The Dirichlet-Rescale (DRS) algorithm is a method for generating vectors of random numbers such that:
- The values of the vector sum to a given total U
- Given a vector of upper bounds, each element of the returned vector is less than or equal to its corresponding upper bound
- Given a vector of lower bounds, each element of the returned vector is greater or equal to than its corresponding lower bound
- The distribution of the vectors in the space defined by the constraints is uniform.
DRS accomplishes this by drawing an initial point from the flat Dirichlet Distribution and performing rescaling operations until the point lies within the accepted region. The way in which the rescaling operations are performed preseves the uniformity of the distribution; the remainder of the algorithm is all about efficiently performing these operations and minimising the effects of the rescale operations (floating point error, running out of the finite amount of entropy encoded in the initial point).
DRS can be thought of as a generalised version of the UUnifast and RandFixedSum algorithms, and can be used as a replacement for both. Note that while RandFixedSum only supports symmetrical bounds (the same for each component of the vector), it may be faster than DRS when generating a large number of vectors with the same symmetric constraints.
The algorithm is described in more detail in the paper "Generating Utilization Vectors for the Systematic Evaluation of Schedulability Tests", published at RTSS 2020. The authors version can be found here: http://eprints.whiterose.ac.uk/167646/ and a narrated presentation here: https://www.youtube.com/watch?v=mwkmXYXc28k
If you wish to cite this work, please use the following references:
@inproceedings{GriffinRTSS2020,
author = {David Griffin and Iain Bate and Robert I. Davis},
title = {Generating Utilization Vectors for the Systematic Evaluation of Schedulability Tests},
booktitle = {{IEEE} Real-Time Systems Symposium, {RTSS} 2020, Houston, Texas, USA},
December 1-4, 2020},
publisher = {{IEEE}},
year = {2020},
url = {http://eprints.whiterose.ac.uk/167646/}
}
@software{david_griffin_2020_4118059,
author = {David Griffin and Iain Bate and Robert I. Davis},
title = {dgdguk/drs},
publisher = {Zenodo},
version = {latest}
doi = {10.5281/zenodo.4118058},
url = {https://doi.org/10.5281/zenodo.4118058}
}
If citing the software itself, please cite the correct version (the DOI of the above reference always resolves to the most recent version; the DOIs of specific versions can be found there).
DRS is licensed under the MIT license.
For general use, there is only one function to consider
def drs(
n: int,
sumu: float,
upper_bounds: Optional[Sequence[Union[int, float]]]=None,
lower_bounds: Optional[Sequence[Union[int, float]]]=None
) -> Sequence[float]: ...
The parameters are as follows
n
: The number of elements to generatesumu
: The target sum for the generated elementsupper_bounds
: An optional sequence of lengthn
which gives the upper bounds on each returned value. If given, thenall(x <= y for x, y in zip(output, upper_bounds))
. If not provided, all upper bounds are set tosumu
.lower_bounds
: An optional sequence of lengthn
which gives the lower bounds on each returned value. If given, thenall(x >= y for x, y in zip(output, lower_bounds))
If not provided, all lower bounds are set to0
.
Invalid inputs are checked for and will result in a ValueError
(e.g. if sumu > sum(upper_bounds)
, or upper_bounds[n] < lower_bounds[n]
).
from drs import drs
result = drs(2, 2)
Will produce vectors of length two such that sum(result) == 2
from drs import drs
result = drs(2, 3, [1.5, 3])
Will produce vectors of length two such that result[0] <= 1.5
, result[1] <= 3
, and sum(result) == 3
.
from drs import drs
result = drs(2, 4, [2, 3], [1, 2])
Will produce vectors of length two such that 1 <= result[0] <= 2
, 2 <= result[1] <= 3
, and sum(result) == 4
.
Due to the amount of entropy in a floating point being finite, and DRS's nature as a rescaling algorithm, it is possible for DRS to exhaust it's source of entropy. This behaviour is controlled by the epsilon parameter, which defaults to 10**-4
. DRS only guarantees that the values returned sum to within sumu*epsilon
of the target, and that only the part of the result greater than sumu*epsilon
is uniformly distributed. If more precision is required, the set_epsilon(epsilon: float)
function can be used to adjust the epsilon parameter.
The maximum size of output vector DRS can produce is theoretically capped at 1015 for versions of Python that use 64-bit floats. In practice it's expected that this will be too computationally expensive for practical use. DRS has been tested to produce output vectors of up to size 200, however above 140 it may be necessary to use the optional mpmath support. Consult drs.py for more information.
This repository also includes build_libdrsc.py
which uses CFFI to produce a shared
library to embded the DRS algorithm into any programming language that supports the C
ABI. This is currently in testing and will be finalised in the next release.