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Qalculate! library and CLI

Qalculate! is a multi-purpose cross-platform desktop calculator. It is simple to use but provides power and versatility normally reserved for complicated math packages, as well as useful tools for everyday needs (such as currency conversion and percent calculation). Features include a large library of customizable functions, unit calculations and conversion, symbolic calculations (including integrals and equations), arbitrary precision, uncertainty propagation, interval arithmetic, plotting, and a user-friendly interface (GTK+, Qt, and CLI).
[!TIP] Visit the website at https://qalculate.github.io/ to see additional screenshots, read the manual, and download the latest version.
For Linux distributions which provide separate development packages, these must be installed for all the required libraries (e.g. libmpfr-dev) before compilation.
Instructions and download links for installers, binaries packages, and the source code of released versions of Qalculate! are available at https://qalculate.github.io/downloads.html.
In a terminal window in the top source code directory run
* ./autogen.sh (not required if using a release source tarball, only if using the git version)
* ./configure
* make
* make install (as root, e.g. sudo make install)
* ldconfig (if necessary, as root)
If libqalculate is installed in /usr/local (default) you may need to add /usr/local/lib to the library path of the system (add /usr/local/lib to a file under /etc/ld.so.conf.d/ and run ldconfig).
The API documentation is included in the package and is installed in $docdir/libqalculate/html (usually /usr/share/doc/libqalculate/html). It is generated when running autogen.sh.
It is also available online at http://qalculate.github.io/reference/index.html.
To calculate a single expression from the command line (non-interactive mode) enter
qalc mathematical expression (e.g. qalc 5+2)
qalc --help shows information about command line options in non-interactive mode.
If you run qalc without any mathematical expression the program will start in interactive mode, where you can enter multiple expressions with history and completion, manipulate the result and change settings. Type help in interactive mode for more information.
A man page is also available (shown using the command man qalc, or online at https://qalculate.github.io/manual/qalc.html).
The main user interfaces for libqalculate are qalculate-gtk (https://github.com/Qalculate/qalculate-gtk) and qalculate-qt (https://github.com/Qalculate/qalculate-qt).
Other software using libqalculate include * Qalculator web app (https://qalculator.xyz/) (also available as an app for Android, iOS, and Windows) * Qalculate for Android (https://github.com/jherkenhoff/qalculate-android) * KDE Plasma Workspace (https://www.kde.org/workspaces/plasmadesktop/) * Cantor (http://kde.org/applications/education/cantor/) * Step (http://kde.org/applications/education/step/) * Qalculate widget for KDE Plasma (https://store.kde.org/p/1155946/)
…and more…
[!TIP] For more details about the syntax, and available functions, units, and variables, please consult the manual (https://qalculate.github.io/manual/).
[!NOTE] Semicolon can be replaced with comma in function arguments, if comma is not used as decimal or thousands separator.
sqrt 4 # = sqrt(4) = 4^(0.5) = 4^(1/2) = 2
sqrt(25; 16; 9; 4) # = [5 4 3 2]
sqrt(32) # = 4 × √(2) (in exact mode)
cbrt(-27) # = root(-27; 3) = −3 (real root)
(-27)^(1/3) # ≈ 1.5 + 2.5980762i (principal root)
ln 25 # = log(25; e) ≈ 3.2188758
log2(4)/log10(100) # = log(4; 2)/log(100; 10) = 1
5! # = 1 × 2 × 3 × 4 × 5 = 120
5\2 # = 5//2 = trunc(5 / 2) = 2 (integer division)
5 mod 3 # = mod(5; 3) = 2
52 to factors # = 2^2 × 13
25/4 * 3/5 to fraction # = 3 + 3/4
gcd(63; 27) # = 9
sin(pi/2) - cos(pi) # = sin(90 deg) − cos(180 deg) = 2
sum(x; 1; 5) # = 1 + 2 + 3 + 4 + 5 = 15
sum(\i^2+sin(\i); 1; 5; \i) # = 1^2 + sin(1) + 2^2 + sin(2) + … ≈ 55.176162
product(x; 1; 5) # = 1 × 2 × 3 × 4 × 5 = 120
var1:=5 # stores value 5 in variable var1
var1 * 2 # = 10
sinh(0.5) where sinh()=cosh() # = cosh(0.5) ≈ 1.1276260
plot(x^2; -5; 5) # plots the function y=x^2 from -5 to 5
[!TIP]
tocan be replace with an arrow (➞or->).
5 dm3 to l # = 5 dm^3 to L = 5 L
20 miles / 2 h to km/h # = 16.09344 km/h
1.74 to ft # = 1.74 m to ft ≈ 5 ft + 8.5039370 in
1.74 m to -ft # ≈ 5.7086614 ft
100 lbf * 60 mph to hp # ≈ 16 hp
50 Ω * 2 A # = 100 V
50 Ω * 2 A to base # = 100 kg·m²/(s³·A)
10 N / 5 Pa # = (10 N)/(5 Pa) = 2 m²
5 m/s to s/m # = 0.2 s/m
€500 - 20% to £ # ≈ £347.12
500 megabit/s * 2 h to b?byte # ≈ 419.09516 gibibytes
k_e / G * a_0
# = (CoulombsConstant / NewtonianConstant) × BohrRadius ≈ 7.126e9 kg·H·m^−1
ℎ / (λ_C * c)
# = planck ∕ (ComptonWavelength × SpeedOfLight) ≈ 9.1093837e-31 kg
5 ns * rydberg to c
# ≈ 6.0793194E-8c
atom(Hg; weight) + atom(C; weight) * 4 to g
# ≈ 4.129e-22 g
(G * planet(earth; mass) * planet(mars; mass))/(54.6e6 km)^2
# ≈ 8.58e16 N (gravitational attraction between earth and mars)
[!NOTE] Results with interval arithmetic activated are shown in parenthesis.
sin(5±0.2)^2/2±0.3 # ≈ 0.460±0.088 (0.46±0.12)
(2±0.02 J)/(523±5 W) # ≈ 3.824±0.053 ms (3.825±0.075 ms)
interval(-2; 5)^2 # ≈ interval(−8.2500000; 12.750000) (interval(0; 25))
[!TIP] "±" can be replaced with "+/-".
(5x^2 + 2)/(x - 3) # = 5x + 15 + 47/(x − 3)
(\a + \b)(\a - \b) # = 'a'^2 − 'b'^2
(x + 2)(x - 3)^3 # = x^4 − 7x^3 + 9x^2 + 27x − 54
x^4 - 7x^3 + 9x^2 + 27x - 54 to factors # = (x + 2)(x − 3)^3
cos(x)+3y^2 where x=pi; y=2 # = 11
gcd(25x; 5x^2) # = 5x
1/(x^2+2x-3) to partial fraction # = 1/(4x − 4) − 1/(4x + 12)
x+x^2+4 = 16 # x = 3 or x = −4
x^2/(5 m) - hypot(x; 4 m) = 2 m where x > 0 # x ≈ 7.1340411 m
cylinder(20cm; x) = 20l # x = (1 / (2π)) m ≈ 16 cm
asin(sqrt(x)) = 0.2 # x = sin(0.2)^2 ≈ 0.039469503
x^2 > 25x # x > 25 or x < 0
solve(x = y+ln(y); y) # = lambertw(e^x)
solve2(5x=2y^2; sqrt(y)=2; x; y) # = 32/5
multisolve([5x=2y+32, y=2z, z=2x]; [x, y, z]) # = [−32/3 −128/3 −64/3]
dsolve(diff(y; x) - 2y = 4x; 5) # = 6e^(2x) − 2x − 1
diff(6x^2) # = 12x
diff(sinh(x^2)/(5x) + 3xy/sqrt(x)) # = (2/5) × cosh(x^2) − sinh(x^2)/(5x^2) + (3y)/(2 × √(x))
integrate(6x^2) # = 2x^3 + C
integrate(6x^2; 1; 5) # = 248
integrate(sinh(x^2)/(5x) + 3xy/sqrt(x)) # = 2x × √(x) × y + Shi(x^2) / 10 + C
integrate(sinh(x^2)/(5x) + 3xy/sqrt(x); 1; 2) # ≈ 3.6568542y + 0.87600760
limit(ln(1 + 4x)/(3^x - 1); 0) # = 4 / ln(3)
[1, 2, 3; 4, 5, 6] # = [1 2 3; 4 5 6] (2×3 matrix)
1…5 = (1:5) = (1:1:5) # = [1 2 3 4 5]
(1; 2; 3) * 2 - 2 # = [(1 × 2 − 2), (2 × 2 − 2), (3 × 2 − 2)] = [0 2 4]
[1 2 3].[4 5 6] = dot([1 2 3]; [4 5 6]) # = 32 (dot product)
cross([1 2 3]; [4 5 6]) # = [−3 6 −3] (cross product)
[1 2 3; 4 5 6].*[7 8 9; 10 11 12] # = [7 16 27; 40 55 72] (hadamard product)
[1 2 3; 4 5 6] * [7 8; 9 10; 11 12] # = [58 64; 139 154] (matrix multiplication)
[1 2; 3 4]^-1 # = inverse([1 2; 3 4]) = [−2 1; 1.5 −0.5]
mean(5; 6; 4; 2; 3; 7) # = 4.5
stdev(5; 6; 4; 2; 3; 7) # ≈ 1.87
quartile([5 6 4 2 3 7]; 1) # = percentile((5; 6; 4; 2; 3; 7); 25) ≈ 2.9166667
normdist(7; 5) # ≈ 0.053990967
spearman(column(load(test.csv); 1); column(load(test.csv); 2))
# ≈ −0.33737388 (depends on the data in the CSV file)
10:31 + 8:30 to time # = 19:01
10h 31min + 8h 30min to time # = 19:01
now to utc # = "2020-07-10T07:50:40Z"
"2020-07-10T07:50CET" to utc+8 # = "2020-07-10T14:50:00+08:00"
"2020-05-20" + 523d # = addDays(2020-05-20; 523) = "2021-10-25"
today - 5 days # = "2020-07-05"
"2020-10-05" - today # = days(today; 2020-10-05) = 87 d
timestamp(2020-05-20) # = 1 589 925 600
stamptodate(1 589 925 600) # = "2020-05-20T00:00:00"
"2020-05-20" to calendars
# returns date in Hebrew, Islamic, Persian, Indian, Chinese, Julian, Coptic, and Ethiopian calendars
52 to bin # = 0011 0100
52 to bin16 # = 0000 0000 0011 0100
52 to oct # = 064
52 to hex # = 0x34
0x34 = hex(34) # = base(34; 16) = 52
523<<2&250 to bin # = 0010 1000
52.345 to float # ≈ 0100 0010 0101 0001 0110 0001 0100 1000
float(01000010010100010110000101001000) # = 1715241/32768 ≈ 52.345001
floatError(52.345) # ≈ 1.2207031e-6
52.34 to sexa # = 52°20′24″
1978 to roman # = MCMLXXVIII
52 to base 32 # = 1K
sqrt(32) to base sqrt(2) # ≈ 100000
0xD8 to unicode # = Ø
code(Ø) to hex # = 0xD8
$ claude mcp add libqalculate \
-- python -m otcore.mcp_server <graph>