Programmer Guide/Command Reference/NUM: Difference between revisions
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|0<BR>warning code | |0<BR>warning code | ||
|} | |} | ||
:;numbers: | The ''expression'' will be evaluated numerically, and the result (textual representation) will be returned. The ''expression'' may consist of the following parts: | ||
;decimal numbers: <code>123.456</code>, <code>17.5e3</code>, <code>100</code>, <code>-312.123</code>, <code>1e-3</code>,… | |||
;hexa-decimal numbers:<code>0x1234</code>, <code>0xabc</code>, <code>0XabC</code>, … | |||
;special constants:<code>pi</code> (=3.1415...), <code>e</code> (=2.71828...), | |||
:<code>rand</code> (a linear distributed pseudo random number ''r''; -1≤''r''<1) | |||
:<code>lran</code> (a linear distributed pseudo random number ''r''; 0≤''r''<1) | |||
;numerical operators: <code>-''a''</code> (negate), <code>''a''+''b''</code> (add), <code>''a''-''b''</code> (subtract), <code>''a''*''b''</code> (multiply), <code>''a''/''b''</code> (divide), <code>''a''%''b''</code> (modulo), <code>''a''^''b''</code> (power) | |||
;logical operators (bitwise): <code>!''a</code> (not), <code>''a''&''b''</code> (and), <code>''a''|''b''</code> (or), <code>''a''^''b''</code> (exclusive or) | |||
;brackets:<code>(''expression'')</code> | |||
;functions: | |||
:{|class="einrahmen" | :{|class="einrahmen" | ||
| | |<code>setlran(''seed'')</code> | ||
|linear distributed pseudo random number ''r'' (0≤''r''<1)<BR>''seed'' is the start value (0≤''seed''<<1) | |||
|- | |||
|<code>sin(''x'')</code>, <code>cos(''x'')</code>, <code>tan(''x'')</code> | |||
|sine, cosine or tangent of ''x'' | |||
|- | |||
|<code>asin(''x'')</code>, <code>acos(''x'')</code>, <code>atan(''x'')</code> | |||
|inverse sine, cosine or tangent of ''x'' | |||
|- | |- | ||
| | |<code>exp(''x'')</code> | ||
|computes <code>e<sup>''x''</sup></code> | |||
|- | |- | ||
| | |<code>log(''x'')</code> | ||
|common logarithm of ''x'' (base <code>10</code>) | |||
|- | |||
|<code>ln(''x'')</code> | |||
|natural logarithm of ''x'' (base <code>e</code>) | |||
|- | |||
|<code>sqrt(''x'')</code> | |||
|square root of ''x'' (base 10) | |||
|- | |||
|<code>abs(''x'')</code> | |||
|absolute value of ''x'' (base 10) | |||
|- | |||
|<code>int(''x'')</code> | |||
|integer part of ''x'', the fractional part is truncated<BR>(range of ''x'': 32bit signed integer) | |||
|- | |||
|<code>round(''x'')</code> | |||
|round to the nearest integer of ''x''<BR>(range of ''x'': 32bit signed integer) | |||
|- | |||
|<code>db(''x'')</code> | |||
|convert level to factor (<code>10<sup>''x''/20</sup></code>) | |||
|- | |||
|<code>sinc(''x'')</code>, <code>sinx(''x'')</code> | |||
|sinc function: <code>sin(''x'') / ''x''</code> | |||
|- | |||
|<code>sign(''x'')</code> | |||
|sign of ''x''; returns -1 if <code>''x''<0</code>, otherwise 1 | |||
|- | |||
|<code>hz2bark(''x'')</code> | |||
|convert ''x'' from Hertz to Bark | |||
|- | |||
|<code>bark2hz(''x'')</code> | |||
|convert ''x'' from Bark to Hertz | |||
|- | |||
|<code>bit(''n'')</code> | |||
|returns the integer with only bit ''n'' (0≤''n''<32) is set and all other are cleared; can be used to generate bit masks | |||
|- | |||
|<code>floor(''x'')</code> | |||
|returns a floating-point value representing the largest integer that is less than or equal to ''x''<BR>(range of ''x'': 64bit float) | |||
|- | |||
|<code>iserr(''rc'')</code>, <code>iserror(''rc'')</code> | |||
|returns 1 if ''rc'' is a {{STX}} error code, otherwise 0<BR>this function can be used to test the completion code <code>RC</code> of a command | |||
|- | |||
|<code>iswarn(''rc'')</code>, <code>iswarning(''rc'')</code> | |||
|returns 1 if ''rc'' is a {{STX}} warning code, otherwise 0<BR>this function can be used to test the completion code <code>RC</code> of a command | |||
|- | |||
|<code>npow2(''n'')</code> | |||
|next power of 2; returns the smallest possible value <code>2<sup>m</sup> ≥ ''n''</code> | |||
|} | |} | ||
;Notes: | ;Notes: | ||
*In case of the expression being syntactically ill-formed, an error (<code>NUM</code>) or warning (<code>NUMCHECK</code>) is reported. | |||
*The special numerical objects (vectors, matrices) available in [[../EVAL|EVAL]]-expressions, can not be used in the <code>NUM</code> expressions. Only the use of numerical constants and variables is possible. | |||
*The same expression syntax is used for the [[../INT|INT and INTCHECK]], for the numerical expressions in [[Programmer_Guide/Introduction#Conditional_Expressions|conditions]] (e.g. [[../IF|IF]] or [[../WHILE|WHILE]]) and for the evaluation of numerical arguments of commands. | |||
*Numerical expressions are evaluated in 64bit floating point precission. | |||
*For logical (operators <code>!, &, |, ^</code>) and integer expressions (functions <code>round, int, bit</code>) 32bit signed integers are used. | |||
;See also: [[../INT|INT, INTCHECK]], [[../EVAL|EVAL, EVALCHECK]], [[../SEGMENT|SEGMENT]] | |||
;Examples: | ;Examples: | ||
# | // #wave = wave item | ||
# | #t := num $#wave[!length] / $#wave[!srate] // duration in seconds | ||
# | // #t = frame length in seconds, #o = overlap in percent | ||
#lfrm := int $#t * $#wave[!srate] // frame length in samples | |||
#lhop := int $#t * (1 - $#o / 100) * $#wave[!srate] // hopsize in samples | |||
// | #lfft := int npow2($#lfrm) // fft length | ||
# | #df := num $#wave[!srate] / $#lfft // frequency resolution | ||
// using expressions in a IF statement | |||
if 'db($#level)' > 1 then | |||
conlog 'level must be lower or equal 0dB' | |||
#level := 0 | |||
end | |||
Latest revision as of 17:51, 25 April 2014
| command | return value | value of RC |
|---|---|---|
NUM expression
|
value of expression or empty string if the evaluation fails |
0 error code |
NUMCHECK expression
|
value of expression or empty string if the evaluation fails |
0 warning code |
The expression will be evaluated numerically, and the result (textual representation) will be returned. The expression may consist of the following parts:
- decimal numbers
123.456,17.5e3,100,-312.123,1e-3,…- hexa-decimal numbers
0x1234,0xabc,0XabC, …- special constants
pi(=3.1415...),e(=2.71828...),rand(a linear distributed pseudo random number r; -1≤r<1)lran(a linear distributed pseudo random number r; 0≤r<1)- numerical operators
-a(negate),a+b(add),a-b(subtract),a*b(multiply),a/b(divide),a%b(modulo),a^b(power)- logical operators (bitwise)
!a(not),a&b(and),a|b(or),a^b(exclusive or)- brackets
(expression)- functions
setlran(seed)linear distributed pseudo random number r (0≤r<1)
seed is the start value (0≤seed<<1)sin(x),cos(x),tan(x)sine, cosine or tangent of x asin(x),acos(x),atan(x)inverse sine, cosine or tangent of x exp(x)computes exlog(x)common logarithm of x (base 10)ln(x)natural logarithm of x (base e)sqrt(x)square root of x (base 10) abs(x)absolute value of x (base 10) int(x)integer part of x, the fractional part is truncated
(range of x: 32bit signed integer)round(x)round to the nearest integer of x
(range of x: 32bit signed integer)db(x)convert level to factor ( 10x/20)sinc(x),sinx(x)sinc function: sin(x) / xsign(x)sign of x; returns -1 if x<0, otherwise 1hz2bark(x)convert x from Hertz to Bark bark2hz(x)convert x from Bark to Hertz bit(n)returns the integer with only bit n (0≤n<32) is set and all other are cleared; can be used to generate bit masks floor(x)returns a floating-point value representing the largest integer that is less than or equal to x
(range of x: 64bit float)iserr(rc),iserror(rc)returns 1 if rc is a STx error code, otherwise 0
this function can be used to test the completion codeRCof a commandiswarn(rc),iswarning(rc)returns 1 if rc is a STx warning code, otherwise 0
this function can be used to test the completion codeRCof a commandnpow2(n)next power of 2; returns the smallest possible value 2m ≥ n
- Notes
- In case of the expression being syntactically ill-formed, an error (
NUM) or warning (NUMCHECK) is reported. - The special numerical objects (vectors, matrices) available in EVAL-expressions, can not be used in the
NUMexpressions. Only the use of numerical constants and variables is possible. - The same expression syntax is used for the INT and INTCHECK, for the numerical expressions in conditions (e.g. IF or WHILE) and for the evaluation of numerical arguments of commands.
- Numerical expressions are evaluated in 64bit floating point precission.
- For logical (operators
!, &, |, ^) and integer expressions (functionsround, int, bit) 32bit signed integers are used.
- See also
- INT, INTCHECK, EVAL, EVALCHECK, SEGMENT
- Examples
// #wave = wave item #t := num $#wave[!length] / $#wave[!srate] // duration in seconds // #t = frame length in seconds, #o = overlap in percent #lfrm := int $#t * $#wave[!srate] // frame length in samples #lhop := int $#t * (1 - $#o / 100) * $#wave[!srate] // hopsize in samples #lfft := int npow2($#lfrm) // fft length #df := num $#wave[!srate] / $#lfft // frequency resolution
// using expressions in a IF statement
if 'db($#level)' > 1 then
conlog 'level must be lower or equal 0dB'
#level := 0
end
