stdlib-js · Planeshifter · Feb 16, 2026 · Feb 16, 2026
diff --git a/lib/node_modules/@stdlib/repl/code-blocks/data/data.csv b/lib/node_modules/@stdlib/repl/code-blocks/data/data.csv
@@ -228,7 +228,7 @@ base.capitalize,"var out = base.capitalize( 'beep' )\nout = base.capitalize( 'Bo
 base.cbrt,"var y = base.cbrt( 64.0 )\ny = base.cbrt( 27.0 )\ny = base.cbrt( 0.0 )\ny = base.cbrt( -0.0 )\ny = base.cbrt( -9.0 )\ny = base.cbrt( NaN )\n"
 base.cbrtf,"var y = base.cbrtf( 64.0 )\ny = base.cbrtf( 27.0 )\ny = base.cbrtf( 0.0 )\ny = base.cbrtf( -0.0 )\ny = base.cbrtf( -9.0 )\ny = base.cbrtf( NaN )\n"
 base.cceil,"var v = base.cceil( new Complex128( -1.5, 2.5 ) )\n"
-base.cceilf,"var v = base.cceilf( new Complex64( -1.5, 2.5 ) )\nvar re = realf( v )\nvar im = imagf( v )\n"
+base.cceilf,"var v = base.cceilf( new Complex64( -1.5, 2.5 ) )\n"
 base.cceiln,"var out = base.cceiln( new Complex128( 5.555, -3.333 ), -2 )\nvar re = real( out )\nvar im = imag( out )\n"
 base.ccis,"var y = base.ccis( new Complex128( 0.0, 0.0 ) )\ny = base.ccis( new Complex128( 1.0, 0.0 ) )\n"
 base.cdiv,"var z1 = new Complex128( -13.0, -1.0 )\nvar z2 = new Complex128( -2.0, 1.0 )\nvar y = base.cdiv( z1, z2 )\nvar re = real( y )\nvar im = imag( y )\n"

diff --git a/lib/node_modules/@stdlib/repl/code-blocks/data/data.json b/lib/node_modules/@stdlib/repl/code-blocks/data/data.json
diff --git a/lib/node_modules/@stdlib/repl/help/data/data.csv b/lib/node_modules/@stdlib/repl/help/data/data.csv
@@ -228,7 +228,7 @@ base.capitalize,"\nbase.capitalize( str )\n    Capitalizes the first character i
 base.cbrt,"\nbase.cbrt( x )\n    Computes the cube root of a double-precision floating-point number.\n\n    Parameters\n    ----------\n    x: number\n        Input value.\n\n    Returns\n    -------\n    y: number\n        Cube root.\n\n    Examples\n    --------\n    > var y = base.cbrt( 64.0 )\n    4.0\n    > y = base.cbrt( 27.0 )\n    3.0\n    > y = base.cbrt( 0.0 )\n    0.0\n    > y = base.cbrt( -0.0 )\n    -0.0\n    > y = base.cbrt( -9.0 )\n    ~-2.08\n    > y = base.cbrt( NaN )\n    NaN\n\n    See Also\n    --------\n    base.pow, base.sqrt\n"
 base.cbrtf,"\nbase.cbrtf( x )\n    Computes the cube root of a single-precision floating-point number.\n\n    Parameters\n    ----------\n    x: number\n        Input value.\n\n    Returns\n    -------\n    y: number\n        Cube root.\n\n    Examples\n    --------\n    > var y = base.cbrtf( 64.0 )\n    4.0\n    > y = base.cbrtf( 27.0 )\n    3.0\n    > y = base.cbrtf( 0.0 )\n    0.0\n    > y = base.cbrtf( -0.0 )\n    -0.0\n    > y = base.cbrtf( -9.0 )\n    ~-2.08\n    > y = base.cbrtf( NaN )\n    NaN\n\n    See Also\n    --------\n    base.cbrt, base.sqrtf\n"
 base.cceil,"\nbase.cceil( z )\n    Rounds each component of a double-precision complex floating-point number\n    toward positive infinity.\n\n    Parameters\n    ----------\n    z: Complex128\n        Complex number.\n\n    Returns\n    -------\n    out: Complex128\n        Result.\n\n    Examples\n    --------\n    > var v = base.cceil( new Complex128( -1.5, 2.5 ) )\n    <Complex128>[ -1.0, 3.0 ]\n\n    See Also\n    --------\n    base.cceiln, base.cfloor, base.cround\n"
-base.cceilf,"\nbase.cceilf( z )\n    Rounds each component of a single-precision complex floating-point number\n    toward positive infinity.\n\n    Parameters\n    ----------\n    z: Complex64\n        Complex number.\n\n    Returns\n    -------\n    out: Complex64\n        Result.\n\n    Examples\n    --------\n    > var v = base.cceilf( new Complex64( -1.5, 2.5 ) )\n    <Complex64>\n    > var re = realf( v )\n    -1.0\n    > var im = imagf( v )\n    3.0\n\n    See Also\n    --------\n    base.cceil\n"
+base.cceilf,"\nbase.cceilf( z )\n    Rounds each component of a single-precision complex floating-point number\n    toward positive infinity.\n\n    Parameters\n    ----------\n    z: Complex64\n        Complex number.\n\n    Returns\n    -------\n    out: Complex64\n        Result.\n\n    Examples\n    --------\n    > var v = base.cceilf( new Complex64( -1.5, 2.5 ) )\n    <Complex64>[ -1.0, 3.0 ]\n\n    See Also\n    --------\n    base.cceil\n"
 base.cceiln,"\nbase.cceiln( z, n )\n    Rounds each component of a double-precision complex number to the nearest\n    multiple of `10^n` toward positive infinity.\n\n    Parameters\n    ----------\n    z: Complex128\n        Complex number.\n\n    n: integer\n        Integer power of 10.\n\n    Returns\n    -------\n    out: Complex128\n        Real and imaginary components.\n\n    Examples\n    --------\n    > var out = base.cceiln( new Complex128( 5.555, -3.333 ), -2 )\n    <Complex128>\n    > var re = real( out )\n    5.56\n    > var im = imag( out )\n    -3.33\n\n    See Also\n    --------\n    base.cceil, base.cfloorn, base.croundn\n"
 base.ccis,"\nbase.ccis( z )\n    Evaluates the cis function for a double-precision complex floating-point\n    number.\n\n    Parameters\n    ----------\n    z: Complex128\n        Complex number.\n\n    Returns\n    -------\n    out: Complex128\n        Complex number.\n\n    Examples\n    --------\n    > var y = base.ccis( new Complex128( 0.0, 0.0 ) )\n    <Complex128>[ 1.0, 0.0 ]\n    > y = base.ccis( new Complex128( 1.0, 0.0 ) )\n    <Complex128>[ ~0.540, ~0.841 ]\n\n"
 base.cdiv,"\nbase.cdiv( z1, z2 )\n    Divides two double-precision complex floating-point numbers.\n\n    Parameters\n    ----------\n    z1: Complex128\n        Complex number.\n\n    z2: Complex128\n        Complex number.\n\n    Returns\n    -------\n    out: Complex128\n        Result.\n\n    Examples\n    --------\n    > var z1 = new Complex128( -13.0, -1.0 )\n    <Complex128>\n    > var z2 = new Complex128( -2.0, 1.0 )\n    <Complex128>\n    > var y = base.cdiv( z1, z2 )\n    <Complex128>\n    > var re = real( y )\n    5.0\n    > var im = imag( y )\n    3.0\n\n\nbase.cdiv.assign( re1, im1, re2, im2, out, strideOut, offsetOut )\n    Divides two double-precision complex floating-point numbers and assigns\n    results to a provided output array.\n\n    Parameters\n    ----------\n    re1: number\n        Real component of the first complex number.\n\n    im1: number\n        Imaginary component of the first complex number.\n\n    re2: number\n        Real component of the second complex number.\n\n    im2: number\n        Imaginary component of the second complex number.\n\n    out: ArrayLikeObject\n        Output array.\n\n    strideOut: integer\n        Stride length.\n\n    offsetOut: integer\n        Starting index.\n\n    Returns\n    -------\n    out: ArrayLikeObject\n        Output array.\n\n    Examples\n    --------\n    > var out = new Float64Array( 2 );\n    > base.cdiv.assign( -13.0, -1.0, -2.0, 1.0, out, 1, 0 )\n    <Float64Array>[ 5.0, 3.0 ]\n\n\nbase.cdiv.strided( z1, sz1, oz1, z2, sz2, oz2, out, so, oo )\n    Divides two double-precision complex floating-point numbers stored in real-\n    valued strided array views and assigns results to a provided strided output\n    array.\n\n    Parameters\n    ----------\n    z1: ArrayLikeObject\n        First complex number view.\n\n    sz1: integer\n        Stride length for `z1`.\n\n    oz1: integer\n        Starting index for `z1`.\n\n    z2: ArrayLikeObject\n        Second complex number view.\n\n    sz2: integer\n        Stride length for `z2`.\n\n    oz2: integer\n        Starting index for `z2`.\n\n    out: ArrayLikeObject\n        Output array.\n\n    so: integer\n        Stride length for `out`.\n\n    oo: integer\n        Starting index for `out`.\n\n    Returns\n    -------\n    out: ArrayLikeObject\n        Output array.\n\n    Examples\n    --------\n    > var z1 = new Float64Array( [ -13.0, -1.0 ] );\n    > var z2 = new Float64Array( [ -2.0, 1.0 ] );\n    > var out = new Float64Array( 2 );\n    > base.cdiv.strided( z1, 1, 0, z2, 1, 0, out, 1, 0 )\n    <Float64Array>[ 5.0, 3.0 ]\n\n    See Also\n    --------\n    base.cadd, base.cmul, base.csub"

diff --git a/lib/node_modules/@stdlib/repl/help/data/data.json b/lib/node_modules/@stdlib/repl/help/data/data.json