ndarray-base-every

Test whether every element in an ndarray is truthy.

https://github.com/stdlib-js/ndarray-base-every

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all array base every javascript ndarray node node-js nodejs stdlib strided truthy utility utils

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Test whether every element in an ndarray is truthy.

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Host: GitHub
Owner: stdlib-js
License: apache-2.0
Language: C
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Homepage: https://github.com/stdlib-js/stdlib
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all array base every javascript ndarray node node-js nodejs stdlib strided truthy utility utils

Created 11 months ago · Last pushed 8 months ago

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every

Test whether every element in an ndarray is truthy.

## Installation ```bash npm install @stdlib/ndarray-base-every ``` Alternatively, - To load the package in a website via a `script` tag without installation and bundlers, use the [ES Module][es-module] available on the [`esm`][esm-url] branch (see [README][esm-readme]). - If you are using Deno, visit the [`deno`][deno-url] branch (see [README][deno-readme] for usage intructions). - For use in Observable, or in browser/node environments, use the [Universal Module Definition (UMD)][umd] build available on the [`umd`][umd-url] branch (see [README][umd-readme]). The [branches.md][branches-url] file summarizes the available branches and displays a diagram illustrating their relationships. To view installation and usage instructions specific to each branch build, be sure to explicitly navigate to the respective README files on each branch, as linked to above.

## Usage ```javascript var every = require( '@stdlib/ndarray-base-every' ); ``` #### every( arrays ) Tests whether every element in an ndarray is truthy. ```javascript var Float64Array = require( '@stdlib/array-float64' ); // Create a data buffer: var xbuf = new Float64Array( [ 1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0 ] ); // Define the shape of the input array: var shape = [ 3, 1, 2 ]; // Define the array strides: var sx = [ 4, 4, 1 ]; // Define the index offset: var ox = 0; // Create the input ndarray-like object: var x = { 'dtype': 'float64', 'data': xbuf, 'shape': shape, 'strides': sx, 'offset': ox, 'order': 'row-major' }; // Test elements: var out = every( [ x ] ); // returns true ``` The function accepts the following arguments: - **arrays**: array-like object containing an input ndarray. The provided ndarray should be an `object` with the following properties: - **dtype**: data type. - **data**: data buffer. - **shape**: dimensions. - **strides**: stride lengths. - **offset**: index offset. - **order**: specifies whether an ndarray is row-major (C-style) or column major (Fortran-style).

## Notes - For very high-dimensional ndarrays which are non-contiguous, one should consider copying the underlying data to contiguous memory before performing the operation in order to achieve better performance.

## Examples ```javascript var bernoulli = require( '@stdlib/random-array-bernoulli' ); var ndarray2array = require( '@stdlib/ndarray-base-to-array' ); var every = require( '@stdlib/ndarray-base-every' ); var x = { 'dtype': 'generic', 'data': bernoulli( 10, 0.9, { 'dtype': 'generic' }), 'shape': [ 5, 2 ], 'strides': [ 2, 1 ], 'offset': 0, 'order': 'row-major' }; console.log( ndarray2array( x.data, x.shape, x.strides, x.offset, x.order ) ); var out = every( [ x ] ); console.log( out ); ```

## C APIs

Character codes for data types: - **x**: `bool` (boolean). - **z**: `complex128` (double-precision floating-point complex number). - **c**: `complex64` (single-precision floating-point complex number). - **f**: `float32` (single-precision floating-point number). - **d**: `float64` (double-precision floating-point number). - **k**: `int16` (signed 16-bit integer). - **i**: `int32` (signed 32-bit integer). - **s**: `int8` (signed 8-bit integer). - **t**: `uint16` (unsigned 16-bit integer). - **u**: `uint32` (unsigned 32-bit integer). - **b**: `uint8` (unsigned 8-bit integer). Function name suffix naming convention: ```text stdlib_ndarray_every__ ``` For example, ```c void stdlib_ndarray_every_d_x(...) {...} ``` is a function which accepts one double-precision floating-point input ndarray and one boolean output ndarray. Function name suffix naming convention for applying a predicate function: ```text stdlib_ndarray_every_by__[_as__] ``` For example, ```c void stdlib_ndarray_every_by_d_x(...) {...} ``` is a function which accepts one double-precision floating-point input ndarray and one boolean output ndarray. In other words, the suffix encodes the function type signature. To support callbacks whose input arguments are of a different data type than the input ndarray data type, the naming convention supports appending an `as` suffix. For example, ```c void stdlib_ndarray_every_by_f_x_as_d_x(...) {...} ``` is a function which accepts one single-precision floating-point input ndarray and one boolean output ndarray. However, the callback accepts double-precision floating-point numbers. Accordingly, the input values need to be cast using the following conversion sequence ```c #include // Convert each input array element to double-precision: double in1 = (double)x[ i ]; // Evaluate the callback: bool out = f( in1 ); ```

### Usage ```c #include "stdlib/ndarray/base/every.h" ``` #### stdlib_ndarray_every_b_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_b_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_b_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_c_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float32/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_COMPLEX64; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 16, 8 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_c_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_c_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_d_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT64; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 16, 8 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_d_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_d_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_f_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_f_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_f_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_i_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_i_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_i_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_k_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_k_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_k_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_s_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_s_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_s_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_t_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_t_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_t_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_u_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_u_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_u_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_x_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_BOOL; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_x_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_x_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_z_x( \*arrays\[], \*data ) Tests whether every element in an input ndarray is truthy. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_COMPLEX128; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 32, 16 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_z_x( arrays, NULL ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to a zero-dimensional output ndarray. - **data**: `[in] void*` function data. This argument is unused and should be a `NULL` pointer. ```c int8_t stdlib_ndarray_every_z_x( struct ndarray *arrays[], void *data ); ``` #### stdlib_ndarray_every_by_b_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const uint8_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(uint8_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_c_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float32/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex64_t x ) { return ( stdlib_complex64_real( x ) == 0.0f && stdlib_complex64_imag( x ) == 0.0f ); } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_c_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex64_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_c_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_f_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const float x ) { return x == 0.0f; } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_f_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(float)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_f_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_i_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_i_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_i_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_k_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int16_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_k_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int16_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_k_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_t_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const uint16_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_t_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(uint16_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_t_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_u_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const uint32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_u_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(uint32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_u_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_b_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_b_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_b_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_c_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float32/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_COMPLEX64; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 16, 8 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex64_t x ) { return ( stdlib_complex64_real( x ) == 0.0f && stdlib_complex64_imag( x ) == 0.0f ); } // Test elements: int8_t status = stdlib_ndarray_every_by_c_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex64_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_c_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_c_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_COMPLEX64; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 16, 8 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_c_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_c_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT64; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 16, 8 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_d_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT64; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 16, 8 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_d_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_d_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_f_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const float x ) { return x == 0.0f; } // Test elements: int8_t status = stdlib_ndarray_every_by_f_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(float)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_f_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_f_x_as_c_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float32/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex64_t x ) { return ( stdlib_complex64_real( x ) == 0.0f && stdlib_complex64_imag( x ) == 0.0f ); } // Test elements: int8_t status = stdlib_ndarray_every_by_f_x_as_c_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex64_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_f_x_as_c_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_f_x_as_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_f_x_as_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_f_x_as_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_f_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_FLOAT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_f_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_f_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_i_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_i_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_i_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_i_x_as_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_i_x_as_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_i_x_as_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_i_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_i_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_i_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_k_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int16_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_k_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int16_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_k_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_k_x_as_c_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float32/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex64_t x ) { return ( stdlib_complex64_real( x ) == 0.0f && stdlib_complex64_imag( x ) == 0.0f ); } // Test elements: int8_t status = stdlib_ndarray_every_by_k_x_as_c_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex64_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_k_x_as_c_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_k_x_as_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_k_x_as_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_k_x_as_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_k_x_as_f_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const float x ) { return x == 0.0f; } // Test elements: int8_t status = stdlib_ndarray_every_by_k_x_as_f_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(float)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_k_x_as_f_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_k_x_as_i_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_k_x_as_i_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_k_x_as_i_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_k_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_k_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_k_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_s_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int8_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_s_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int8_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_s_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_s_x_as_c_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float32/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex64_t x ) { return ( stdlib_complex64_real( x ) == 0.0f && stdlib_complex64_imag( x ) == 0.0f ); } // Test elements: int8_t status = stdlib_ndarray_every_by_s_x_as_c_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex64_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_s_x_as_c_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_s_x_as_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_s_x_as_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_s_x_as_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_s_x_as_f_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const float x ) { return x == 0.0f; } // Test elements: int8_t status = stdlib_ndarray_every_by_s_x_as_f_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(float)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_s_x_as_f_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_s_x_as_i_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_s_x_as_i_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_s_x_as_i_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_s_x_as_k_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int16_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_s_x_as_k_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int16_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_s_x_as_k_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_s_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_INT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_s_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_s_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_t_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const uint16_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_t_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(uint16_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_t_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_t_x_as_c_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float32/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex64_t x ) { return ( stdlib_complex64_real( x ) == 0.0f && stdlib_complex64_imag( x ) == 0.0f ); } // Test elements: int8_t status = stdlib_ndarray_every_by_t_x_as_c_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex64_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_t_x_as_c_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_t_x_as_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_t_x_as_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_t_x_as_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_t_x_as_f_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const float x ) { return x == 0.0f; } // Test elements: int8_t status = stdlib_ndarray_every_by_t_x_as_f_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(float)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_t_x_as_f_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_t_x_as_i_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const int32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_t_x_as_i_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(int32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_t_x_as_i_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_t_x_as_u_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const uint32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_t_x_as_u_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(uint32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_t_x_as_u_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_t_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT16; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_t_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_t_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_u_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const uint32_t x ) { return x == 0; } // Test elements: int8_t status = stdlib_ndarray_every_by_u_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(uint32_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_u_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_u_x_as_d_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const double x ) { return x == 0.0; } // Test elements: int8_t status = stdlib_ndarray_every_by_u_x_as_d_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(double)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_u_x_as_d_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_u_x_as_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT32; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 8, 4 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_u_x_as_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_u_x_as_z_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_x_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_BOOL; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 2, 1 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const bool x ) { return x; } // Test elements: int8_t status = stdlib_ndarray_every_by_x_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(bool)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_x_x( struct ndarray *arrays[], void *fcn ); ``` #### stdlib_ndarray_every_by_z_x( \*arrays\[], \*fcn ) Tests whether every element in an input ndarray is truthy according to a predicate function. ```c #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include "stdlib/complex/float64/ctor.h" #include #include #include #include // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_COMPLEX128; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; uint8_t ybuf[] = { 0 }; // Define the number of dimensions: int64_t ndims = 2; // Define the array shapes: int64_t shx[] = { 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 32, 16 }; int64_t sy[] = { 0 }; // Define the index offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Define a callback: static bool fcn( const stdlib_complex128_t x ) { return ( stdlib_complex128_real( x ) == 0.0 && stdlib_complex128_imag( x ) == 0.0 ); } // Test elements: int8_t status = stdlib_ndarray_every_by_z_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // ... // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); ``` The function accepts the following arguments: - **arrays**: `[inout] struct ndarray**` array whose first element is a pointer to an input ndarray and whose second element is a pointer to an output ndarray. - **fcn**: `[in] void*` a `bool (*f)(stdlib_complex128_t)` predicate function to apply provided as a `void` pointer. ```c int8_t stdlib_ndarray_every_by_z_x( struct ndarray *arrays[], void *fcn ); ```

### Examples ```c #include "stdlib/ndarray/base/every.h" #include "stdlib/ndarray/dtypes.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include "stdlib/ndarray/ctor.h" #include #include #include #include #include static void print_ndarray_contents( const struct ndarray *x ) { int64_t i; int8_t s; bool v; for ( i = 0; i < stdlib_ndarray_length( x ); i++ ) { s = stdlib_ndarray_iget_bool( x, i, &v ); if ( s != 0 ) { fprintf( stderr, "Unable to resolve data element.\n" ); exit( EXIT_FAILURE ); } fprintf( stdout, "data[%"PRId64"] = %s\n", i, ( v ) ? "true" : "false" ); } } static bool fcn( const uint8_t x ) { return ( x != 0 ); } int main( void ) { // Define the ndarray data types: enum STDLIB_NDARRAY_DTYPE xdtype = STDLIB_NDARRAY_UINT8; enum STDLIB_NDARRAY_DTYPE ydtype = STDLIB_NDARRAY_BOOL; // Create underlying byte arrays: uint8_t xbuf[] = { 1, 2, 3, 4, 5, 6, 7, 8 }; uint8_t ybuf[] = { 0 }; // Define the number of input array dimensions: int64_t ndims = 3; // Define the array shapes: int64_t shx[] = { 2, 2, 2 }; int64_t *shy = NULL; // Define the strides: int64_t sx[] = { 4, 2, 1 }; int64_t sy[] = { 0 }; // Define the offsets: int64_t ox = 0; int64_t oy = 0; // Define the array order: enum STDLIB_NDARRAY_ORDER order = STDLIB_NDARRAY_ROW_MAJOR; // Specify the index mode: enum STDLIB_NDARRAY_INDEX_MODE imode = STDLIB_NDARRAY_INDEX_ERROR; // Specify the subscript index modes: int8_t submodes[] = { imode }; int64_t nsubmodes = 1; // Create an input ndarray: struct ndarray *x = stdlib_ndarray_allocate( xdtype, xbuf, ndims, shx, sx, ox, order, imode, nsubmodes, submodes ); if ( x == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Create an output ndarray: struct ndarray *y = stdlib_ndarray_allocate( ydtype, ybuf, 0, shy, sy, oy, order, imode, nsubmodes, submodes ); if ( y == NULL ) { fprintf( stderr, "Error allocating memory.\n" ); exit( EXIT_FAILURE ); } // Define an array containing the ndarrays: struct ndarray *arrays[] = { x, y }; // Test elements: int8_t status = stdlib_ndarray_every_by_b_x( arrays, (void *)fcn ); if ( status != 0 ) { fprintf( stderr, "Error during computation.\n" ); exit( EXIT_FAILURE ); } // Print the results: print_ndarray_contents( y ); fprintf( stdout, "\n" ); // Free allocated memory: stdlib_ndarray_free( x ); stdlib_ndarray_free( y ); } ```

* * * ## Notice This package is part of [stdlib][stdlib], a standard library for JavaScript and Node.js, with an emphasis on numerical and scientific computing. The library provides a collection of robust, high performance libraries for mathematics, statistics, streams, utilities, and more. For more information on the project, filing bug reports and feature requests, and guidance on how to develop [stdlib][stdlib], see the main project [repository][stdlib]. #### Community [![Chat][chat-image]][chat-url] --- ## License See [LICENSE][stdlib-license]. ## Copyright Copyright © 2016-2025. The Stdlib [Authors][stdlib-authors].

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Standard library for JavaScript.

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  Standard library for JavaScript and Node.js.

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package.json npm

@stdlib/array-typed-complex-ctors ^0.2.2 development
@stdlib/assert-is-boolean ^0.2.2 development
@stdlib/bench-harness ^0.2.2 development
@stdlib/math-base-special-cbrt ^0.2.2 development
@stdlib/math-base-special-floor ^0.2.3 development
@stdlib/math-base-special-pow ^0.3.0 development
@stdlib/math-base-special-sqrt ^0.2.2 development
@stdlib/ndarray-base-shape2strides ^0.2.2 development
@stdlib/ndarray-base-to-array ^0.2.1 development
@stdlib/random-array-bernoulli ^0.2.1 development
@stdlib/random-array-discrete-uniform ^0.2.1 development
istanbul ^0.4.1 development
tap-min git+https://github.com/Planeshifter/tap-min.git development
tape git+https://github.com/kgryte/tape.git#fix/globby development
@stdlib/array-base-assert-is-booleanarray ^0.0.2
@stdlib/array-base-assert-is-complex-typed-array ^0.1.2
@stdlib/blas-base-gscal ^0.2.2
@stdlib/ndarray-base-iteration-order ^0.2.2
@stdlib/ndarray-base-minmax-view-buffer-index ^0.2.2
@stdlib/ndarray-base-ndarraylike2object ^0.2.2
@stdlib/ndarray-base-nullary-loop-interchange-order ^0.2.2
@stdlib/ndarray-base-nullary-tiling-block-size ^0.2.2
@stdlib/ndarray-base-numel ^0.2.2
@stdlib/ndarray-base-vind2bind ^0.2.2
@stdlib/strided-base-reinterpret-boolean ^0.0.2
@stdlib/strided-base-reinterpret-complex ^0.1.2
@stdlib/types ^0.4.3

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