Whoever is reading this blog knows that I use
Ledger-likes to track my
finances. Some of you may also know that the currency is just some arbitrary
name for any kind of unit. And a minority of you may also know there is special
support for tracking time in the original Ledger program. This post explains
how I use Ledger and a few Bash aliases to track different activities during a
normal work day.
In a “regular” Ledger file you will find transactions that describe the flow
of a commodity from one (or more) to another account at a certain time.
There is however special support for timelog entries in the ledger program.
They look similar but have special syntax to describe the start and end of a
“transaction”
i 2019/03/02 00:30:20 Entertainment:Netflix
o 2019/03/02 00:35:20
which basically state what to account from i to o. Suppose you have a
timelog file foo.ledger then ledger -f time.ledger bal would give you
something like this:
9.07h Work
32.3m Mail
6.9m Admin
8.40h Development
1.69h Entertainment:Netflix
14.2m Drinking
11.9m Meetings
--------------------
11.19h
All good. Now, adding new entries by “punching in” new lines like that above is
more than just cumbersome, it’s something a simple alias could do as well. I
have defined something like
alias clock-in='echo i $(date +"%Y/%m/%d %H:%M:%S") >> ${TIMELOG}'
alias clock-out='echo o $(date +"%Y/%m/%d %H:%M:%S") >> ${TIMELOG}'
where TIMELOG points to the time.ledger file. Once you type
an appropriate transaction will be made. To check what’s currently going on,
this alias might help:
alias clock-status='[[ $(tail -1 ${TIMELOG} | cut -c 1) == "i" ]] && { echo "Clocked IN to $(tail -1 ${TIMELOG} | cut -d " " -f 4)"; wasted; } || { echo "Clocked OUT"; wasted;}'
That all looks nice and dandy until you realize you don’t remember a particular
activity you want to account you current time on. If you have used any CLI
program you probably hit Tab more than twice. Wait no more, just define
function _clock_in ()
{
local cur prev
_get_comp_words_by_ref -n : cur
local words="$(cut -d ' ' -s -f 4 ${TIMELOG} | sed '/^$/d' | sort | uniq)"
COMPREPLY=($(compgen -W "${words}" -- ${cur}))
__ltrim_colon_completions "${cur}"
}
complete -F _clock_in clock-in
and you are all set to complete the timelog entry while you clock in. You could
write more elaborate logic in an appropriate scripting language but that’s an
exercise for the reader.
I wrote about meson the awesome build system before. For C-based projects
with many test executables there is nice infrastructure, however many C++
projects probably use Google Test or Catch and a single binary which
runs the entire test suite. This is all nice and dandy with Google Test if you
compile and link the test executable straight from the unit test source files.
If however you build intermediate static libraries for organizational reasons
you will quickly notice that Google Test won’t run anything at all because the
symbols from Google Test itself won’t end up in the final
binary without specifying the
--whole-archive flag. Luckily, meson got the link_whole parameter since
version 0.46, so instead of declaring your static test library as
test_lib = static_library('testlib',
sources: test_sources,
dependencies: [gtest_dep] + build_deps,
)
test_dep = declare_dependency(
link_with: test_lib,
dependencies: other_deps,
)
test_binary = executable('testfoo',
sources: ['main.cpp'],
dependencies: [test_dep],
)
you would change test_dep to
test_dep = declare_dependency(
link_whole: test_lib,
dependencies: other_deps,
)
and run your tests as usual.
For the past three years I have been recording my finances with tools from the
ledger family. While I had no major issues with them, there were a few minor
annoyances, most notably recording capital gains in hledger without a virtual
posting and a lack of a nice visual representation of my finances. I knew about
beancount but was always a bit sceptical about its data format which is not
really compatible with the other ledger tools. The deciding factor to take the
plunge was the fava web interface and the comprehensive inventory system
which makes recording capital gains a breeze.
Importing Deutsche Bank data
Moving the ledger data to the beancount format was pretty straightforward using
the ledger2beancount tool. Unfortunately, I had to re-write the import tool
from scratch because beancount does not provide a command similar to hledger
csv. On the other hand, it was relatively simple to come up with these little
bits of Python:
import os
import re
import codecs
import csv
import datetime
from beancount.core import number, data, amount
from beancount.ingest import importer
class Target(object):
def __init__(self, account, payee=None, narration=None):
self.account = account
self.payee = payee
self.narration = narration
class DeutscheBankImporter(importer.ImporterProtocol):
def __init__(self, account, default, mapping):
self.account = account
self.default = default
self.mapping = mapping
def identify(self, fname):
return re.match(r"Kontoumsaetze_\d+_\d+_\d+_\d+.csv",
os.path.basename(fname.name))
def file_account(self, fname):
return self.account
def extract(self, fname):
fp = codecs.open(fname.name, 'r', 'iso-8859-1')
lines = fp.readlines()
# drop top and bottom stuff
lines = lines[5:]
lines = lines[:-1]
entries = []
def fix_decimals(s):
return s.replace('.', '').replace(',', '.')
for index, row in enumerate(csv.reader(lines, delimiter=';')):
meta = data.new_metadata(fname.name, index)
date = datetime.datetime.strptime(row[0], '%d.%m.%Y').date()
desc = row[4]
payee = row[3]
credit = fix_decimals(row[15]) if row[15] != '' else None
debit = fix_decimals(row[16]) if row[16] != '' else None
currency = row[17]
account = self.default
num = number.D(credit if credit else debit)
units = amount.Amount(num, currency)
for p, t in self.mapping.items():
if p in desc:
account = t.account
if t.narration:
desc = t.narration
if t.payee:
payee = t.payee
frm = data.Posting(self.account, units, None, None, None, None)
to = data.Posting(account, -units, None, None, None, None)
txn = data.Transaction(meta, date, "*", payee, desc,
data.EMPTY_SET, data.EMPTY_SET, [frm, to])
entries.append(txn)
return entries
that you would plug in to your import config like this:
mappings = {
'Salary':
Target('Assets:Income', 'Foo Company'),
'Walmart':
Target('Expenses:Food:Groceries'),
}
CONFIG = [
DeutscheBankImporter('Assets:Checking', 'Expenses:ReplaceMe', mappings)
]
Yes, that’s my answer to this statement from the official documentation:
My standard answer is that while it would be fun to have [automatic
categorization], if you have a text editor with account name completion
configured properly, it’s a breeze to do this manually and you don’t really
need it.
On to the next years …
Developing C and C++ projects in a cross-platform manner is not only difficult
because of different system APIs but also because dependencies have to be
tracked, installed and integrated into the build system du jour. While it is
largely a solved problem on Linux thanks to system package managers and de facto
standards such as pkg-config, the situation on Windows is tricky because both
are missing. Rust and Go easily circumvent this situation by building static
binaries from source using their integrated package managers. In a similar
manner a Microsoft team tries to combine package management and build
integration on Linux, Mac and Windows with their open source vcpkg package
manager.
The main idea is simple: 1) provide a repository with build and dependency
descriptions for a wide range of libraries, 2) a CLI tool to actually build said
libraries locally and 3) means to make use of these libraries. Each of these
points has its pros and cons you can see when trying to build the following C
toy example on Linux which depends on the GLib utility library:
#include <glib.h>
int
main (int argc, char *argv[])
{
g_print ("Hello world\n");
return 0;
}
With vcpkg you first have to clone the repository and then build the vcpkg
binary. Easier said than done because the binary requires g++-7 to build. You
then use
to build GLib and all its dependencies which works well but has one big caveat:
Using so-called CONTROL files, maintainers specify the version of the library
and all their dependencies. Unfortunately, build dependencies are not
versioned but taken from the current state of the repository. This means you can
only pin the version of library A by not upgrading the repository therefore you
are unable to upgrade to a newer version of library B. In the end, vcpkg is
just like a system package manager and we are nowhere near closer to the Rust
build story.
Now, how do we use our library? Well there’s the first problem. At the moment,
the only officially supported way is to write a CMake build script such as this
cmake_minimum_required(VERSION 3.0)
project(hello)
find_path(GLIB_INCLUDE_DIR glib.h)
find_library(GLIB glib REQUIRED)
add_executable(hello hello.c)
target_link_libraries(hello PRIVATE ${GLIB_LIBRARY})
target_include_directories(hello ${GLIB_INCLUDE_DIR})
and passing their toolchain file to the configure process of CMake
cmake <builddir> . -DCMAKE_TOOLCHAIN_FILE=<vcpkgroot>/scripts/buildsystems/vcpkg.cmake
For projects that have native CMake support you can use the find_package
command but as you can see we have to rely on the find_library and find_path
commands for GLib. Except, it does not work. CMake is unable to find neither
GLib sqlite3 using find_package as outlined in the documentation. Could we
at least build something by hand? Kind of. All libraries and header files are
installed under <vcpkgroot>/installed/x64-linux and the various
sub-directories. However, you have to hardcode the paths because pkg-config
files are not installed thus its worse than using system development libraries.
Because of these issues, I would not consider vcpkg to be an alternative
package and build manager for Linux at the time of writing. There are some good
ideas but spack pretty much does the same for a while now
and they gave way more time thinking into their product. Let’s hope it will get
better.