I recently developed Pokerware, an offline passphrase
generator that operates in the same spirit as Diceware.
The primary difference is that it uses a shuffled deck of playing
cards as its entropy source rather than dice. Draw some cards and use
them to select a uniformly random word from a list. Unless you’re some
sort of tabletop gaming nerd, a deck of cards is more readily
available than five 6-sided dice, which would typically need to be
borrowed from the Monopoly board collecting dust on the shelf, then
rolled two at a time.
There are various flavors of two different word lists here:
Hardware random number generators are difficult to verify
and may not actually be as random as they promise, either
intentionally or unintentionally. For the particularly paranoid,
Diceware and Pokerware are an easily verifiable alternative for
generating secure passphrases for cryptographic purposes.
At any time, a deck of 52 playing cards is in one of 52! possible
arrangements. That’s more than 225 bits of entropy. If you give your
deck a thorough shuffle, it will be in an arrangement that
has never been seen before and will never be seen again. Pokerware
draws on some of these bits to generate passphrases.
The Pokerware list has 5,304 words (12.4 bits per word), compared to
Diceware’s 7,776 words (12.9 bits per word). My goal was to invent a
card-drawing scheme that would uniformly select from a list in the same
sized ballpark as Diceware. Much smaller and you’d have to memorize more
words for the same passphrase strength. Much larger and the words on the
list would be more difficult to memorize, since the list would contain
longer and less frequently used words. Diceware strikes a nice balance
at five dice.
One important difference for me is that I like my Pokerware word
lists a lot more than the two official Diceware lists. My lists only
have simple, easy-to-remember words (for American English speakers, at
least), without any numbers or other short non-words. Pokerware has
two official lists, “formal” and “slang,” since my early testers
couldn’t agree on which was better. Rather than make a difficult
decision, I took the usual route of making no decision at all.
The “formal” list is derived in part from Google’s Ngram
Viewer, with my own additional filters and tweaking. It’s called
“formal” because the ngrams come from formal publications and represent
more formal kinds of speech.
The “slang” list is derived from every reddit comment between
December 2005 and May 2017, tamed by the same additional filters. I
have this data on hand, so I may as well put it to use. I
figured more casually-used words would be easier to remember. Due to
my extra filtering, there’s actually a lot of overlap between these
lists, so the differences aren’t too significant.
If you have your own word list, perhaps in a different language, you
can use the Makefile in the repository to build your own Pokerware
lookup table, both plain text and PDF. The PDF is generated using
Groff macros.
Passphrase generation instructions
Thoroughly shuffle the deck.
Draw two cards. Sort them by value, then suit. Suits are in
alphabetical order: Clubs, Diamonds, Hearts, Spades.
Draw additional cards until you get a card that doesn’t match the
face value of either of your initial two cards. Observe its suit.
Using your two cards and observed suit, look up a word in the table.
Place all cards back in the deck, shuffle, and repeat from step 2
until you have the desired number of words. Each word is worth 12.4
bits of entropy.
A word of warning about step 4: If you use software to do the word list
lookup, beware that it might save your search/command history — and
therefore your passphrase — to a file. For example, the less pager
will store search history in ~/.lesshst. It’s easy to prevent that
one:
$ LESSHISTFILE=- less pokerware-slang.txt
Example word generation
Suppose in step 2 you draw King of Hearts (KH/K♥) and Queen of Clubs
(QC/Q♣).
In step 3 you first draw King of Diamonds (KD/K♦), discarding it because
it matches the face value of one of your cards from step 2.
Next you draw Four of Spades (4S/4♠), taking spades as your extra suit.
In order, this gives you Queen of Clubs, King of Hearts, and Spades:
QCKHS or Q♣K♥♠. This corresponds to “wizard” in the formal word list and
would be the first word in your passphrase.
A deck of cards as an office tool
I now have an excuse to keep a deck of cards out on my desk at work.
I’ve been using Diceware — or something approximating it since I’m not
so paranoid about hardware RNGs — for passwords for over 8 years
now. From now I’ll deal new passwords from an in-reach deck of
cards. Though typically I need to tweak the results to meet outdated
character-composition requirements.
Last week I was discussing CVE-2017-7529 with my intern.
Specially crafted input to Nginx causes an integer overflow which has the
potential to leak sensitive information. But how could an integer overflow
be abused to trick a program into leaking information? To answer this
question, I put together the simplest practical example I could imagine.
This small C program converts a vector image from a custom format
(described below) into a Netpbm image, a conveniently simple
format. The program defensively and carefully parses its input, but
still makes a subtle, fatal mistake. This mistake not only leads to
sensitive information disclosure, but, with a more sophisticated attack,
could be used to execute arbitrary code.
After getting the hang of the interface for the program, I encourage you
to take some time to work out an exploit yourself. Regardless, I’ll reveal
a functioning exploit and explain how it works.
A new vector format
The input format is line-oriented and very similar to Netpbm itself. The
first line is the header, starting with the magic number V2 (ASCII)
followed by the image dimensions. The target output format is Netpbm’s
“P2” (text gray scale) format, so the “V2” parallels it. The file must end
with a newline.
V2 <width> <height>
What follows is drawing commands, one per line. For example, the s
command sets the value of a particular pixel.
s <x> <y> <00–ff>
Since it’s not important for the demonstration, this is the only command I
implemented. It’s easy to imagine additional commands to draw lines,
circles, Bezier curves, etc.
Here’s an example (example.txt) that draws a single white point in the
middle of the image:
V2 256 256
s 127 127 ff
The rendering tool reads standard input to standard output:
$ render < example.txt > example.pgm
Here’s what it looks like rendered:
However, you will notice that when you run the rendering tool, it prompts
you for username and password. This is silly, of course, but it’s an
excuse to get “sensitive” information into memory. It will accept any
username/password combination where the username and password don’t match
each other. The key is this: It’s possible to craft a valid image that
leaks the the entered password.
Tour of the implementation
Without spoiling anything yet, let’s look at how this program works. The
first thing to notice is that I’m using a custom “obstack”
allocator instead of malloc() and free(). Real-world allocators have
some defenses against this particular vulnerability. Plus a specific
exploit would have to target a specific libc. By using my own allocator,
the exploit will mostly be portable, making for a better and easier
demonstration.
The allocator interface should be pretty self-explanatory, except for two
details. This is an obstack allocator, so freeing an object also frees
every object allocated after it. Also, it doesn’t call malloc() in the
background. At initialization you give it a buffer from which to allocate
all memory.
There are no vulnerabilities in these functions (I hope!). It’s just
here for predictability.
Next here’s the “authentication” function. It reads a username and
password combination from /dev/tty. It’s only an excuse to get a flag in
memory for this capture-the-flag game. The username and password must be
less than 32 characters each.
Next up is a paranoid wrapper for strtoul() that defensively checks its
inputs. If it’s out of range of an unsigned long, it bails out. If
there’s trailing garbage, it bails out. If there’s no number at all, it
bails out. If you make prolonged eye contact, it bails out.
unsignedlongsafe_strtoul(char*nptr,char**endptr,intbase){errno=0;unsignedlongn=strtoul(nptr,endptr,base);if(errno){perror(nptr);exit(EXIT_FAILURE);}elseif(nptr==*endptr){fprintf(stderr,"Expected an integer\n");exit(EXIT_FAILURE);}elseif(!isspace(**endptr)){fprintf(stderr,"Invalid character '%c'\n",**endptr);exit(EXIT_FAILURE);}returnn;}
The main() function parses the header using this wrapper and allocates
some zeroed memory:
Then there’s a command processing loop, also using safe_strtoul(). It
carefully checks bounds against width and height. Finally it writes
out a Netpbm, P2 (.pgm) format.
Where did those junk numbers come from in the image data? Plug them into
an ASCII table and you’ll get “mysecret”. Despite allocating the image
with naive_calloc(), the password has found its way into the image! How
could this be?
What happened is that width * height overflows an unsigned long.
(Well, technically speaking, unsigned integers are defined not to
overflow in C, wrapping around instead, but it’s really the same thing.)
In naive_calloc(), the overflow results in a value of 16, so it only
allocates and clears 16 bytes. The requested allocation “succeeds” despite
far exceeding the available memory. The caller has been given a lot less
memory than expected, and the memory believed to have been allocated
contains a password.
The final part that writes the output doesn’t multiply the integers and
doesn’t need to test for overflow. It uses a nested loop instead,
continuing along with the original, impossible image size.
How do we fix this? Add an overflow check at the beginning of the
naive_calloc() function (making it no longer naive). This is what the
real calloc() does.
if(nmemb&&size>-1UL/nmemb)return0;
The frightening takeaway is that this check is very easy to forget. It’s
a subtle bug with potentially disastrous consequences.
In practice, this sort of program wouldn’t have sensitive data resident in
memory. Instead an attacker would target the program’s stack with those
s commands — specifically the return pointers — and perform a ROP
attack against the application. With the exploit header above and a
platform where long the same size as a size_t, the program will behave
as if all available memory has been allocated to the image, so the s
command could be used to poke custom values anywhere in memory. This is
a much more complicated exploit, and it has to contend with ASLR and
random stack gap, but it’s feasible.
The most recent Smarter Every Day (#172) explains a phenomenon
that results from rolling shutter. You’ve likely seen this effect in
some of your own digital photographs. When a CMOS digital camera
captures a picture, it reads one row of the sensor at a time. If the
subject of the picture is a fast-moving object (relative to the
camera), then the subject will change significantly while the image is
being captured, giving strange, unreal results:
In the Smarter Every Day video, Destin illustrates the effect by
simulating rolling shutter using a short video clip. In each frame of
the video, a few additional rows are locked in place, showing the
effect in slow motion, making it easier to understand.
At the end of the video he thanks a friend for figuring out how to get
After Effects to simulate rolling shutter. After thinking about this
for a moment, I figured I could easily accomplish this myself with
just a bit of C, without any libraries. The video above this paragraph
is the result.
I previously described a technique to edit and manipulate
video without any formal video editing tools. A unix pipeline is
sufficient for doing minor video editing, especially without sound.
The program at the front of the pipe decodes the video into a raw,
uncompressed format, such as YUV4MPEG or PPM. The tools in
the middle losslessly manipulate this data to achieve the desired
effect (watermark, scaling, etc.). Finally, the tool at the end
encodes the video into a standard format.
For the “decode” program I’ll be using ffmpeg now that it’s back in
the Debian repositories. You can throw a video in virtually any
format at it and it will write PPM frames to standard output. For the
encoder I’ll be using the x264 command line program, though ffmpeg
could handle this part as well. Without any filters in the middle,
this example will just re-encode a video:
The filter tools in the middle only need to read and write in the raw
image format. They’re a little bit like shaders, and they’re easy to
write. In this case, I’ll write C program that simulates rolling
shutter. The filter could be written in any language that can read and
write binary data from standard input to standard output.
Update: It appears that input PPM streams are a rather recent
feature of libavformat (a.k.a lavf, used by x264). Support for PPM
input first appeared in libavformat 3.1 (released June 26th, 2016). If
you’re using an older version of libavformat, you’ll need to stick
ppmtoy4m in front of x264 in the processing pipeline.
In the past, my go to for raw video data has been loose PPM frames and
YUV4MPEG streams (via ppmtoy4m). Fortunately, over the years a lot
of tools have gained the ability to manipulate streams of PPM images,
which is a much more convenient format. Despite being raw video data,
YUV4MPEG is still a fairly complex format with lots of options and
annoying colorspace concerns. PPM is simple RGB without
complications. The header is just text:
The maximum depth is virtually always 255. A smaller value reduces the
image’s dynamic range without reducing the size. A larger value involves
byte-order issues (endian). For video frame data, the file will
typically look like:
P6
1920 1080
255
<frame RGB>
Unfortunately the format is actually a little more flexible than this.
Except for the new line (LF, 0x0A) after the maximum depth, the
whitespace is arbitrary and comments starting with # are permitted.
Since the tools I’m using won’t produce comments, I’m going to ignore
that detail. I’ll also assume the maximum depth is always 255.
Here’s the structure I used to represent a PPM image, just one frame
of video. I’m using a flexible array member to pack the data at the
end of the structure.
Finally, a function to read a frame, reusing an existing buffer if
possible. The most complex part of the whole program is just parsing
the PPM header. The %*c in the scanf() specifically consumes the
line feed immediately following the maximum depth.
Since this program will only be part of a pipeline, I’m not worried
about checking the results of fwrite() and fread(). The process
will be killed by the shell if something goes wrong with the pipes.
However, if we’re out of video data and get an EOF, scanf() will
fail, indicating the EOF, which is normal and can be handled cleanly.
An identity filter
That’s all the infrastructure we need to built an identity filter that
passes frames through unchanged:
Processing a frame is just matter of adding some stuff to the body of
the while loop.
A rolling shutter filter
For the rolling shutter filter, in addition to the input frame we need
an image to hold the result of the rolling shutter. Each input frame
will be copied into the rolling shutter frame, but a little less will be
copied from each frame, locking a little bit more of the image in place.
The shutter_step controls how many rows are capture per frame of
video. Generally capturing one row per frame is too slow for the
simulation. For a 1080p video, that’s 1,080 frames for the entire
simulation: 18 seconds at 60 FPS or 36 seconds at 30 FPS. If this
program were to accept command line arguments, controlling the shutter
rate would be one of the options.
Here are some of the results for different shutter rates: 1, 3, 5, 8,
10, and 15 rows per frame. Feel free to right-click and “View Video”
to see the full resolution video.
Source and original input
This post contains the full source in parts, but here it is all together:
Stack clashing has been in the news lately due to some recently
discovered vulnerablities along with proof-of-concept
exploits. As the announcement itself notes, this is not a new issue,
though this appears to be the first time it’s been given this
particular name. I do know of one “good” use of stack clashing, where
it’s used for something productive than as part of an attack. In this
article I’ll explain how it works.
You can find the complete code for this article here, ready to run:
But first, what is a stack clash? Here’s a rough picture of the
typical way process memory is laid out. The stack starts at a high
memory address and grows downwards. Code and static data sit at low
memory, with a brk pointer growing upward to make small allocations.
In the middle is the heap, where large allocations and memory mappings
take place.
Below the stack is a slim guard page that divides the stack and the
region of memory reserved for the heap. Reading or writing to that
memory will trap, causing the program to crash or some special action
to be taken. The goal is to prevent the stack from growing into the
heap, which could cause all sorts of trouble, like security issues.
The problem is that this thin guard page isn’t enough. It’s possible to
put a large allocation on the stack, never read or write to it, and
completely skip over the guard page, such that the heap and stack
overlap without detection.
Once this happens, writes into the heap will change memory on the
stack and vice versa. If an attacker can cause the program to make
such a large allocation on the stack, then legitimate writes into
memory on the heap can manipulate local variables or return pointers,
changing the program’s control flow. This can bypass buffer
overflow protections, such as stack canaries.
Binary trees and coroutines
Now, I’m going to abruptly change topics to discuss binary search
trees. We’ll get back to stack clash in a bit. Suppose we have a
binary tree which we would like to iterate depth-first. For this
demonstration, here’s the C interface to the binary tree.
An empty tree is the NULL pointer, hence the double-pointer for
insert. In the demonstration it’s an unbalanced search tree, but this
could very well be a balanced search tree with the addition of another
field on the structure.
For the traversal, first visit the root node, then traverse its left
tree, and finally traverse its right tree. It makes for a simple,
recursive definition — the sort of thing you’d teach a beginner.
Here’s a definition that accepts a callback, which the caller will use
to visit each key/value in the tree. This really is as simple as it
gets.
Unfortunately this isn’t so convenient for the caller, who has to
split off a callback function that lacks context, then hand
over control to the traversal function.
Usually it’s much nicer for the caller if instead it’s provided an
iterator, which the caller can invoke at will. Here’s an interface
for it, just two functions.
The first constructs an iterator object, and the second one visits a
key/value pair each time it’s called. It returns 0 when traversal is
complete, automatically freeing any resources associated with the
iterator.
Notice I haven’t defined struct tree_it. That’s because I’ve got
four different implementations, each taking a different approach. The
last one will use stack clashing.
Manual State Tracking
With just the standard facilities provided by C, there’s a some manual
bookkeeping that has to take place in order to convert the recursive
definition into an iterator. Depth-first traversal is a stack-oriented
process, and with recursion the stack is implicit in the call stack.
As an iterator, the traversal stack needs to be managed
explicitly. The iterator needs to keep track of the path it
took so that it can backtrack, which means keeping track of parent
nodes as well as which branch was taken.
Here’s my little implementation, which, to keep things simple, has a
hard depth limit of 32. It’s structure definition includes a stack of
node pointers, and 2 bits of information per visited node, stored
across a 64-bit integer.
The 2 bits track three different states for each visited node:
Visit the current node
Traverse the left tree
Traverse the right tree
It works out to the following. Don’t worry too much about trying to
understand how this works. My point is to demonstrate that converting
the recursive definition into an iterator complicates the
implementation.
Wouldn’t it be nice to keep both the recursive definition while also
getting an iterator? There’s an exact solution to that: coroutines.
Coroutines
C doesn’t come with coroutines, but there are a number of libraries
available. We can also build our own coroutines. One way to do that is
with user contexts (<ucontext.h>) provided by the X/Open System
Interfaces Extension (XSI), an extension to POSIX. This set of
functions allow programs to create their own call stacks and switch
between them. That’s the key ingredient for coroutines. Caveat: These
functions aren’t widely available, and probably shouldn’t be used in
new code.
It needs one context for the original stack and one context for the
iterator’s stack. Each time the iterator is invoked, it the program
will switch to the other stack, find the next value, then switch back.
This process is called yielding. Values are passed between context
using the k (key) and v (value) fields on the iterator.
Before I get into initialization, here’s the actual traversal
coroutine. It’s nearly the same as the original recursive definition
except for the swapcontext(). This is the yield, pausing execution
and sending control back to the caller. The current context is saved
in the first argument, and the second argument becomes the current
context.
While the actual traversal is simple again, initialization is more
complicated. The first problem is that there’s no way to pass pointer
arguments to the coroutine. Technically only int arguments are
permitted. (All the online tutorials get this wrong.) To work around
this problem, I smuggle the arguments in as global variables. This
would cause problems should two different threads try to create
iterators at the same time, even on different trees.
The stack has to be allocated manually, which I do with a call to
malloc(). Nothing fancy is needed, though this means the new
stack won’t have a guard page. For the stack size, I use the suggested
value of SIGSTKSZ. The makecontext() function is what creates the
new context from scratch, but the new context must first be
initialized with getcontext(), even though that particular snapshot
won’t actually be used.
Notice I gave it a function pointer, a lot like I’m starting a new
thread. This is no coincidence. There’s a lot of similarity between
coroutines and multiple threads, as you’ll soon see.
Finally the iterator function itself. Since NULL isn’t a valid key, it
initializes the key to NULL before yielding to the iterator context.
If the iterator has no more nodes to visit, it doesn’t set the key,
which can be detected when control returns.
That’s all it takes to create and operate a coroutine in C, provided
you’re on a system with these XSI extensions.
Semaphores
Instead of a coroutine, we could just use actual threads and a couple
of semaphores to synchronize them. This is a heavy implementation and
also probably shouldn’t be used in practice, but at least it’s fully
portable.
Overall, this is almost identical to the coroutine version.
Coroutines using stack clashing
Finally I can tie this back into the topic at hand. Without either XSI
extensions or Pthreads, we can (usually) create coroutines by abusing
setjmp() and longjmp(). Technically this violates two of the C’s
rules and relies on undefined behavior, but it generally works. This
is not my own invention, and it dates back to at least 2010.
From the very beginning, C has provided a crude “exception” mechanism
that allows the stack to be abruptly unwound back to a previous state.
It’s a sort of non-local goto. Call setjmp() to capture an opaque
jmp_buf object to be used in the future. This function returns 0
this first time. Hand that value to longjmp() later, even in a
different function, and setjmp() will return again, this time with a
non-zero value.
It’s technically unsuitable for coroutines because the jump is a
one-way trip. The unwound stack invalidates any jmp_buf that was
created after the target of the jump. In practice, though, you can
still use these jumps, which is one rule being broken.
That’s where stack clashing comes into play. In order for it to be a
proper coroutine, it needs to have its own stack. But how can we do
that with these primitive C utilities? Extend the stack to overlap
the heap, call setjmp() to capture a coroutine on it, then return.
Generally we can get away with using longjmp() to return to this
heap-allocated stack.
Here’s my iterator definition for this one. Like the XSI context
struct, this has two jmp_buf “contexts.” The stack holds the
iterator’s stack buffer so that it can be freed, and the gap field
will be used to prevent the optimizer from spoiling our plans.
The coroutine looks familiar again. This time the yield is performed
with setjmmp() and longjmp(), just like swapcontext(). Remember
that setjmp() returns twice, hence the branch. The longjmp() never
returns.
Next is the tricky part to cause the stack clash. First, allocate the
new stack with malloc() so that we can get its address. Then use a
local variable on the stack to determine how much the stack needs to
grow in order to overlap with the allocation. Taking the difference
between these pointers is illegal as far as the language is concerned,
making this the second rule I’m breaking. I can imagine an
implementation where the stack and heap are in two separate
kinds of memory, and it would be meaningless to take the difference. I
don’t actually have to imagine very hard, because this is actually how
it used to work on the 8086 with its segmented memory
architecture.
I’m using a variable-length array (VLA) named gap to indirectly
control the stack pointer, moving it over the heap. I’m assuming the
stack grows downward, since otherwise the sign would be wrong.
The compiler is smart and will notice I’m not actually using gap,
and it’s happy to throw it away. In fact, it’s vitally important that
I don’t touch it since the guard page, along with a bunch of
unmapped memory, is actually somewhere in the middle of that array. I
only want the array for its side effect, but that side effect isn’t
officially supported, which means the optimizer doesn’t need to
consider it in its decisions. To inhibit the optimizer, I store the
array’s address where someone might potentially look at it, meaning
the array has to exist.
Finally, the iterator function looks just like the others, again.
For more than 5 years now I’ve kept a private “root” filesystem within
my home directory under $HOME/.local/. Within are the standard
/usr directories, such as bin/, include/, lib/, etc.,
containing my own software, libraries, and man pages. These are
first-class citizens, indistinguishable from the system-installed
programs and libraries. With one exception (setuid programs), none of
this requires root privileges.
Installing software in $HOME serves two important purposes, both of
which are indispensable to me on a regular basis.
No root access: Sometimes I’m using a system administered by
someone else, and I don’t have root access.
This prevents me from installing packaged software myself through the
system’s package manager. Building and installing the software myself in
my home directory, without involvement from the system administrator,
neatly works around this issue. As a software developer, it’s already
perfectly normal for me to build and run custom software, and this is
just an extension of that behavior.
In the most desperate situation, all I need from the sysadmin is a
decent C compiler and at least a minimal POSIX environment. I can
bootstrap anything I might need, both libraries and
programs, including a better C compiler along the way. This is one
major strength of open source software.
I have noticed one alarming trend: Both GCC (since 4.8) and Clang are
written in C++, so it’s becoming less and less reasonable to bootstrap
a C++ compiler from a C compiler, or even from a C++ compiler that’s
more than a few years old. So you may also need your sysadmin to
supply a fairly recent C++ compiler if you want to bootstrap an
environment that includes C++. I’ve had to avoid some C++ software
(such as CMake) for this reason.
Custom software builds: Even if I am root, I may still want to
install software not available through the package manager, a version
not available in the package manager, or a version with custom
patches.
In theory this is what /usr/local is all about. It’s typically the
location for software not managed by the system’s package manager.
However, I think it’s cleaner to put this in $HOME/.local, so long
as other system users don’t need it.
For example, I have an installation of each version of Emacs between
24.3 (the oldest version worth supporting) through the latest stable
release, each suffixed with its version number, under $HOME/.local.
This is useful for quickly running a test suite under different
releases.
$ git clone https://github.com/skeeto/elfeed
$ cd elfeed/
$ make EMACS=emacs24.3 clean test
...
$ make EMACS=emacs25.2 clean test
...
$ tar xzf nethack-343-src.tar.gz
$ cd nethack-3.4.3/
$ patch -p1 < ~/nh343-menucolor.diff
$ patch -p1 < ~/nh343-wchar.diff
$ patch -p1 < ~/nh343-home-install.diff
$ sh sys/unix/setup.sh
$ make -j$(nproc) install
Normally NetHack wants to be setuid (e.g. run as the “games” user) in
order to restrict access to high scores, saves, and bones — saved levels
where a player died, to be inserted randomly into other players’ games.
This prevents cheating, but requires root to set up. Fortunately, when I
install NetHack in my home directory, this isn’t a feature I actually
care about, so I can ignore it.
Mutt is in a similar situation, since it wants to install a
special setgid program (mutt_dotlock) that synchronizes mailbox
access. All MUAs need something like this.
Everything described below is relevant to basically any modern
unix-like system: Linux, BSD, etc. I personally install software in
$HOME across a variety of systems and, fortunately, it mostly works
the same way everywhere. This is probably in large part due to
everyone standardizing around the GCC and GNU binutils interfaces,
even if the system compiler is actually LLVM/Clang.
Configuring for $HOME installs
Out of the box, installing things in $HOME/.local won’t do anything
useful. You need to set up some environment variables in your shell
configuration (i.e. .profile, .bashrc, etc.) to tell various
programs, such as your shell, about it. The most obvious variable is
$PATH:
export PATH=$HOME/.local/bin:$PATH
Notice I put it in the front of the list. This is because I want my
home directory programs to override system programs with the same
name. For what other reason would I install a program with the same
name if not to override the system program?
In the simplest situation this is good enough, but in practice you’ll
probably need to set a few more things. If you install libraries in
your home directory and expect to use them just as if they were
installed on the system, you’ll need to tell the compiler where else
to look for those headers and libraries, both for C and C++.
This is like the -I compiler option and the -L linker option,
except you won’t need to use them explicitly. Some software uses
pkg-config to determine its compiler and linker flags, and your home
directory will contain some of the needed information. So set that up
too:
export PKG_CONFIG_PATH=$HOME/.local/lib/pkgconfig
Run-time linker
Finally, when you install libraries in your home directory, the run-time
dynamic linker will need to know where to find them. There are three
ways to deal with this:
Screw it, just statically link the bugger. (Not always possible.)
For the crude way, point the run-time linker at your lib/ and you’re
done:
export LD_LIBRARY_PATH=$HOME/.local/lib
However, this is like using a shotgun to kill a fly. If you install a
library in your home directory that is also installed on the system,
and then run a system program, it may be linked against your library
rather than the library installed on the system as was originally
intended. This could have detrimental effects.
The precision method is to set the ELF “runpath” value. It’s like a
per-binary LD_LIBRARY_PATH. The run-time linker uses this path first
in its search for libraries, and it will only have an effect on that
particular program/library. This also applies to dlopen().
Some software will configure the runpath by default, but usually you
need to configure this yourself with the linker -rpath option in
LDFLAGS. It’s used directly like this:
ELF supports a special $ORIGIN “variable” set to the binary’s
location. This allows the program and associated libraries to be
installed anywhere without changes, so long as they have the same
relative position to each other . (Note the quotes to prevent shell
interpolation.)
There is one situation where runpath won’t work: when you want a
system-installed program to find a home directory library with
dlopen() — e.g. as an extension to that program. You either need to
ensure it uses a relative or absolute path (i.e. the argument to
dlopen() contains a slash) or you must use LD_LIBRARY_PATH.
Personally, I always use the Worse is BetterLD_LIBRARY_PATH
shotgun. Occasionally it’s caused some annoying issues, but the vast
majority of the time it gets the job done with little fuss. This is
just my personal development environment, after all, not a production
server.
Manual pages
Another potentially tricky issue is man pages. When a program or
library installs a man page in your home directory, it would certainly
be nice to access it with man <topic> just like it was installed on
the system. Fortunately, Debian and Debian-derived systems, using a
mechanism I haven’t yet figured out, discover home directory man pages
automatically without any assistance. No configuration needed.
It’s more complicated on other systems, such as the BSDs. You’ll need to
set the MANPATH variable to include $HOME/.local/share/man. It’s
unset by default and it overrides the system settings, which means you
need to manually include the system paths. The manpath program can
help with this … if it’s available.
export MANPATH=$HOME/.local/share/man:$(manpath)
I haven’t figured out a portable way to deal with this issue, so I
mostly ignore it.
How to install software in $HOME
While I’ve poo-pooed autoconf in the past, the standard
configure script usually makes it trivial to build and install
software in $HOME. The key ingredient is the --prefix option:
$ tar xzf name-version.tar.gz
$ cd name-version/
$ ./configure --prefix=$HOME/.local
$ make -j$(nproc)
$ make install
Most of the time it’s that simple! If you’re linking against your own
libraries and want to use runpath, it’s a little more complicated:
The CMake builds I’ve seen use ELF runpath by default, and no further
configuration may be required to make that work. I’m sure that’s not
always the case, though.
Some software is just a single, static, standalone binary with
everything baked in. It doesn’t need to be given a prefix, and
installation is as simple as copying the binary into place. For example,
Enchive works like this:
$ git clone https://github.com/skeeto/enchive
$ cd enchive/
$ make
$ cp enchive ~/.local/bin
Some software uses its own unique configuration interface. I can respect
that, but it does add some friction for users who now have something
additional and non-transferable to learn. I demonstrated a NetHack build
above, which has a configuration much more involved than it really
should be. Another example is LuaJIT, which uses make variables that
must be provided consistently on every invocation:
$ tar xzf LuaJIT-2.0.5.tar.gz
$ cd LuaJIT-2.0.5/
$ make -j$(nproc) PREFIX=$HOME/.local
$ make PREFIX=$HOME/.local install
(You can use the “install” target to both build and install, but I
wanted to illustrate the repetition of PREFIX.)
Some libraries aren’t so smart about pkg-config and need some
handholding — for example, ncurses. I mention it because
it’s required for both Vim and Emacs, among many others, so I’m often
building it myself. It ignores --prefix and needs to be told a
second time where to install things:
Another issue is that a whole lot of software has been hardcoded for
ncurses 5.x (i.e. ncurses5-config), and it requires hacks/patching
to make it behave properly with ncurses 6.x. I’ve avoided ncurses 6.x
for this reason.
Learning through experience
I could go on and on like this, discussing the quirks for the various
libraries and programs that I use. Over the years I’ve gotten used to
many of these issues, committing the solutions to memory.
Unfortunately, even within the same version of a piece of software,
the quirks can change between major operating system
releases, so I’m continuously learning my way around new
issues. It’s really given me an appreciation for all the hard work
that package maintainers put into customizing and maintaining software
builds to fit properly into a larger ecosystem.
Note: The way I manage my email wouldn’t really work for most people,
so don’t read this as a recommendation. This is just a discussion of
how I prefer to use email.
It was almost four years ago I switched from webmail to a customized
email configuration based on Notmuch and Emacs. Notmuch served
as both as a native back-end that provided indexing and tagging, as well
as a front-end, written in Emacs Lisp. It dramatically improved my email
experience, and I wished I had done it earlier. I’ve really enjoyed
having so much direct control over my email.
However, I’m always fiddling with things — fiddling feels a lot more
productive than it actually is — and last month I re-invented my email
situation, this time switching to a combination of Mutt,
Vim, mu, and tmux. The entirety of my email
interface now resides inside a terminal, and I’m enjoying it even more.
I feel I’ve “leveled up” again in my email habits.
On the server-side I also switched from Exim to Postfix and procmail,
making the server configuration a whole lot simpler. Including
SpamAssassin, it’s just three lines added to the default Debian
configuration. It leaves a lot less room for error, and I could rebuild
it from scratch with little trouble if there was an emergency. My
previous configuration required quite a bit of system configuration,
such as relying on incron to sort incoming mail, particularly
spam, but procmail now does this job more cleanly.
Towards Robustness
Over the years I’ve gotten less patient when it comes to dealing with
breaking changes in software, and I’ve gotten more conservative
about system stability. Continuously updating my configurations and
habits to the latest software changes was an interesting challenge
earlier in my career, but today there are much better uses of my time.
Debian Stable, my preferred operating system, runs at pretty much the
perfect pace for me.
Following these changing preferences, one of the biggest motivations for
my recent email change was to make my email setup more robust and
stable. Until now, email was tied tightly to Emacs, with a configuration
drawing directly from MELPA, pulling in the bleeding edge
version of every package I use. Breaking changes arrive at unexpected
times, and occasionally the current version of a package temporarily
doesn’t work. Usually it’s because the developer pushed a bad commit
right before the latest MELPA build, and so the package is broken for a
few hours or days. I’ve been guilty of this myself. MELPA
Stable is intended to address these issues, but it seems to break more
often than normal MELPA. For example, at the time of this writing,
Evil is not installable via MELPA Stable due to an unmet
dependency.
Tying something as vital as email to this Rube Goldberg machine made me
nervous. Access to my email depended on a number of independent systems
of various levels of stability to mostly work correctly. My switch to
Mutt cut this down to just a couple of very stable systems.
format=flowed
I’ve long believed HTML email is an abomination that should never have
been invented. Text is the ideal format for email, and there are a
number of specifications to make it work well across different systems.
One of those standards is RFC 3676, colloquially named
format=flowed, or just f=f.
Messages encoded with f=f allow mail clients to safely reflow the
paragraphs to nicely fit the user’s display, whether that display be
thinner or wider than the sender’s original message. It’s also
completely compatible with mail clients that don’t understand
format=flowed, which will display the message as the sender originally
wrapped it.
The gist of f=f is that messages can have both “soft” and “hard” line
breaks. If a line ends with a space, then it’s a soft line break. The
mail client can safely reflow lines separated by a soft line break.
Without the trailing space, it’s a hard line break, which prohibits
flowing with the next line. The last line of a paragraph ends with a
hard line break. It’s also used for text that shouldn’t reflow, such as
code samples.
I’ll illustrate using an underscore in place of a space, so that you can
see it:
This is a message in the format=flowed style, allowing_
mail clients to flow this message nicely in displays of_
different widths.
> This is an example of a quote block in a message,_
> which is supported by the format=flowed specification.
>> It also supports nested quote blocks, which means_
>> this paragraph won't flow into the previous.
The RFC covers edge cases that require special “space-stuffing” rules,
but, when editing a text email in an editor, you only need to think
about soft and hard line breaks. In my case, Mutt takes care of the rest
of the details.
First, I tell Mutt that I want to use f=f in my .muttrc:
set text_flowed
Then in Vim, I add the w flag to formatoptions, which tells it to
wrap paragraphs using soft line breaks.
set fo+=w
If I want to inspect my f=f formatting, I temporarily enable the list
option, which displays a $ for all newlines.
set list
Although few people would notice a difference, I feel a little bad for
not using f=f all these years! A few people may have endured some
ugly, non-flowing emails from me. My only condolance is that at least it
wasn’t HTML.
It’s not all roses, though. When I reply to a message, Mutt doesn’t
insert the quoted text as f=f into my reply, so I have to massage it
into f=f myself. Also, just as GitHub doesn’t support Markdown in email
responses, neither does it support f=f. When I reply to issues by email,
GitHub won’t nicely reflow my carefully crafted f=f message, needlessly
making email responses an inferior option.
Features unneeded
One reason I didn’t choose this particular email arrangement 4 years ago
was that PGP support was one of my prime requirements. Mutt has solid
PGP support, but, with a Maildir setup (i.e. not IMAP), I’d have to use
the key on the server, which was out of the question. Since I no longer
care about PGP, my email requirements are more relaxed.
Over the years wasn’t making much use of Notmuch’s tagging system. I
only used two tags: “unread” and “inbox” (e.g. read, but still needs
attention). Otherwise I’d use Notmuch’s powerful search to find what I
wanted. I still needed to keep track of the tags I was using, so the
Notmuch index, nearly as large as the email messages themselves, became
part of my mail backup.
The Maildir format itself supports some flags: passed (P),
replied (R), seen (S), trashed (T), draft (D), and flagged (F). These
are stored in the message’s filename. In my new configuration, the
“seen” tag (inversely) takes the place of Notmuch’s “unread” tag. The
“flagged” tag takes place of the “inbox” tag. Normally in Mutt you’d use
mailboxes — i.e. Maildir subdirectories — for something like this, but I
prefer all my mail to sit in one big bucket. Search, don’t sort.
Since the two flags are part of the filename, I no longer need to
include a tag database (i.e. the entire Notmuch index) in the backup,
and my mail backups are much smaller. I could continue to use Notmuch
for searching, but I’ve settled on mu instead. When I perform a search,
mu writes the results to a temporary Maildir using symbolic links, which
I visit with Mutt. The mu index is transient and doesn’t need to be
backed up.
Mu also manages my contacts alias list. It can produce a Mutt-style
alias file based on the contents of my Maildir:
mu cfind --format=mutt-alias > aliases
It’s been really nice to have all my email sitting around as nothing
more than a big pile of files like this. I’ve begun writing little
scripts to harvest data from it, too.
Configuration files
As with all my personal configuration files, you can see my .muttrc
online. The first few weeks I was tweaking this file hourly,
but I’ve now got it basically the way I want.
I recently learned how to use BeautifulSoup, a Python library for
manipulating HTML and XML parse trees, and it’s been a fantastic
addition to my virtual toolbelt. In the past when I’ve needed to process
raw HTML, I’ve tried nasty hacks with Unix pipes, or routing the
content through a web browser so that I could manipulate it via
the DOM API. None of that worked very well, but now I finally have
BeautifulSoup to fill that gap. It’s got a selector interface and,
except for rendering, it’s basically as comfortable with HTML as
JavaScript.
Today’s problem was that I wanted to read a recommended online
book called Interviewing Leather, a story set “in a world where
caped heroes fight dastardly villains on an everyday basis.” I say
“online book” because the 39,403 word story is distributed as a series
of 14 blog posts. I’d rather not read it on the website in a browser,
instead preferring it in e-book form where it’s more comfortable. The
last time I did this, I manually scraped the entire book into
Markdown, spent a couple of weeks editing it for mistakes, and finally
sent the Markdown to Pandoc to convert into an e-book.
For this book, I just want a quick-and-dirty scrape in order to shift
formats. I’ve never read it and I may not even like it (update: I
enjoyed it), so I definitely don’t want to spend much time on the
conversion. Despite having fun with typing lately, I’d also
prefer to keep all the formating — italics, etc. — without re-entering
it all manually.
Fortunately Pandoc can consume HTML as input, so, in theory, I can feed
it the original HTML and preserve all of the original markup. The
challenge is that the HTML is spread across 14 pages surrounded by all
the expected blog cruft. I need some way to extract the book content
from each page, concatenate it together along with chapter headings, and
send the result to Pandoc. Enter BeautifulSoup.
First, I need to construct the skeleton HTML document. Rather than code
my own HTML, I’m going to build it with BeautifulSoup. I start by
creating a completely empty document and adding a doctype to it.
Next I create the html root element, then add the head and body
elements. I also add a title element. The original content has fancy
Unicode markup — left and right quotation marks, em dash, etc. — so it’s
important to declare the page as UTF-8, since otherwise these characters
are likely to be interpreted incorrectly. It always feels odd declaring
the encoding within the content being encoded, but that’s just the way
things are.
Next, I assemble a list of the individual blog posts. When I was
actually writing the script, I first downloaded them locally with my
favorite download tool, curl, and ran the script against local
copies. I didn’t want to hit the web server each time I tested. (Note:
I’ve truncated these URLs to fit in this article.)
I visit a few of these pages in my browser to determine which part of
the page I want to extract. I want to look closely enough to see what
I’m doing, but not too closely as to not spoil myself! Right clicking
the content in the browser and selecting “Inspect Element” (Firefox) or
“Inspect” (Chrome) pops up a pane to structurally navigate the page.
“View Page Source” would work, too, especially since this is static
content, but I find the developer pane easier to read. Plus it hides
most of the content, revealing only the structure.
The content is contained in a div with the class entry-content. I
can use a selector to isolate this element and extract its child p
elements. However, it’s not quite so simple. Each chapter starts with a
bit of commentary that’s not part of the book, and I don’t want to
include in my extract. It’s separated from the real content by an hr
element. There’s also a footer below another hr element, likely put
there by someone who wasn’t paying attention to the page structure. It’s
not quite the shining example of semantic markup, but it’s regular
enough I can manage.
<body><mainclass="site-main"><divclass="entry-body"><divclass="entry-content"><p>A little intro.</p><p>Some more intro.</p><hr/><p>Actual book content.</p><p>More content.</p><hr/><p>Footer navigation junk.</p></div></div></main></body>
The next step is visiting each of these pages. I use enumerate since I
want the chapter numbers when inserting h1 chapter elements. Pandoc
will use these to build the table of contents.
fori,chapterinenumerate(chapters):# Construct h1 for the chapterheader=doc.new_tag('h1')header.string='Chapter %d'%(i+1,)body.append(header)
Next grab the page content using urllib and parse it with
BeautifulSoup. I’m using a selector to locate the div with the
book content.
Finally I iterate over the child elements of the div.entry-content
element. I keep a running count of the hr element and only extract
content when we’ve seen exactly one hr element.
# Append content between hr elementshr_count=0forchildincontent.children:if(child.name=='hr'):hr_count+=1elif(child.name=='p'andhr_count==1):child.attrs={}if(child.string=='#'):body.append(doc.new_tag('hr'))else:body.append(child)
If it’s a p element, I copy it into the output document, taking a
moment to strip away any attributes present on the p tag, since, for
some reason, some of these elements have old-fashioned alignment
attributes in the original content.
The original content also uses the text “#” by itself in a p to
separate sections rather than using the appropriate markup. Despite
being semantically incorrect, I’m thankful for this since more hr
elements would have complicated matters further. I convert these to the
correct markup for the final document.
A brief inspection with a browser indicates that everything seems to
have come out correctly. I won’t know for sure, though, until I actually
read through the whole book. Finally I have Pandoc perform the
conversion.
$ pandoc -t epub3 -o output.epub output.html
And that’s it! It’s ready to read offline in my e-book reader of
choice. The crude version of my script took around 15–20 minutes to
write and test, so I had an e-book conversion in under 30 minutes.
That’s about as long as I was willing to spend to get it. Tidying the
script up for this article took a lot longer.
I don’t have permission to share the resulting e-book, but I can share
my script so that you can generate your own, at least as long as it’s
hosted at the same place with the same structure.
When coding against a standard, whether it’s a programming
language specification or an open API with multiple vendors, a common
concern is the conformity of a particular construct to the standard.
This cannot be determined simply by experimentation, since a piece of
code may work correctly due only to the specifics of a particular
implementation. It works today with this implementation, but it
may not work tomorrow or with a different implementation.
Sometimes an implementation will warn about the use of non-standard
behavior, but this isn’t always the case.
When I’m reasoning about whether or not something is allowed, I like to
imagine an adversarial implementation. If the standard allows some
freedom, this implementation takes an imaginative or unique approach. It
chooses non-obvious interpretations with possibly unexpected,
but valid, results. This is nearly the opposite of djb’s hypothetical
boringcc, though some of the ideas are similar.
Many argue that this is already the case with modern C and C++
optimizing compilers. Compiler writers are already creative with the
standard in order to squeeze out more performance, even if it’s
at odds with the programmer’s actual intentions. The most prominent
example in C and C++ is strict aliasing, where the optimizer is
deliberately blinded to certain kinds of aliasing because the standard
allows it to be, eliminating some (possibly important) loads. This
happens despite the compiler’s ability to trivially prove that two
particular objects really do alias.
I want to be clear that I’m not talking about the nasal daemon
kind of creativity. That’s not a helpful thought experiment. What I
mean is this: Can I imagine a conforming implementation that breaks
any assumptions made by the code?.
In practice, compilers typically have to bridge multiple
specifications: the language standard, the platform ABI, and
operating system interface (process startup, syscalls, etc.). This
really ties its hands on how creative it can be with any one of the
specifications. Depending on the situation, the imaginary adversarial
implementation isn’t necessarily running on any particular platform.
If our program is expected to have a long life, useful for many years
to come, we should avoid making too many assumptions about future
computers and imagine an adversarial compiler with few limitations.
C example
Take this bit of C:
printf("%d",sizeof(foo));
The printf function is variadic, and it relies entirely on the format
string in order to correctly handle all its arguments. The %d
specifier means that its matching argument is of type int. The result
of the sizeof operator is an integer of type size_t, which has a
different sign and may even be a different size.
Typically this code will work just fine. An int and size_t are
generally passed the same way, the actual value probably fits in an
int, and two’s complement means the signedness isn’t an issue due to
the value being positive. From the printf point of view, it
typically can’t detect that the type is wrong, so everything works by
chance. In fact, it’s hard to imagine a real situation where this
wouldn’t work fine.
However, this still undefined behavior — a scenario where a creative
adversarial implementation can break things. In this case there are a
few options for an adversarial implementation:
Arguments of type int and size_t are passed differently, so
printf will load the argument it from the wrong place.
The implementation doesn’t use two’s complement and even small
positive values have different bit representations.
The type of foo is given crazy padding for arbitrary reasons that
makes it so large it doesn’t fit in an int.
What’s interesting about #1 is that this has actually happened. For
example, here’s a C source file.
floatfoo(intx,inty){(void)x;// ignore x
returny*2.0f;}
The type of argument x differs between the prototype and the
definition, which is undefined behavior. However, since this argument
is ignored, this code will still work correctly on many different
real-world computers, particularly where float and int arguments
are passed the same way (i.e. on the stack).
However, in 2003 the x86-64 CPU arrived with its new System V ABI.
Floating point and integer arguments were now passed differently, and
the types of preceding arguments mattered when deciding which register
to use. Some constructs that worked fine, by chance, prior to 2003 would
soon stop working due to what may have seemed like an adversarial
implementation years before.
Python example
Let’s look at some Python. This snippet opens a file a million times
without closing any handles.
foriinrange(1,1000000):f=open("/dev/null","r")
Assuming you have a /dev/null, this code will work fine without
throwing any exceptions on CPython, the most widely used Python
implementation. CPython uses a deterministic reference counting scheme,
and the handle is automatically closed as soon as its variable falls out
of scope. It’s like having an invisible f.close() at the end of the
block.
However, this code is incorrect. The deterministic handle closing an
implementation behavior, not part of the specification. The
operating system limits the number of files a process can have open at
once, and there’s a risk that this resource will run out even though
none of those handles are reachable. Imagine an adversarial Python
implementation trying to break this code. It could sufficiently delay
garbage collection, or even have infinite memory, omitting
garbage collection altogether.
Like before, such an implementation eventually did come about: PyPy, a
Python implementation written in Python with a JIT compiler. It uses (by
default) something closer to mark-and-sweep, not reference counting, and
those handles are left open until the next collection.
>>>> for i in range(1, 1000000):
.... f = open("/dev/null", "r")
....
Traceback (most recent call last):
File "<stdin>", line 2, in <module>
IOError: [Errno 24] Too many open files: '/dev/null'
A tool for understanding specifications
This fits right in with a broader method of self-improvement:
Occasionally put yourself in the implementor’s shoes. Think about what
it would take to correctly implement the code that you write, either
as a language or the APIs that you call. On reflection, you may find
that some of those things that seem cheap may not be. Your
assumptions may be reasonable, but not guaranteed. (Though it may be
that “reasonable” is perfectly sufficient for your situation.)
An adversarial implementation is one that challenges an assumption
you’ve taken for granted by turning it on its head.
