Appendix
Contents
Appendix¶
Directed Acyclic Graph¶
A Directed Acyclic Graph (DAG) is a graph of nodes and edges that is:
directed: edges have a direction and you can only walk the graph in that direction
acyclic: does not contain cycles: A can’t depend on B when B depends on A.
The latter property is of course quite handy for a build system. More information on DAGs can be found on Wikipedia.
Installing Make¶
First, check if you have GNU Make installed already. In a terminal type:
$ make
If you get make: command not found
(or similar), you don’t have Make. If
you get make: *** No targets specified and no makefile found. Stop.
you
do have Make.
We’ll be using GNU Make in this tutorial. Verify that this is what you have by typing:
$ make --version
If you don’t have GNU Make but have the BSD version, some things might not work as expected and we recommend installing GNU Make.
To install GNU Make, please follow these instructions:
Linux: Use your package manager to install Make. For instance on Arch Linux:
$ sudo pacman -S make
Ubuntu:
$ sudo apt-get install build-essential
MacOS: If you have Homebrew installed, it’s simply:
$ brew install make
If you have a builtin Make implementation, please ensure that it’s GNU Make by checking
make --version
.
Advanced: Generating Rules using Call¶
This section continues the tutorial above and demonstrates a feature of Make for automatic generation of rules.
In a data science pipeline, it may be quite common to apply multiple scripts to the same data (for instance when you’re comparing methods or testing different parameters). In that case, it can become tedious to write a separate rule for each script when only the script name changes. To simplify this process, we can let Make expand a so-called canned recipe.
To follow along, switch to the canned
branch:
$ make clean
$ git stash --all # note the '--all' flag so we also stash the Makefile
$ git checkout canned
On this branch you’ll notice that there is a new script in the scripts
directory called generate_qqplot.py
. This script works similarly to the
generate_histogram.py
script (it has the same command line syntax), but it
generates a QQ-plot. The
report.tex file has also been updated to incorporate these plots.
After switching to the canned
branch there will be a Makefile in the
repository that contains a separate rule for generating the QQ-plots. This
Makefile looks like this:
# Makefile for analysis report
#
ALL_CSV = $(wildcard data/*.csv)
DATA = $(filter-out $(wildcard data/input_file_*.csv),$(ALL_CSV))
HISTOGRAMS = $(patsubst data/%.csv,output/figure_%.png,$(DATA))
QQPLOTS = $(patsubst data/%.csv,output/qqplot_%.png,$(DATA))
.PHONY: all clean
all: output/report.pdf
$(HISTOGRAMS): output/histogram_%.png: data/%.csv scripts/generate_histogram.py
python scripts/generate_histogram.py -i $< -o $@
$(QQPLOTS): output/qqplot_%.png: data/%.csv scripts/generate_qqplot.py
python scripts/generate_qqplot.py -i $< -o $@
output/report.pdf: report/report.tex $(FIGURES)
cd report/ && pdflatex report.tex && mv report.pdf ../$@
clean:
rm -f output/report.pdf
rm -f $(HISTOGRAMS) $(QQPLOTS)
You’ll notice that the rules for histograms and QQ-plots are very similar.
As the number of scripts that you want to run on your data grows, this may lead to a large number of rules in the Makefile that are almost exactly the same. We can simplify this by creating a canned recipe that takes both the name of the script and the name of the genre as input:
define run-script-on-data
output/$(1)_$(2).png: data/$(2).csv scripts/generate_$(1).py
python scripts/generate_$(1).py -i $$< -o $$@
endef
Note that in this recipe we use $(1)
for either histogram
or
qqplot
and $(2)
for the genre. These correspond to the expected
function arguments to the run-script-on-data
canned recipe. Also, notice
that we use $$<
and $$@
in the actual recipe, with two $
symbols
for escaping. To actually create all the targets, we need a line that calls
this canned recipe. In our case, we use a double for loop over the genres and
the scripts:
$(foreach genre,$(GENRES),\
$(foreach script,$(SCRIPTS),\
$(eval $(call run-script-on-data,$(script),$(genre))) \
) \
)
In these lines the \
character is used for continuing long lines.
The full Makefile then becomes:
# Makefile for analysis report
#
ALL_CSV = $(wildcard data/*.csv)
DATA = $(filter-out $(wildcard data/input_file_*.csv),$(ALL_CSV))
HISTOGRAMS = $(patsubst %,output/histogram_%.png,$(GENRES))
QQPLOTS = $(patsubst %,output/qqplot_%.png,$(GENRES))
GENRES = $(patsubst data/%.csv,%,$(DATA))
SCRIPTS = histogram qqplot
.PHONY: all clean
all: output/report.pdf
define run-script-on-data
output/$(1)_$(2).png: data/$(2).csv scripts/generate_$(1).py
python scripts/generate_$(1).py -i $$< -o $$@
endef
$(foreach genre,$(GENRES),\
$(foreach script,$(SCRIPTS),\
$(eval $(call run-script-on-data,$(script),$(genre)))\
)\
)
output/report.pdf: report/report.tex $(HISTOGRAMS) $(QQPLOTS)
cd report/ && pdflatex report.tex && mv report.pdf ../$@
clean:
rm -f output/report.pdf
rm -f $(HISTOGRAMS) $(QQPLOTS)
Note that we’ve added a SCRIPTS
variable with the histogram
and
qqplot
names. If we were to add another script that follows the same
pattern as these two, we would only need to add it to the SCRIPTS
variable.
To build all of this, run
$ make -j 4