y =
ceil (x)
¶Return the smallest integer not less than x.
This is equivalent to rounding towards positive infinity.
If x is complex, return
ceil (real (x)) + ceil (imag (x)) * I
.
ceil ([-2.7, 2.7]) ⇒ -2 3
y =
fix (x)
¶Truncate fractional portion of x and return the integer portion.
This is equivalent to rounding towards zero. If x is complex, return
fix (real (x)) + fix (imag (x)) * I
.
fix ([-2.7, 2.7]) ⇒ -2 2
y =
floor (x)
¶Return the largest integer not greater than x.
This is equivalent to rounding towards negative infinity. If x is
complex, return floor (real (x)) + floor (imag (x)) * I
.
floor ([-2.7, 2.7]) ⇒ -3 2
y =
round (x)
¶Return the integer nearest to x.
If x is complex, return
round (real (x)) + round (imag (x)) * I
. If there
are two nearest integers, return the one further away from zero.
round ([-2.7, 2.7]) ⇒ -3 3
y =
roundb (x)
¶Return the integer nearest to x. If there are two nearest integers, return the even one (banker’s rounding).
If x is complex,
return roundb (real (x)) + roundb (imag (x)) * I
.
See also: round.
m =
max (x)
¶m =
max (x, [], dim)
¶[m, im] =
max (x)
¶m =
max (x, y)
¶Find maximum values in the array x.
For a vector argument, return the maximum value. For a matrix argument,
return a row vector with the maximum value of each column. For a
multi-dimensional array, max
operates along the first non-singleton
dimension.
If the optional third argument dim is present then operate along this dimension. In this case the second argument is ignored and should be set to the empty matrix.
For two inputs (x and y), return the pairwise maximum according to the rules for Broadcasting.
Thus,
max (max (x))
returns the largest element of the 2-D matrix x, and
max (2:5, pi) ⇒ 3.1416 3.1416 4.0000 5.0000
compares each element of the range 2:5
with pi
, and returns a
row vector of the maximum values.
For complex arguments, the magnitude of the elements are used for comparison. If the magnitudes are identical, then the results are ordered by phase angle in the range (-pi, pi]. Hence,
max ([-1 i 1 -i]) ⇒ -1
because all entries have magnitude 1, but -1 has the largest phase angle with value pi.
If called with one input and two output arguments, max
also returns
the first index of the maximum value(s). Thus,
[x, ix] = max ([1, 3, 5, 2, 5]) ⇒ x = 5 ix = 3
m =
min (x)
¶m =
min (x, [], dim)
¶[m, im] =
min (x)
¶m =
min (x, y)
¶Find minimum values in the array x.
For a vector argument, return the minimum value. For a matrix argument,
return a row vector with the minimum value of each column. For a
multi-dimensional array, min
operates along the first non-singleton
dimension.
If the optional third argument dim is present then operate along this dimension. In this case the second argument is ignored and should be set to the empty matrix.
For two inputs (x and y), return the pairwise minimum according to the rules for Broadcasting.
Thus,
min (min (x))
returns the smallest element of the 2-D matrix x, and
min (2:5, pi) ⇒ 2.0000 3.0000 3.1416 3.1416
compares each element of the range 2:5
with pi
, and returns a
row vector of the minimum values.
For complex arguments, the magnitude of the elements are used for comparison. If the magnitudes are identical, then the results are ordered by phase angle in the range (-pi, pi]. Hence,
min ([-1 i 1 -i]) ⇒ -i
because all entries have magnitude 1, but -i has the smallest phase angle with value -pi/2.
If called with one input and two output arguments, min
also returns
the first index of the minimum value(s). Thus,
[x, ix] = min ([1, 3, 0, 2, 0]) ⇒ x = 0 ix = 3
M =
cummax (x)
¶M =
cummax (x, dim)
¶[M, IM] =
cummax (…)
¶Return the cumulative maximum values along dimension dim.
If dim is unspecified it defaults to column-wise operation. For example:
cummax ([1 3 2 6 4 5]) ⇒ 1 3 3 6 6 6
If called with two output arguments the index of the maximum value is also returned.
[w, iw] = cummax ([1 3 2 6 4 5]) ⇒ M = 1 3 3 6 6 6 IM = 1 2 2 4 4 4
M =
cummin (x)
¶M =
cummin (x, dim)
¶[M, IM] =
cummin (x)
¶Return the cumulative minimum values along dimension dim.
If dim is unspecified it defaults to column-wise operation. For example:
cummin ([5 4 6 2 3 1]) ⇒ 5 4 4 2 2 1
If called with two output arguments the index of the minimum value is also returned.
[M, IM] = cummin ([5 4 6 2 3 1]) ⇒ M = 5 4 4 2 2 1 IM = 1 2 2 4 4 6
h =
hypot (x, y)
¶h =
hypot (x, y, z, …)
¶Compute the element-by-element square root of the sum of the squares of x and y.
This is equivalent to
sqrt (x.^2 + y.^2)
, but is calculated in a manner that
avoids overflows for large values of x or y.
hypot
can also be called with more than 2 arguments; in this case,
the arguments are accumulated from left to right:
hypot (hypot (x, y), z) hypot (hypot (hypot (x, y), z), w), etc.
dx =
gradient (m)
¶[dx, dy, dz, …] =
gradient (m)
¶[…] =
gradient (m, s)
¶[…] =
gradient (m, x, y, z, …)
¶[…] =
gradient (f, x0)
¶[…] =
gradient (f, x0, s)
¶[…] =
gradient (f, x0, x, y, …)
¶Calculate the gradient of sampled data or a function.
If m is a vector, calculate the one-dimensional gradient of m. If m is a matrix the gradient is calculated for each dimension.
[dx, dy] = gradient (m)
calculates the
one-dimensional gradient for x and y direction if m is a
matrix. Additional return arguments can be use for multi-dimensional
matrices.
A constant spacing between two points can be provided by the s parameter. If s is a scalar, it is assumed to be the spacing for all dimensions. Otherwise, separate values of the spacing can be supplied by the x, … arguments. Scalar values specify an equidistant spacing. Vector values for the x, … arguments specify the coordinate for that dimension. The length must match their respective dimension of m.
At boundary points a linear extrapolation is applied. Interior points are calculated with the first approximation of the numerical gradient
y'(i) = 1/(x(i+1)-x(i-1)) * (y(i-1)-y(i+1)).
If the first argument f is a function handle, the gradient of the
function at the points in x0 is approximated using central difference.
For example, gradient (@cos, 0)
approximates the gradient of the
cosine function in the point x0 = 0. As with sampled data, the
spacing values between the points from which the gradient is estimated can
be set via the s or dx, dy, … arguments. By default
a spacing of 1 is used.
z =
dot (x, y)
¶z =
dot (x, y, dim)
¶Compute the dot product of two vectors.
If x and y are matrices, calculate the dot products along the first non-singleton dimension.
If the optional argument dim is given, calculate the dot products along this dimension.
Implementation Note: This is equivalent to
sum (conj (X) .* Y, dim)
, but avoids forming a
temporary array and is faster. When X and Y are column vectors,
the result is equivalent to X' * Y
. Although, dot
is defined for integer arrays, the output may differ from the expected result
due to the limited range of integer objects.
See also: cross, divergence.
z =
cross (x, y)
¶z =
cross (x, y, dim)
¶Compute the vector cross product of two 3-dimensional vectors x and y.
If x and y are matrices, the cross product is applied along the first dimension with three elements.
The optional argument dim forces the cross product to be calculated along the specified dimension.
Example Code:
cross ([1, 1, 0], [0, 1, 1]) ⇒ 1 -1 1
See also: dot, curl, divergence.
div =
divergence (x, y, z, fx, fy, fz)
¶div =
divergence (fx, fy, fz)
¶div =
divergence (x, y, fx, fy)
¶div =
divergence (fx, fy)
¶Calculate divergence of a vector field given by the arrays fx, fy, and fz or fx, fy respectively.
d d d div F(x,y,z) = -- F(x,y,z) + -- F(x,y,z) + -- F(x,y,z) dx dy dz
The coordinates of the vector field can be given by the arguments x, y, z or x, y respectively.
[cx, cy, cz, v] =
curl (x, y, z, fx, fy, fz)
¶[cz, v] =
curl (x, y, fx, fy)
¶[…] =
curl (fx, fy, fz)
¶[…] =
curl (fx, fy)
¶v =
curl (…)
¶Calculate curl of vector field given by the arrays fx, fy, and fz or fx, fy respectively.
/ d d d d d d \ curl F(x,y,z) = | -- Fz - -- Fy, -- Fx - -- Fz, -- Fy - -- Fx | \ dy dz dz dx dx dy /
The coordinates of the vector field can be given by the arguments x, y, z or x, y respectively. v calculates the scalar component of the angular velocity vector in direction of the z-axis for two-dimensional input. For three-dimensional input the scalar rotation is calculated at each grid point in direction of the vector field at that point.
See also: divergence, gradient, del2, cross.
L =
del2 (M)
¶L =
del2 (M, h)
¶L =
del2 (M, dx, dy, …)
¶Calculate the discrete Laplace operator.
For a 2-dimensional matrix M this is defined as
1 / d^2 d^2 \ L = --- * | --- M(x,y) + --- M(x,y) | 4 \ dx^2 dy^2 /
For N-dimensional arrays the sum in parentheses is expanded to include second derivatives over the additional higher dimensions.
The spacing between evaluation points may be defined by h, which is a scalar defining the equidistant spacing in all dimensions. Alternatively, the spacing in each dimension may be defined separately by dx, dy, etc. A scalar spacing argument defines equidistant spacing, whereas a vector argument can be used to specify variable spacing. The length of the spacing vectors must match the respective dimension of M. The default spacing value is 1.
Dimensions with fewer than 3 data points are skipped. Boundary points are calculated from the linear extrapolation of interior points.
Example: Second derivative of 2*x^3
f = @(x) 2*x.^3; dd = @(x) 12*x; x = 1:6; L = 4*del2 (f(x)); assert (L, dd (x));
f =
factorial (n)
¶Return the factorial of n where n is a real non-negative integer.
If n is a scalar, this is equivalent to prod (1:n)
. For
vector or matrix arguments, return the factorial of each element in the
array.
For non-integers see the generalized factorial function gamma
.
Note that the factorial function grows large quite quickly, and even
with double precision values overflow will occur if n > 171. For
such cases consider gammaln
.
pf =
factor (q)
¶[pf, n] =
factor (q)
¶Return the prime factorization of q.
The prime factorization is defined as prod (pf) == q
where every element of pf is a prime number. If q == 1
,
return 1. The output pf is of the same numeric class as the input.
With two output arguments, return the unique prime factors pf and
their multiplicities. That is,
prod (pf .^ n) == q
.
Implementation Note: If the input q is single
or double
,
then it must not exceed the corresponding flintmax
. For larger
inputs, cast them to uint64
if they’re less than 2^64:
factor (uint64 (18446744073709011493)) ⇒ 571111 761213 42431951
For even larger inputs, use sym
if you have the Symbolic package
installed and loaded:
factor (sym ('9444733049654361449941')) ⇒ (sym) 1 1 1099511627689 ⋅8589934669
g =
gcd (a1, a2, …)
¶[g, v1, …] =
gcd (a1, a2, …)
¶Compute the greatest common divisor of a1, a2, ….
All arguments must be the same size or scalar. For arrays, the greatest common divisor is calculated for each element individually. All elements must be ordinary or Gaussian (complex) integers. Note that for Gaussian integers, the gcd is only unique up to a phase factor (multiplication by 1, -1, i, or -i), so an arbitrary greatest common divisor among the four possible is returned.
Optional return arguments v1, …, contain integer vectors such that,
g = v1 .* a1 + v2 .* a2 + …
Example code:
gcd ([15, 9], [20, 18]) ⇒ 5 9
Programming tip: To find the GCD of all the elements of a single array, use
num2cell
instead of nested calls or a loop:
x = [30 42 70 105]; # vector or array of inputs gcd (num2cell (x) {:}) ⇒ 1
l =
lcm (x, y)
¶l =
lcm (x, y, …)
¶Compute the least common multiple of x and y, or of the list of all arguments.
All inputs must be of the same size, or scalar. All elements must be real integer or Gaussian (complex) integer. For complex inputs, the result is unique only up to a phase factor (multiplication by +1, +i, -1, or -i), and one of the four is returned arbitrarily.
Example code:
lcm (5:8, 9:12) ⇒ 45 30 77 24
Programming tip: To find the LCM of all the elements of a single array, use
num2cell
instead of nested calls or a loop:
x = 1:10; # vector or array of inputs lcm (num2cell (x) {:}) ⇒ 2520
r =
rem (x, y)
¶Return the remainder of the division x / y
.
The remainder is computed using the expression
x - y .* fix (x ./ y)
An error message is printed if the dimensions of the arguments do not agree, or if either argument is complex.
Programming Notes: When calculating with floating point numbers (double,
single), values within a few eps of an integer will be rounded to that
integer before computation for compatibility with MATLAB. Any floating
point integers greater than flintmax
(2^53 for double) will not compute
correctly. For larger integer values convert the input to uint64
before
calling this function.
By convention,
rem (x, 0) = NaN if x is a floating point variable rem (x, 0) = 0 if x is an integer variable rem (x, y) returns a value with the signbit from x
For the opposite conventions see the mod
function. In general,
rem
is best when computing the remainder after division of two
positive numbers. For negative numbers, or when the values are
periodic, mod
is a better choice.
See also: mod.
m =
mod (x, y)
¶Compute the modulo of x and y.
Conceptually this is given by
x - y .* floor (x ./ y)
and is written such that the correct modulus is returned for integer types.
This function handles negative values correctly. That is,
mod (-1, 3)
is 2, not -1, as rem (-1, 3)
returns.
An error results if the dimensions of the arguments do not agree, or if either of the arguments is complex.
Programming Notes: When calculating with floating point numbers (double,
single), values within a few eps of an integer will be rounded to that
integer before computation for compatibility with MATLAB. Any floating
point integers greater than flintmax
(2^53 for double) will not compute
correctly. For larger integer values convert the input to uint64
before
calling this function.
By convention,
mod (x, 0) = x mod (x, y) returns a value with the signbit from y
For the opposite conventions see the rem
function. In general,
mod
is a better choice than rem
when any of the inputs are
negative numbers or when the values are periodic.
See also: rem.
p =
primes (n)
¶Return all primes up to n.
The output data class (double, single, uint32, etc.) is the same as the input class of n. The algorithm used is the Sieve of Eratosthenes.
Note: For a specific number n of primes, call
list_primes (n)
. Alternatively, call
primes (n*log (k*n))(1:n)
where k is
about 5 or 6. This works because the distance from one prime to the next is
proportional to the logarithm of the prime, on average. On integrating,
there are about n primes less than n * log (5*n)
.
See also: list_primes, isprime.
p =
list_primes ()
¶p =
list_primes (n)
¶List the first n primes.
If n is unspecified, the first 25 primes are listed.
y =
sign (x)
¶Compute the signum function.
This is defined as
-1, x < 0; sign (x) = 0, x = 0; 1, x > 0.
For complex arguments, sign
returns x ./ abs (x)
.
Note that sign (-0.0)
is 0. Although IEEE 754 floating point
allows zero to be signed, 0.0 and -0.0 compare equal. If you must test
whether zero is signed, use the signbit
function.
See also: signbit.
y =
signbit (x)
¶Return logical true if the value of x has its sign bit set and false otherwise.
This behavior is consistent with the other logical functions. See Logical Values. The behavior differs from the C language function which returns nonzero if the sign bit is set.
This is not the same as x < 0.0
, because IEEE 754 floating point
allows zero to be signed. The comparison -0.0 < 0.0
is false,
but signbit (-0.0)
will return a nonzero value.
See also: sign.