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sadam.gcd
| External |
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Compute the Greatest Common Divisor of two integers.
sadam.gcd will compute the Greatest Common Divisor of two integers. The GCD of two positive integers is the largest positive integer that divides the numbers without a remainder. If an incoming number is negative, the object will take its absolute value. For the case when an incoming number was 0, GCD returns the absolute value of the other incoming number. |
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sadam.lcm
| External |
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Compute the Least Common Multiple of two integers.
sadam.lcm will compute the Least Common Multiple of two integers. The LCM of two positive integers is the smallest positive integer that is an integer multiple of both numbers. If an incoming number is negative, the object will take its absolute value. If either the first or the second number was 0, the object returns 0. |
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sadam.limits
| External |
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Get minimum and maximum finite values of Max data types.
sadam.limits will output the minimum and maximum finite values of the integer or the floating point Max data type. Note that for floating point numbers the minimum representable finite value is actually the smallest positive number that is not denormal. |
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sadam.lzo
| External |
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Loseless data compression and decompression using the LZO library.
sadam.lzo will compress and decompress loselessly any arbitrary message you send it. The behaviour (compressor/decompressor) is set by the first argument. The compressed result is a single message that may contain any ASCII value (except 0), so caution should be taken, specially if the result is used outside the native Max world (for example if you pass it to MXJ or you plan to store it in a file on the file system). For these cases you might find useful to encode the result with sadam.base64. |
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sadam.normalize~
| External |
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An object that sets the gain of a source to the level of a reference signal.
sadam.normalize~ takes a source and a reference signal, computes their average gain (doing an average over the absolute values or the square root of the sum of the square of the absolute values of the incoming signals) and rescales the source signal to have the same gain as the reference signal. |
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sadam.prime
| External |
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Compute the closest prime numbers to a positive integer.
sadam.prime will compute the closest prime numbers to the absolute value of any integer input. It also reports whether the absolute value of the input is a prime or not. Since the smallest prime number is 2, if the absolute value of the input is smaller than 2, the outlet reporting the closest smaller prime will give false results (it reports the absolute value of the input). The object uses an internal prime table to compute the primes which can be printed to the Max window. |
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sadam.rand~
| External |
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Band-limited random signal.
sadam.rand~ generates a signal consisting of random values between -1 and 1 generated at a frequency specified by its input. It uses a sinewave-section to interpolate between these values. The result is more close to a band-limited pink noise than those generated by rand~. |
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sadam.rapidXML
| External |
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A RapidXML wrapper for Max.
sadam.rapidXML will create, read, store or even modify DOM trees. The DOM is one of the possible representations of the contents of an XML document (see http://www.w3.org/TR/DOM-Level-2-Core/.) The object internally uses the RapidXML 1.13 library (see http://rapidxml.sourceforge.net/,) which is one of the fastest, yet still almost completely W3C compliant, freely available XML parsers.
When an XML is parsed, the object will assign a unique ID to each Element of the document, called the Element Index. This index won't get stored and changes each time when the order of Elements in the XML is modified (either by inserting or removing Elements). However, using the Element Index is the preferred (and in most cases, the only) way to address a given element in the XML. The Element Index is sent out the rightmost outlet each time an element is accessed. The Element Index of the Document Element is always 0, the rest of the Elements get their index in their 'order of appearence'. This means that even if an Element is being inserted or removed, the Index of the Elements that come earlier in the Document won't change.
When querying Attributes, Text, or CDATA nodes, the requested data will be sent out the appropriate outlets in right-to-left order (in case of Attributes, if more than one Attribute is requested, they will be sent to the output as a sequence like AttributeName1-AttributeValue1-AttributeName2-AttributeValue2-...-AttributeNameN-AttributeValueN, alternating on the appropriate outlets) followed by an error code. When querying Elements, the result will be sent out as a sequence (from right to left) consisting of the Element Index, the Tree Depth of the Element (the Document Element is at level 0, its children are at level 1 etc.), the Element's Tag Name, the Attributes, and finally the Text Content (which is a concatenation of all Text and CDATA nodes).
The leftmost outlet serves as an error outlet. After each command sent to the object, an error code is being sent back through this outlet at the end of the execution of the given command. A negative value means that the command could not be executed successfully, while 0 means success. In some cases (typically when one or more Elements are queried) the error outlet reports the number of Elements successfully returned.
As already mentioned, RapidXML 1.13 (and therefore sadam.rapidXML) is not fully W3C compliant. The main reason is that the parser ignores DOCTYPE declarations. There are also some difficulties with namespace management as well, the parser wouldn't refuse XMLs containing more than one root element and it will allow duplicate attributes for the same element. Also, to make parsing faster, all kind of XML validation is turned off by the wrapper Max object. If you need a 100% W3C compliant XML parser, consider sadam.dom, which is almost identical in functionality to sadam.rapidXML and requires MXJ to run. |
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sadam.stat
| External |
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Get mean and standard deviation of a number sequence.
sadam.stat will compute the mean and the standard deviation of a sequence of numbers. With no arguments it will compute these values using all the numbers it received (like the mean object) while by declaring a fixed buffer size N it will do the calculations only on the last N entries. |
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sah~
| External |
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Sample-and-hold
Sample-and-hold. The sah~ object accepts two signals. The left signal is the "input" and the right signal is the "control." When the control makes a transition from being at or below a the trigger value to being above the trigger value, the input is sampled and its current value is output until another control transition occurs and the input is sampled again. The default threshold value is 0, but can be specified via a float in the left inlet or as an argument to sah~. |
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Same
| Abstraction |
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counts out repetition of a specified value |
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sampv1~
| Abstraction |
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simple sampler voice element
This is a simple sampler voice element using the MSP play~ object. The interest of sampv1~ is that all of the commands are on a higher level: velocity (scaled to MIDI values), transposition (in cents) onset, rise and decay times (in milliseconds), and sample name/number. |
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sc.lfclipnoise~
| External |
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Clipped Noise.
Randomly generates the values -1 or +1 at a rate given by the nearest integer division |
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sc.lfnoise0~
| External |
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Generates random values at a rate |
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sc.lfnoise1~
| External |
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Generates linearly interpolated random values at a rate |
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| Libraries | |
BulkStore
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='62'Tom Mays |
bulk storage memory device for all values (any message) |
FuzzyLib
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='139'Alain Bonardi
Isis Truck |
When manipulating human knowledge such as perception, feelings, appreciation, veracity of facts, etc., the classical logic that recognize only two truth degrees (true or false) is not always the most suitable.
To solve this problem, more than two degrees are considered in the non-classical logics. The fuzzy logic is one of these logics.
In this logic, facts are represented through membership functions: when the membership value is equal to 1 the fact is exactly true; when it is equal to 0 the fact is exactly false; in between there is an uncertainty about the veracity of the fact.
These membership functions are called "fuzzy subsets". They can be of different shapes: gaussian, trapezoidal, triangular, etc.
Thus the aim of the fuzzy logic is to propose a theoretical framework for the manipulation - representation and reasoning - of such facts.
The Fuzzy Lib library implements all the tools that are necessary to handle this manipulation: representation of a fuzzy subset (among them are the fuzzification, defuzzification and partitioning), reasoning process (generalized modus ponens, fuzzy implications, t-norms, t-conorms, etc.).
This version 1 of the Fuzzy Lib enables to implement fuzzification, uncertain reasoning and defuzzification for any number of data in the framework of Max/MSP environment. |
Litter Power Pro Package
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='54'Peter Castine |
The Litter Power package consists of over 60 external objects, including a number of new MSP noise sources, externals that produce values from a wide variety of random number distributions, and externals for mutation and cross-synthesis. |
p.jit.gl.tools
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='123' Pelado |
the p.jit.gl tools are designed to provide for easier learning of and experimenting with the many attributes that are available to jitter's gl objects by making them a whole lot more transparent and accessible. patches expose jitter gl object's attributes to interfaces that allow you to immediately edit and change an attribute's value. many of the parameters are attached to blines, which provide smooth changes while rendering, and all settings can be saved and recalled as presets using the pattrs that are embedded in the patches. |
Panaiotis Objects
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='122' Panaiotis |
The Mac version is UB.
These Max objects have been enhanced since the documentation to the left was written. Help files for the objects provide information on enhancements.
The matrix object has been substantially upgraded. It now combines features of unpack, spray, funnel, append, and prepend into one object. This makes a great object to place between controllers and jit objects because it acts like a multi-prepend. There are new configuration commands and enhancements to the old: even, odd, mod,and range, among others). Most commands can be applied to inlets of outlets. There is also a mute function that adds another layer of control. Matrixctrl support has been enhanced. See the help file for full details and examples.
Most other objects now fully support floats. RCer and autocount will count in float values, not just integers.
Notegen16 is a 16 channel version of its predecessor: notegen. It is more generalized and much more efficient. |
SFA Max/MSP Library
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='172'Stefano Fasciani |
The SFA-MaxLib is a collection of Max/MSP objects developed in the context of the VCI4DMI. It includes functions and utilities in the form of FTM externals, FTM abstractions and Max abstractions. FTM is a shared library for Max/MSP developed by IRCAM, which provides a small and simple real-time object system and a set of optimized services to be used within Max/MSP externals.
List of FTM Externals: sfa.eig - eigenvalues; sfa.inputcombinations - combination generator; sfa.levinson - levinson-durbin recursion; sfa.lpc2cep - lpc to cepstra conversion; sfa.rastafilt - rasta filter; sfa.rmd - relative mean difference; sfa.roots - polynomial roots;
List of Abstractions: sfa.bark.maxpat - energy of the Bark bands from time domain frame;sfa.bark2hz_vect.maxpat - Herts to Bark conversion;sfa.barkspect.maxpat - energy of the Bark bands from spectrum; sfa.ceil.maxpat - ceil function; sfa.featfluxgate.maxpat - gated distance on stream of feature vectors; sfa.fft2barkmx.maxpat - utility sub-abstraction of sfa.bark; sfa.fft2barkmxN.maxpat - utility sub-abstraction of sfa.barkspect; sfa.hynek_eq_coeff.maxpat - hynek equalization coefficients; sfa.hz2bark.maxpat - Hertz to Bark conversion; sfa.hz2bark_vect.maxpat - Hertz to Bark conversion for vectors; sfa.hz2mel.maxpat - Hertz to Mel conversion; sfa.idft_real_coeff.maxpat - utility sub-abstraction of sfa.rasta-plp; sfa.maxminmem.maxpat - minimum and maximum of a stream of data; sfa.mfcc.maxpat - MFCC coefficients; sfa.modalphafilter.maxpat - 1st order IIR lowpass on a stream of vectors; sfa.nonlinfeqscale.maxpat - linear spectrum to Bark or Mel scale conversion; sfa.rasta-plp.maxpat - PLP and RASTA-PLP coefficients; sfa.spectmoments.maxpat - 4 spectral moments (centroid, deviation, skewness, kurtosis); sfa.3spectmoments+flatness.maxpat - 3 spectral moments (centroid, deviation, skewness) and the spectral flatness; sfa.spectralflux.maxpat - spectral flux on stream of spectrum vectors; sfa.spectralfluxgate.maxpat - gated spectral flux on stream of spectrum vectors; sfa.std.maxpat - standard deviation; sfa.win_to_fft_size.maxpat - smaller FFT size given frame size; sfa.GCemulator.maxpat – 3D gestural controller emulator; |
suivi
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='88' Ircam |
Two externals performing score following on soloist performances using Hidden Markov Models (HMM)
Suivi is based on FTM and requires the shared library FTMlib for Max/MSP. Both externals use an FTM track object - a sequence of time-tagged FTM values - to store the score of the soloist performance to be followed. Notes, trills and other elements of the score are represented by FTM score objects (FTM scoob class). For the moment, scores can be imported from standard MIDI files only.
An editor for the FTM track class, which will also provide a graphical control interface for the score follower is under development as well as the import of MusicXML files.
The suivi object set is distributed within the IRCAM Forum. |
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