For each primary function input whose class is fixed point (
fi), specify the inputnumerictypeandfimathproperties.For each primary function input whose class is
struct, specify the properties of each of its fields in the order that they appear in the structure definition.
Specifying Properties of Primary Inputs by Example
Consider a function that adds its two inputs:
function y = emcf(u,v) %#codegen % The directive %#codegen indicates that you % intend to generate code for this algorithm y = u + v;
The following examples show how to specify different properties of the primary
inputs u and v by example at the command line:
Use a literal cell array of constants to specify that both inputs are real, scalar, fixed-point values:
fiaccel -o emcfx emcf ... -args {fi(0,1,16,15),fi(0,1,16,15)}Use a literal cell array of constants to specify that input
uis an unsigned 16-bit, 1-by-4 vector and inputvis a scalar, fixed-point value:fiaccel -o emcfx emcf ... -args {zeros(1,4,'uint16'),fi(0,1,16,15)}Assign sample values to a cell array variable to specify that both inputs are real, unsigned 8-bit integer vectors:
a = fi([1;2;3;4],0,8,0) b = fi([5;6;7;8],0,8,0) ex = {a,b} fiaccel -o emcfx emcf -args ex
Specifying Properties of Primary Fixed-Point Inputs by Example
Consider a function that calculates the square root of a fixed-point number:
function y = sqrtfi(x) %#codegen y = sqrt(x);
To specify the properties of the primary fixed-point input x by
example on the MATLAB command line, follow these steps:
Define the
numerictypeproperties forx, as in this example:T = numerictype('WordLength',32,... 'FractionLength',23,'Signed',true);Define the
fimathproperties forx, as in this example:F = fimath('SumMode','SpecifyPrecision',... 'SumWordLength',32,'SumFractionLength',23,... 'ProductMode','SpecifyPrecision', ... ProductWordLength',32,'ProductFractionLength',23);Create a fixed-point variable with the
numerictypeandfimathproperties you defined, as in this example:myeg = { fi(4.0,T,F) };Compile the function
sqrtfiusing thefiaccelcommand, passing the variablemyegas the argument to the-argsoption, as in this example:fiaccel sqrtfi -args myeg;
Specify Constant Inputs at the Command Line
If you know that your primary inputs do not change at run time, you can reduce overhead in the generated code by specifying that the primary inputs are constant values. Constant inputs are commonly used for flags that control how an algorithm executes and values that specify the sizes or types of data.
To specify that inputs are constants, use the -args command-line
option with a coder.Constant object. To specify that an input is a
constant with the size, class, complexity, and value of
constant_input, use the following
syntax:
-args {coder.Constant(constant_input)}Calling Functions with Constant Inputs
fiaccel compiles constant function inputs into the generated
code. As a result, the MEX function signature differs from the MATLAB function signature. At run time, you supply the constant argument to
the MATLAB function, but not to the MEX function.
For example, consider the following function identity which
copies its input to its
output:
function y = identity(u) %#codegen y = u;
To generate a MEX function identity_mex with a constant input,
type the following command at the MATLAB prompt:
fiaccel -o identity_mex identity...
-args {coder.Constant(fi(0.1,1,16,15))}To run the MATLAB function, supply the constant argument as follows:
identity(fi(0.1,1,16,15))
You get the following result:
ans =
0.1000Now, try running the MEX function with this command:
identity_mex
You should get the same answer.
Specifying a Structure as a Constant Input
Suppose that you define a structure tmp in the MATLAB workspace to specify the dimensions of a matrix, as
follows:
tmp = struct('rows', 2, 'cols', 3);The following MATLAB function rowcol accepts a structure input
p to define matrix y:
function y = rowcol(u,p) %#codegen y = fi(zeros(p.rows,p.cols),1,16,15) + u;
The following example shows how to specify that primary input u
is a double scalar variable and primary input p is a constant
structure:
fiaccel rowcol ...
-args {fi(0,1,16,15),coder.Constant(tmp)}To run this code, use
u = fi(0.5,1,16,15) y_m = rowcol(u,tmp) y_mex = rowcol_mex(u)
Specify Variable-Size Inputs at the Command Line
Variable-size data is data whose size might change at run time. MATLAB supports bounded and unbounded variable-size data for code generation.
Bounded variable-size data has fixed upper bounds. This data
can be allocated statically on the stack or dynamically on the heap.
Unbounded variable-size data does not have fixed upper
bounds. This data must be allocated on the heap. You can define inputs to have one or
more variable-size dimensions — and specify their upper bounds — using the
-args option and coder.typeof
function:
-args {coder.typeof(example_value, size_vector, variable_dims)}Same class and complexity as
example_valueSame size and upper bounds as
size_vectorVariable dimensions specified by
variable_dims
When you enable dynamic memory allocation, you can specify Inf in
the size vector for dimensions with unknown upper bounds at compile time.
When variable_dims is a scalar, it is applied to
all the dimensions, with the following exceptions:
If the dimension is 1 or 0, which are fixed.
If the dimension is unbounded, which is always variable size.
Specifying a Variable-Size Vector Input
Write a function that computes the sum of every
nelements of a vectorAand stores them in a vectorB:function B = nway(A,n) %#codegen % Compute sum of every N elements of A and put them in B. coder.extrinsic('error'); Tb = numerictype(1,32,24); if ((mod(numel(A),n) == 0) && ... (n>=1 && n<=numel(A))) B = fi(zeros(1,numel(A)/n),Tb); k = 1; for i = 1 : numel(A)/n B(i) = sum(A(k + (0:n-1))); k = k + n; end else B = fi(zeros(1,0),Tb); error('n<=0 or does not divide evenly'); endSpecify the first input
Aas afiobject. Its first dimension stays fixed in size and its second dimension can grow to an upper bound of 100. Specify the second inputnas a double scalar.fiaccel nway ... -args {coder.typeof(fi(0,1,16,15,'SumMode','KeepLSB'),[1 100],1),0}... -reportAs an alternative, assign the
coder.typeofexpression to a MATLAB variable, then pass the variable as an argument to-args:vareg = coder.typeof(fi(0,1,16,15,'SumMode','KeepLSB'),[1 100],1) fiaccel nway -args {vareg, double(0)} -report
