9.3. 數學函式及運算子
本節提供了 PostgreSQL 的數學運算方式。對於沒有標準數學約定的型別(例如,日期/時間型別),我們將在後續部分中介紹具體的行為。
Table 9.4 列出了可用的數學運算子。
Table 9.4. Mathematical Operators
+
addition
2 + 3
5
-
subtraction
2 - 3
-1
*
multiplication
2 * 3
6
/
division (integer division truncates the result)
4 / 2
2
%
modulo (remainder)
5 % 4
1
^
exponentiation (associates left to right)
2.0 ^ 3.0
8
|/
square root
|/ 25.0
5
||/
cube root
||/ 27.0
3
!
factorial
5 !
120
!!
factorial (prefix operator)
!! 5
120
@
absolute value
@ -5.0
5
&
bitwise AND
91 & 15
11
|
bitwise OR
32 | 3
35
#
bitwise XOR
17 # 5
20
~
bitwise NOT
~1
-2
<<
bitwise shift left
1 << 4
16
>>
bitwise shift right
8 >> 2
2
位元運算子僅適用於整數資料型別,也可用於位元字串型別的位元和位元變化,如 Table 9.14 所示。
Table 9.5 列出了可用的數學函數。在該表中,dp 表示雙精確度。這些函數中的許多函數都提供了多種形式,且具有不同的參數型別。除非另有說明,否則函數的任何形式都將回傳與其參數相同的資料型別。使用雙精確度資料的功能主要以主機系統的 C 函式庫實作; 因此,邊界情況下的準確性和行為可能會因主機系統而有所差異。
Table 9.5. Mathematical Functions
abs(
x
)
(same as input)
absolute value
abs(-17.4)
17.4
cbrt(dp
)
dp
cube root
cbrt(27.0)
3
ceil(dp
or numeric
)
(same as input)
nearest integer greater than or equal to argument
ceil(-42.8)
-42
ceiling(dp
or numeric
)
(same as input)
nearest integer greater than or equal to argument (same as ceil
)
ceiling(-95.3)
-95
degrees(dp
)
dp
radians to degrees
degrees(0.5)
28.6478897565412
div(
y
numeric
, x
numeric
)
numeric
integer quotient of y
/x
div(9,4)
2
exp(dp
or numeric
)
(same as input)
exponential
exp(1.0)
2.71828182845905
floor(dp
or numeric
)
(same as input)
nearest integer less than or equal to argument
floor(-42.8)
-43
ln(dp
or numeric
)
(same as input)
natural logarithm
ln(2.0)
0.693147180559945
log(dp
or numeric
)
(same as input)
base 10 logarithm
log(100.0)
2
log10(dp
or numeric
)
(same as input)
base 10 logarithm
log10(100.0)
2
log(
b
numeric
, x
numeric
)
numeric
logarithm to base b
log(2.0, 64.0)
6.0000000000
mod(
y
, x
)
(same as argument types)
remainder of y
/x
mod(9,4)
1
pi()
dp
“π” constant
pi()
3.14159265358979
power(
a
dp
, b
dp
)
dp
a
raised to the power of b
power(9.0, 3.0)
729
power(
a
numeric
, b
numeric
)
numeric
a
raised to the power of b
power(9.0, 3.0)
729
radians(dp
)
dp
degrees to radians
radians(45.0)
0.785398163397448
round(dp
or numeric
)
(same as input)
round to nearest integer
round(42.4)
42
round(
v
numeric
, s
int
)
numeric
round to s
decimal places
round(42.4382, 2)
42.44
scale(numeric
)
integer
scale of the argument (the number of decimal digits in the fractional part)
scale(8.41)
2
sign(dp
or numeric
)
(same as input)
sign of the argument (-1, 0, +1)
sign(-8.4)
-1
sqrt(dp
or numeric
)
(same as input)
square root
sqrt(2.0)
1.4142135623731
trunc(dp
or numeric
)
(same as input)
truncate toward zero
trunc(42.8)
42
trunc(
v
numeric
, s
int
)
numeric
truncate to s
decimal places
trunc(42.4382, 2)
42.43
width_bucket(
operand
dp
, b1
dp
, b2
dp
, count
int
)
int
return the bucket number to which operand
would be assigned in a histogram having count
equal-width buckets spanning the range b1
to b2
; returns 0
or count
+1 for an input outside the range
width_bucket(5.35, 0.024, 10.06, 5)
3
width_bucket(
operand
numeric
, b1
numeric
, b2
numeric
, count
int
)
int
return the bucket number to which operand
would be assigned in a histogram having count
equal-width buckets spanning the range b1
to b2
; returns 0
or count
+1 for an input outside the range
width_bucket(5.35, 0.024, 10.06, 5)
3
width_bucket(
operand
anyelement
, thresholds
anyarray
)
int
return the bucket number to which operand
would be assigned given an array listing the lower bounds of the buckets; returns 0
for an input less than the first lower bound; the thresholds
array must be sorted, smallest first, or unexpected results will be obtained
width_bucket(now(), array['yesterday', 'today', 'tomorrow']::timestamptz[])
2
Table 9.6 shows functions for generating random numbers.
Table 9.6. Random Functions
random()
dp
random value in the range 0.0 <= x < 1.0
setseed(dp
)
void
set seed for subsequent random()
calls (value between -1.0 and 1.0, inclusive)
The random()
function uses a simple linear congruential algorithm. It is fast but not suitable for cryptographic applications; see the pgcrypto module for a more secure alternative. If setseed()
is called, the results of subsequent random()
calls in the current session are repeatable by re-issuing setseed()
with the same argument.
Table 9.7 shows the available trigonometric functions. All these functions take arguments and return values of type double precision
. Each of the trigonometric functions comes in two variants, one that measures angles in radians and one that measures angles in degrees.
Table 9.7. Trigonometric Functions
acos(
x
)
acosd(
x
)
inverse cosine
asin(
x
)
asind(
x
)
inverse sine
atan(
x
)
atand(
x
)
inverse tangent
atan2(
y
, x
)
atan2d(
y
, x
)
inverse tangent of y
/x
cos(
x
)
cosd(
x
)
cosine
cot(
x
)
cotd(
x
)
cotangent
sin(
x
)
sind(
x
)
sine
tan(
x
)
tand(
x
)
tangent
Note
Another way to work with angles measured in degrees is to use the unit transformation functions radians()
and degrees()
shown earlier. However, using the degree-based trigonometric functions is preferred, as that way avoids round-off error for special cases such as sind(30)
.
Table 9.8 shows the available hyperbolic functions. All these functions take arguments and return values of type double precision
.
Table 9.8. Hyperbolic Functions
sinh(
x
)
hyperbolic sine
sinh(0)
0
cosh(
x
)
hyperbolic cosine
cosh(0)
1
tanh(
x
)
hyperbolic tangent
tanh(0)
0
asinh(
x
)
inverse hyperbolic sine
asinh(0)
0
acosh(
x
)
inverse hyperbolic cosine
acosh(1)
0
atanh(
x
)
inverse hyperbolic tangent
atanh(0)
0
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