List of Open Source Software which can be built on Fugaku

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 Spack will be used to manage open source software packages on Fugaku. Fugaku users can easily use pre-installed packages and built packages based on Spack recipes. The following list shows the results of building/compiling packages for aarch64 according to the Spack recipes. Note that the results in this list do not guarantee that each package will work properly. On the other hand, Fujitsu will provide the following packages compiled with Fujitsu compiler on Fugaku as "external" packages, of which Spack can be aware.
  • OpenJDK 11
  • Ruby 2.6.5 or later
  • Python2 2.7.15
  • Python3 3.6.8
  • Numpy 1.14.3
  • SciPy 1.0.0
  • Eclipse IDE 2019-09 R Packages
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r-spatstat-core

Package

r-spatstat-core

Description

Core Functionality of the 'spatstat' Family. Functionality for data
analysis and modelling of spatial data, mainly spatial point patterns,
in the 'spatstat' family of packages. (Excludes analysis of spatial data
on a linear network, which is covered by the separate package
'spatstat.linnet'.) Exploratory methods include quadrat counts,
K-functions and their simulation envelopes, nearest neighbour distance
and empty space statistics, Fry plots, pair correlation function, kernel
smoothed intensity, relative risk estimation with cross-validated
bandwidth selection, mark correlation functions, segregation indices,
mark dependence diagnostics, and kernel estimates of covariate effects.
Formal hypothesis tests of random pattern (chi-squared, Kolmogorov-
Smirnov, Monte Carlo, Diggle-Cressie-Loosmore-Ford, Dao-Genton, two-
stage Monte Carlo) and tests for covariate effects (Cox-Berman-Waller-
Lawson, Kolmogorov-Smirnov, ANOVA) are also supported. Parametric models
can be fitted to point pattern data using the functions ppm(), kppm(),
slrm(), dppm() similar to glm(). Types of models include Poisson, Gibbs
and Cox point processes, Neyman-Scott cluster processes, and
determinantal point processes. Models may involve dependence on
covariates, inter-point interaction, cluster formation and dependence on
marks. Models are fitted by maximum likelihood, logistic regression,
minimum contrast, and composite likelihood methods. A model can be
fitted to a list of point patterns (replicated point pattern data) using
the function mppm(). The model can include random effects and fixed
effects depending on the experimental design, in addition to all the
features listed above. Fitted point process models can be simulated,
automatically. Formal hypothesis tests of a fitted model are supported
(likelihood ratio test, analysis of deviance, Monte Carlo tests) along
with basic tools for model selection (stepwise(), AIC()) and variable
selection (sdr). Tools for validating the fitted model include
simulation envelopes, residuals, residual plots and Q-Q plots, leverage
and influence diagnostics, partial residuals, and added variable plots.

Note

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