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This vignette describes the process of updating and extending
auk
. Three topics are covered: updating auk
when a new eBird taxonomy is released, extending auk
to
include new filters, and CRAN submission.
The species, and other taxa, available for entry into the eBird
database is dependent on the eBird
taxonomy. Every August, the eBird team updates this taxonomy to
reflect name changes splits, merges, new species, or any other changes.
Historical eBird records are then updated accordingly and subsequent EBD
files reflect this updated taxonomy. The auk
package stores
a copy of this taxonomy as the data frame ebird_taxonomy
,
and uses it both for filtering by species (auk_species()
)
and for taxonomic roll-up (auk_rollup()
). Therefore,
auk
must be updated when a new eBird taxonomy is released.
This section described how this is done. It is best to do this after the
new taxonomy and the new EBD have both been released,
otherwise the taxonomy and EBD will be out of sync.
When the eBird taxonomy is updated, the new version can be downloaded
from the eBird
website. The taxonomy can be downloaded in csv or Excel format,
be sure to download the Excel file because the csv file
has character encoding issues. Copy this file to data-raw/
.
At this point, you should check that this new taxonomy has the same
format as the previous file, which will also be in this directory.
Ensure that the same columns are present and that they’re named the
same.
The file data-raw/ebird-taxonomy.r
prepares the taxonomy
as a data frame to be stored in the package. Open this file and edit the
read_xlsx()
call to point to the new file you just
downloaded. Run the code, then open the ebird_taxonomy
data
frame to inspect it and make sure there’s no glaring issues. One
potential error that should be investigated is non-ASCII characters.
Some common names have accented characters (e.g. Rüppell’s Griffon, Gyps
rueppelli), which can cause problems. ebird-taxonomy.r
converts these characters to their unaccented equivalents
(e.g. Ruppell’s Griffon). Check that this record, or others with
accented characters, has been properly converted.
Next, update auk_version_date()
(R/auk-version-date.r
) to reflect the date of the new
taxonomy and the new EBD.
Finally, build the package (devtools::build()
) and run
R CMD check
(devtools::check()
). If everything
looks good, commit to git and push to GitHub.
The primary functionality of auk
is to apply filters to
the EBD to extract a subset of records that can be imported into R and
further analyzed. Individual filters are defined by a particular
function (e.g. auk_date()
or auk_country()
)
and correspond to subsetting on a particular column (e.g. “OBSERVATION
DATE” and “COUNTRY CODE”, respectively). Defining a new filter is a
fairly complicated process, involving carefully updating many components
of the package, and should only be attempted by experienced R
programmers. To add a filter called color
, the following
steps are required:
auk_ebd()
(in file R/auk-ebd.r
) to
define the column number for the new filter, create a placeholder in the
auk_ebd
object to store the filtering criteria, and update
the auk_ebd
print method for the new filter.auk_color()
(in file
R/auk-color.r
) that defines the new filter. As a starting
point, use one of the other filtering functions. For example to filter
on a range of numeric values, start with auk_duration()
, to
filter on a logical (true/false) variable use
auk_complete()
, or to filter on a discrete, categorical
variable use auk_country()
. Be sure to apply extensive
checking on the validity of inputs and update the documentation,
including examples.auk_filter()
(in file
R/auk-filter.r
) to incorporate the filtering criteria into
the AWK script. Again, use an existing filter as a template.test_that()
block in
tests/testthat/test_filters.r
. Again, use an existing
filter as a template.README.md
and vignettes/auk.Rmd
to
add the new filter to the list of potential filters.auk_ebd()
Near the top of the code for auk_ebd()
, a data frame
named filter_cols
is defined which specifies which columns
have associated filters. Add a new row to this data frame and set
name
as the name of the column in the file header that will
be filtered on and id
as the name of the filter. For
example, if you’re creating a filter called auk_color()
that filters on the column “FEATHER COLOR”, then set
id = "color"
and name = "feather color"
.
Ideally, similar filters should be grouped together in this data frame,
so insert the new row accordingly.
For filters that don’t apply to the sampling event data file,
i.e. filters at the species level rather than the checklist level, add
the id to the character vector not_in_sampling
. For
example, modify the code to read:
not_in_sampling <- c("species", "breeding", "color")
.
Next, at the end of the code for auk_ebd()
, the
auk_ebd
object is created and returned with the statement
beginning with structure(...
. This object should have
placeholders for every filter. So, add a new element to the list, naming
the variable after the id
in the above data frame, putting
it in the same order as in the above data frame, and choosing a sensible
data type. For example, if color
is a categorical variable,
add a new list element color = character()
, and if it’s a
numeric variable, add color = numeric()
.
Finally, within auk-ebd.r
a print.auk_ebd()
method is defined, which you’ll need to update to print the filter in a
sensible way. Here you’re best to find another filter with a similar
format and use that as a template. Again, be sure to put the print code
for the filter in the right order. For example, for a categorical filter
allow multiple potential values, you may way something like:
Create a new function that will allow users to define a filter. Be
sure to following the naming conventions used, for our color example,
the function should be named auk_color()
and it should be
in a file called auk-color.r
. It’s easiest to use an
existing function as a template here. In general, the function should
take two argument, the auk_ebd
object to modify, and an
argument with the filter criteria,
e.g. auk_color(x, color)
. Note how the name of the function
matches the name of the second argument. The function should be edited
to include the following:
auk_filter()
. At the very least, check
data types and, where possible, check that values are valid
(e.g. color
should be in
c("red", "green", "blue", ...)
). Provide informative error
or warning messages where appropriate.auk_ebd
object. This
is generally as simple as x$filters$color = color
.%>%
).auk_filter()
The actual work of filtering is done by auk_filter()
,
which generates an AWK script, then calls AWK. This function must be
updated to parse the filters defined using the function you created in
step 2 into AWK code. In the code for auk_filter()
, there
are two calls to the internal function awk_translate()
,
which is an internal function defined in the same file. It’s
awk_translate()
that you’ll need to edit. This function has
a series of code blocks each of which prepares the AWK code for a
different filter. Find an existing filter that is similar to the new one
you’re creating and copy it over to the correct spot (remember to
preserve the ordering of the filters). For the auk_color()
example, the code chunk would look like:
# color filter
if (length(filters$color) == 0) {
filter_strings$color <- ""
} else {
idx <- col_idx$index[col_idx$id == "color"]
condition <- paste0("$", idx, " == \"", filters$color, "\"",
collapse = " || ")
filter_strings$color <- str_interp(awk_if, list(condition = condition))
}
When given a sampling event data file in addition to a EBD file,
auk_filter()
will filter both files. By default
auk_filter()
will apply all filters to both files, however,
some filters (e.g. species) are only appropriate for the EBD. To address
this, prior to calling auk_translate()
for the sampling
data, reset the species-specific filters. In the case of color, which is
a species specific variable, modify the code as follows:
s_filters <- x$filters
s_filters$species <- character()
## ADD THIS LINE
s_filters$color <- character()
##
awk_script_sampling <- awk_translate(filters = s_filters,
col_idx = x$col_idx_sampling,
sep = sep,
select = select_cols)
Finally, at the end of the auk-filter.r
file, there’s a
string named awk_filter
, which defines the template for the
AWK script. Each filter has a line in this string
(e.g. ${species}
) where the AWK code will be inserted.
You’ll need to add a line in this file for your new filter:
${color}
.
Now that you’ve successfully created the filter, play around with it
a bit to make sure it works as expected. Once you feel the filter is
working, it’s time to formalize this testing process by defining unit
tests. Open the file tests/testthat/test_filters.r
and
you’ll notice a series of calls like
test_that("auk_species", ...
, each of which contains tests
for a specific filter.
Using an existing test block as an example, define a new block (again, put it in the correct order relative to the other filters). Consult the Testing chapter of Hadley Wickham’s R packages book for details on defining good unit tests. At the very least, define tests to make sure that typical use works as expected, that errors are caught when input is invalid, and that edge cases are correctly handled.
Both the vignette (vignettes/auk.Rmd
) and README
(README.Rmd
) have sections giving a short description of
each filter. Add the new filter you’ve created here.
Carry out the following final steps:
devtools::document()
to generate package
documentationdevtools::build()
to build and install the
packagedevtools::check()
to run the units tests and
variety of other checks via R CMD check
devtools::build_vignettes()
pkgdown::build_site()
Minor updates to auk
can be pushed to GitHub giving
users the option of installing the development version from there.
However, at least once a year, when a new eBird taxonomy is released, a
new version of auk
should be released on CRAN. For full
details on this process, consult Hadley Wickham’s R Packages book, however,
I’ll provide a quick guide here. Once The package has been updated
following the instructions from the above sections:
devtools::check()
to run
R CMD check
locally. Check that a Windows binary can be
built by running devtools::build_win()
. The results will be
emailed to you within about 30 minutes. Also, this package uses
continuous integration to automatically check the package on Linux, Mac,
and Windows whenever it’s pushed to GitHub. Check the badges at the top
of the GitHub repo to ensure the builds are passing. Any NOTEs, ERRORs,
or WARNINGs returned by R CMD check must be fixed before submission to
CRAN.DESCRIPTION
file.NEWS.md
to note any new features or
changes.devtools::build()
, the vignettes
with devtools::build_vignettes()
, and the website with
pkgdown::build_site()
.devtools::release()
At this point, you’ll need to wait for binaries of your package to build, which could take a couple days. It’s possible that problems will arise during this process and your package will be rejected, in which case, you’ll need to fix any problems and resubmit.
Once the package is on CRAN, create a new release on GitHub and tag it with the version number.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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