This project contains two programs:
blink
is a virtual machine that runs x86-64-linux programs on
different operating systems and hardware architectures. It's designed to
do the same thing as the qemu-x86_64
command, except that
-
Blink is 221kb in size (115kb with optional features disabled), whereas qemu-x86_64 is a 4mb binary.
-
Blink will run your Linux binaries on any POSIX system, whereas qemu-x86_64 only supports Linux.
-
Blink goes 2x faster than qemu-x86_64 on some benchmarks, such as SSE integer / floating point math. Blink is also much faster at running ephemeral programs such as compilers.
blinkenlights
is a terminal user
interface that may be used for debugging x86_64-linux or i8086 programs
across platforms. Unlike GDB, Blinkenlights focuses on visualizing
program execution. It uses UNICODE IBM Code Page 437 characters to
display binary memory panels, which change as you step through your
program's assembly code. These memory panels may be scrolled and zoomed
using your mouse wheel. Blinkenlights also permits reverse debugging,
where scroll wheeling over the assembly display allows the rewinding of
execution history.
We regularly test that Blink is able run x86-64-linux binaries on the following platforms:
- Linux (x86, ARM, RISC-V, MIPS, PowerPC, s390x)
- macOS (x86, ARM)
- FreeBSD
- OpenBSD
- Cygwin
Blink depends on the following libraries:
- libc (POSIX.1-2017 with XSI extensions)
Blink can be compiled on UNIX systems that have:
- A C11 compiler with atomics (e.g. GCC 4.9.4+)
- Modern GNU Make (i.e. not the one that comes with XCode)
The instructions for compiling Blink are as follows:
./configure
make -j4
doas make install # note: doas is modern sudo
blink -v
man blink
Here's how you can run a simple hello world program with Blink:
blink third_party/cosmo/tinyhello.elf
Blink has a debugger TUI, which works with UTF-8 ANSI terminals. The
most important keystrokes in this interface are ?
for help, s
for
step, c
for continue, and scroll wheel for reverse debugging.
blinkenlights third_party/cosmo/tinyhello.elf
For maximum tinyness, use MODE=tiny
, since it makes Blink's binary
footprint 50% smaller. The Blink executable should be on the order of
200kb in size. Performance isn't impacted. Please note that all
assertions will be removed, as well as all logging. Use this mode if
you're confident that Blink is bug-free for your use case.
make MODE=tiny
strip o/tiny/blink/blink
ls -hal o/tiny/blink/blink
Some distros configure their compilers to add a lot of security bloat, which might add 60kb or more to the above binary size. You can work around that by using one of Blink's toolchains. This should produce consistently the smallest possible executable size.
make MODE=tiny o/tiny/x86_64/blink/blink
o/third_party/gcc/x86_64/bin/x86_64-linux-musl-strip o/tiny/x86_64/blink/blink
ls -hal o/tiny/x86_64/blink/blink
If you want to make Blink even tinier (more on the order of 120kb
rather than 200kb) than you can tune the ./configure
script to disable
optional features such as jit, threads, sockets, x87, bcd, xsi, etc.
./configure --disable-all --posix
make MODE=tiny o/tiny/x86_64/blink/blink
o/third_party/gcc/x86_64/bin/x86_64-linux-musl-strip o/tiny/x86_64/blink/blink
ls -hal o/tiny/x86_64/blink/blink
The traditional MODE=rel
or MODE=opt
modes are available. Use this
mode if you're on a non-JIT architecture (since this won't improve
performance on AMD64 and ARM64) and you're confident that Blink is
bug-free for your use case, and would rather have Blink not create a
blink.log
or print SIGSEGV
delivery warnings to standard error,
since many apps implement their own crash reporting.
make MODE=rel
o/rel/blink/blink -h
You can hunt down bugs in Blink using the following build modes:
MODE=asan
helps find memory safety bugsMODE=tsan
helps find threading related bugsMODE=ubsan
to find violations of the C standardMODE=msan
helps find uninitialized memory errors
You can check Blink's compliance with the POSIX standard using the following configuration flags:
./configure --posix # only use c11 with posix xopen standard
If you want to run a full chroot
'd Linux distro and require correct
handling of absolute symlinks, displaying of certain values in /proc
,
and so on, and you don't mind paying a small price in terms of size
and performance, you can enable the emulated VFS feature by using
the following configuration:
./configure --enable-vfs
Blink is tested primarily using precompiled binaries downloaded automatically. Blink has more than 700 test programs total. You can check how well Blink works on your local platform by running:
make check
To check that Blink works on 11 different hardware $(ARCHITECTURES)
(see Makefile), you can run the following command, which
will download statically-compiled builds of GCC and Qemu. Since our
toolchain binaries are intended for x86-64 Linux, Blink will bootstrap
itself locally first, so that it's possible to run these tests on other
operating systems and architectures.
make check2
make emulates
Blink passes 194 test suites from the Cosmopolitan Libc project (see third_party/cosmo). Blink passes 350 test suites from the Linux Test Project (see third_party/ltp). Blink passes 108 of Musl Libc's unit test suite (see third_party/libc-test). The tests we haven't included are because either (1) it wanted x87 long double to have 80-bit precision, or (2) it used Linux APIs we can't or won't support, e.g. System V message queues. Blink runs the precompiled Linux test binaries above on other operating systems too, e.g. Apple M1, FreeBSD, Cygwin.
The Blinkenlights project provides two programs which may be launched on the command line.
The headless Blinkenlights virtual machine command (named blink
by
convention) accepts command line arguments per the specification:
blink [FLAG...] PROGRAM [ARG...]
Where PROGRAM
is an x86_64-linux binary that may be specified as:
- An absolute path to an executable file, which will be run as-is
- A relative path containing slashes, which will be run as-is
- A path name without slashes, which will be
$PATH
searched
The following FLAG
arguments are provided:
-
-h
shows help on command usage -
-v
shows version and build configuration details -
-e
means log to standard error (fd 2) in addition to the log file. If logging to only standard error is desired, then-eL/dev/null
may be used. -
-j
disables Just-In-Time (JIT) compilation, which will make Blink go ~10x slower. -
-m
disables the linear memory optimization. This makes Blink memory safe, but comes at the cost of going ~4x slower. On some platforms this can help avoid the possibility of an mmap() crisis. -
-0
allowsargv[0]
to be specified on the command line. Under normal circumstances,blink cmd arg1
is equivalent toexecve("cmd", {"cmd", "arg1"})
since that's how most programs are launched. However if you need the full power of execve() process spawning, you can sayblink -0 cmd arg0 arg1
which is equivalent toexecve("cmd", {"arg0", "arg1"})
. -
-L PATH
specifies the log path. The default log path isblink.log
in the current directory at startup. This log file won't be created until something is actually logged. If logging to a file isn't desired, then-L /dev/null
may be used. See also the-e
flag for logging to standard error. -
-s
enables system call logging. This will emit to the log file the names of system calls each time a SYSCALL instruction in executed, along with its arguments and result. System calls are logged once they've completed. If this option is specified twice, then system calls which are likely to block (e.g. poll) will be logged at entry too. If this option is specified thrice, then all cancellation points will be logged upon entry. System call logging isn't available inMODE=rel
andMODE=tiny
builds, in which case this flag is ignored. -
-Z
will cause internal statistics to be printed to standard error on exit. Stats aren't available inMODE=rel
andMODE=tiny
builds, and this flag is ignored. -
-C path
will cause blink to launch the program in a chroot'd environment. This flag is both equivalent to and overrides theBLINK_OVERLAYS
environment variable. Note: This flag works especially well if you use./configure --enable-vfs
.
The Blinkenlights ANSI TUI interface command (named blinkenlights
by
convention) accepts its command line arguments in accordance with the
following specification:
blinkenlights [FLAG...] PROGRAM [ARG...]
Where PROGRAM
is an x86_64-linux binary that may be specified as:
- An absolute path to an executable file, which will be run as-is
- A relative path containing slashes, which will be run as-is
- A path name without slashes, which will be
$PATH
searched
The following FLAG
arguments are provided:
-
-h
shows help on command usage -
-v
shows version and build configuration details -
-r
puts your virtual machine in real mode. This may be used to run 16-bit i8086 programs, such as SectorLISP. It's also used for booting programs from Blinkenlights's simulated BIOS. -
-b ADDR
pushes a breakpoint, which may be specified as a raw hexadecimal address, or a symbolic name that's defined by your ELF binary (or its associated.dbg
file). When pressingc
(continue) orC
(continue harder) in the TUI, Blink will immediately stop upon reaching an instruction that's listed as a breakpoint, after which a modal dialog is displayed. The modal dialog may be cleared byENTER
after which the TUI resumes its normal state. -
-w ADDR
pushes a watchpoint, which may be specified as a raw hexadecimal address, or a symbolic name that's defined by your ELF binary (or its associated.dbg
file). When pressingc
(continue) orC
(continue harder) in the TUI, Blink will immediately stop upon reaching an instruction that either (a) has a ModR/M encoding that references an address that's listed as a watchpoint, or (b) manages to mutate the memory stored at a watchpoint address by some other means. When Blinkenlights is stopped at a watchpoint, a modal dialog will be displayed which may be cleared by pressingENTER
, after which the TUI resumes its normal state. -
-j
enables Just-In-Time (JIT) compilation. This will make Blinkenlights go significantly faster, at the cost of taking away the ability to step through each instruction. The TUI will visualize JIT path formation in the assembly display; see the JIT Path Glyphs section below to learn more. Please note this flag has the opposite meaning as it does in theblink
command. -
-m
enables the linear memory optimization. This makes blinkenlights capable of faster emulation, at the cost of losing some statistics. It no longer becomes possible to display which percentage of a memory map has been activated. Blinkenlights will also remove the commit / reserve / free page statistics from the status panel on the bottom right of the display. Please note this flag has the opposite meaning as it does in theblink
command. -
-t
may be used to disable Blinkenlights TUI mode. This makes the program behave similarly to theblink
command, however not as good. We're currently using this flag for unit testing real mode programs, which are encouraged to use theSYSCALL
instruction to report their exit status. -
-L PATH
specifies the log path. The default log path is$TMPDIR/blink.log
or/tmp/blink.log
if$TMPDIR
isn't defined. -
-C path
will cause blink to launch the program in a chroot'd environment. This flag is both equivalent to and overrides theBLINK_OVERLAYS
environment variable. -
-s
enables system call logging. This will emit to the log file the names of system calls each time a SYSCALL instruction in executed, along with its arguments and result. System calls are logged once they've completed. If this option is specified twice, then system calls which are likely to block (e.g. poll) will be logged at entry too. If this option is specified thrice, then all cancellation points will be logged upon entry. System call logging isn't available inMODE=rel
andMODE=tiny
builds, in which case this flag is ignored. -
-Z
will cause internal statistics to be printed to standard error on exit. Each line will display a monitoring metric. Most metrics will either be integer counters or floating point running averages. Most but not all integer counters are monotonic. In the interest of not negatively impacting Blink's performance, statistics are computed on a best effort basis which currently isn't guaranteed to be atomic in a multi-threaded environment. Stats aren't available inMODE=rel
andMODE=tiny
builds, and this flag is ignored. -
-z
[repeatable] may be specified to zoom the memory panels, so they display a larger amount of memory in a smaller space. By default, one terminal cell corresponds to a single byte of memory. When memory has been zoomed the magic kernel is used (similar to Lanczos) to decimate the number of bytes by half, for each-z
that's specified. Normally this would be accomplished by usingCTRL+MOUSEWHEEL
where the mouse cursor is hovered over the panel that should be zoomed. However, many terminal emulators (especially on Windows), do not support this xterm feature and as such, this flag is provided as an alternative. -
-V
[repeatable] increases verbosity -
-R
disables reactive error mode -
-H
disables syntax highlighting -
-N
enables natural scrolling
Blinkenlights' TUI requires a UTF-8 VT100 / XTERM style terminal to use. We recommend the following terminals, ordered by preference:
- KiTTY (Linux)
- PuTTY (Windows)
- Gnome Terminal (Linux)
- Terminal.app (macOS)
- CMD.EXE (Windows 10+)
- PowerShell (Windows 10+)
- Xterm (Linux)
The following fonts are recommended, ordered by preference:
- PragmataPro Regular Mono (€59)
- Bitstream Vera Sans Mono (a.k.a. DejaVu Sans Mono)
- Consolas
- Menlo
When the Blinkenlights TUI is run with JITing enabled (using the -j
flag) the assembly dump display will display a glyph next to the address
of each instruction, to indicate the status of JIT path formation. Those
glyphs are defined as follows:
-
-
S
means that a JIT path is currently being constructed which starts at this address. By continuing to presss
(step) in the TUI interface, the JIT path will grow longer until it is eventually completed, and theS
glyph is replaced by*
. -
*
(asterisk) means that a JIT path has been installed to the adjacent address. Whens
(step) is pressed at such addresses within the TUI display, stepping takes on a different meaning. Rather than stepping a single instruction, it will step the entire length of the JIT path. The next assembly line that'll be highlighted will be the instruction after where the path ends.
The following environment variables are recognized by both the blink
and blinkenlights
commands:
-
BLINK_LOG_FILENAME
may be specified to supply a log path to be used in cases where the-L PATH
flag isn't specified. This value should be an absolute path. If logging to standard error is desired, use theblink -e
flag. -
BLINK_OVERLAYS
specifies one or more directories to use as the root filesystem. Similar to$PATH
this is a colon delimited list of pathnames. If relative paths are specified, they'll be resolved to an absolute path at startup time. Overlays only apply to IO system calls that specify an absolute path. The empty string overlay means use the normal/
root filesystem. The default value is:o
, which means if the absolute path/$f
is opened, then first check if/$f
exists, and if it doesn't, then check ifo/$f
exists, in which case open that instead. Blink uses this convention to open shared object tests. It favors the system version if it exists, but also downloadsld-musl-x86_64.so.1
too/lib/ld-musl-x86_64.so.1
so the dynamic linker can transparently find it on platforms like Apple, that don't let users put files in the root folder. On the other hand, it's possible to sayBLINK_OVERLAYS=o:
so thato/...
takes precedence over/...
(noting again that empty string means root). If a single overlay is specified that isn't empty string, then it'll effectively act as a restricted chroot environment.
Blink can be picky about which Linux binaries it'll execute. It may also be the case that your Linux binary will only run under Blink on Linux, but report errors if run under Blink on another platform, e.g. macOS. In our experience, how successfully a program can run under Blink depends almost entirely on (1) how it was compiled, and (2) which C library it uses. This section will provide guidance on which tools will work best.
First, some background. Blink's coverage of the x86_64 instruction set
is comprehensive. However the Linux system call ABI is much larger and
therefore not possible to fully support, unless Blink emulated a Linux
kernel image too. Blink has sought to support the subset of Linux ABIs
that are either (1) standardized by POSIX.1-2017 or (2) too popular to
not support. As an example, AF_INET
, AF_UNIX
, and AF_INET6
are
supported, but Blink will return EINVAL
if a program requests any of
the dozens of other ones, e.g. AF_BLUETOOTH
. Such errors are usually
logged to /tmp/blink.log
, to make it easy to file a feature request.
In other cases ABIs aren't supported simply because they're Linux-only
and difficult to polyfill on other POSIX platforms. For example, Blink
will polyfill open(O_TMPFILE)
on non-Linux platforms so it works the
same way, but other Linux-specific ABIs like membarrier()
we haven't
had the time to figure out yet. Since app developers usually don't use
non-portable APIs, it's usually the platform C library that's at fault
for calling them. Many Linux system calls, could be rightfully thought
of as an implementation detail of Glibc.
Blink's prime directive is to support binaries built with Cosmopolitan Libc. Actually Portable Executables make up the bulk of Blink's unit test suite. Anything created by Cosmopolitan is almost certainly going to work very well. Since Cosmopolitan is closely related to Musl Libc, programs compiled using Musl also tend to work very well. For example, Alpine Linux is a Musl Libc based distro, so their prebuilt dynamic binaries tend to all work well, and it's also a great platform to use for compiling other software from source that's intended for Blink.
So the recommended approach is either:
- Build your app using Cosmopolitan Libc, otherwise
- Build your app using GNU Autotools on Alpine Linux
- Build your app using Buildroot
For Cosmopolitan, please read Getting Started with Cosmopolitan Libc for information on how to get started. Cosmopolitan comes with a lot of third party software included that you can try with Blink right away, e.g. SQLite, Python, QuickJS, and Antirez's Kilo editor.
git clone https://github.com/jart/cosmopolitan/
cd cosmopolitan
make -j8 o//third_party/python/python.com
blinkenlights -jm o//third_party/python/python.com
make -j8 o//third_party/quickjs/qjs.com
blinkenlights -jm o//third_party/quickjs/qjs.com
make -j8 o//third_party/sqlite3/sqlite3.com
blinkenlights -jm o//third_party/sqlite3/sqlite3.com
make -j8 o//examples/kilo.com
blinkenlights -jm o//examples/kilo.com
Blink is great for making single-file autonomous binaries like the above
easily copyable across platforms. If you're more interested in building
systems instead, then Buildroot is one way to
create a Linux userspace that'll run under Blink. All you have to do is
set the $BLINK_OVERLAYS
environment variable to the buildroot target
folder, which will ask Blink to create a chroot'd environment.
cd ~/buildroot
export CC="gcc -Wl,-z,common-page-size=65536,-z,max-page-size=65536"
make menuconfig
make
cp -R output/target ~/blinkroot
doas mount -t devtmpfs none ~/blinkroot/dev
doas mount -t sysfs none ~/blinkroot/sys
doas mount -t proc none ~/blinkroot/proc
cd ~/blink
make -j8
export BLINK_OVERLAYS=$HOME/blinkroot
blink sh
uname -a
Linux hostname 4.5 blink-1.0 x86_64 GNU/Linux
If you want to build an Autotools project like Emacs, the best way to do that is to spin up an Alpine Linux container and use jart/blink-isystem as your system header subset. blink-isystem is basically just the Musl Linux headers with all the problematic APIs commented out. That way autoconf won't think the APIs Blink doesn't have are available, and will instead configure Emacs to use portable alternatives. Setting this up is simple:
./configure CFLAGS="-isystem $HOME/blink-isystem" \
CXXFLAGS="-isystem $HOME/blink-isystem" \
LDFLAGS="-static -Wl,-z,common-page-size=65536,-z,max-page-size=65536"
make -j
Another big issue is the host system page size may cause problems on non-Linux platforms like Apple M1 (16kb) and Cygwin (64kb). On such platforms, you may encounter an error like this:
p_vaddr p_offset skew unequal w.r.t. host page size
The simplest way to solve that is by disabling the linear memory
optimization (using the blink -m
flag) but that'll slow down
performance. Another option is to try recompiling your executable so
that its ELF program headers will work on systems with a larger page
size. You can do that using these GCC flags:
gcc -static -Wl,-z,common-page-size=65536,-z,max-page-size=65536 ...
However that's just step one. The program also needs to be using APIs
like sysconf(_SC_PAGESIZE)
which will return the true host page size,
rather than naively assuming it's 4096 bytes. Your C library gets this
information from Blink via getauxval(AT_PAGESZ)
.
If you're using the Blinkenlights debugger TUI, then another important set of flags to use are the following:
-fno-omit-frame-pointer
-mno-omit-leaf-frame-pointer
By default, GCC and Clang use the %rbp
backtrace pointer as a general
purpose register, and as such, Blinkenlights won't be able to display a
frames panel visualizing your call stack. Using those flags solves that.
However it's tricky sometimes to correctly specify them in a complex
build environment, where other optimization flags might subsequently
turn them back off again.
The trick we recommend using for compiling your programs, is to create a
shell script that wraps your compiler command, and then use the script
in your $CC
environment variable. The script should look something
like the following:
#!/bin/sh
set /usr/bin/gcc "$@" -g \
-fno-omit-frame-pointer \
-fno-optimize-sibling-calls \
-mno-omit-leaf-frame-pointer \
-Wl,-z,norelro \
-Wl,-z,noseparate-code \
-Wl,-z,max-page-size=65536 \
-Wl,-z,common-page-size=65536
printf '%s\n' "$*" >>/tmp/gcc.log
exec "$@"
Those flags will go a long way towards helping your Linux binaries be (1) capable of running under Blink on all of its supported operating systems and microprocessor architectures, and (2) trading away some of the modern security blankets in the interest of making the assembly panel more readable, and less likely to be picky about memory.
If you're a Cosmopolitan Libc user, then Cosmopolitan already provides
such a script, which is the cosmocc
and cosmoc++
toolchain. Please
note that Cosmopolitan Libc uses a 64kb page size so it isn't impacted
by many of these issues that Glibc and Musl users may experience.
If you're not a C / C++ developer, and you prefer to use high-level languages instead, then one program you might consider emulating is Actually Portable Python, which is an APE build of the CPython v3.6 interpreter. It can be built from source, and then used as follows:
git clone https://github.com/jart/cosmopolitan/
cd cosmopolitan
make -j8 o//third_party/python/python.com
blinkenlights -jm o//third_party/python/python.com
The -jm
flags are helpful here, since they ask the Blinkenlights TUI
to enable JIT and the linear memory optimization. It's helpful to have
those flags because Python is a very complicated and compute intensive
program, that would otherwise move too slowly under the Blinkenlights
vizualization. You may also want to press the CTRL-T
(TURBO) key a few
times, to make Python emulate in the TUI even faster.
blink is an x86-64 interpreter for POSIX platforms that's written in ANSI C11 that's compatible with C++ compilers. Instruction decoding is done using our trimmed-down version of Intel's disassembler Xed.
The prime directive of this project is to act as a virtual machine for
userspace binaries compiled by Cosmopolitan Libc. However we've also had
success virtualizing programs compiled with Glibc and Musl Libc, such as
GCC and Qemu. Blink supports 500+ instructions and 150+ Linux syscalls,
including fork() and clone(). Linux system calls may only be used by
long mode programs via the SYSCALL
instruction, as it is written in
the System V ABI.
The following hardware ISAs are supported by Blink.
- i8086
- i386
- X87
- SSE2
- x86_64
- SSE3
- SSSE3
- CLMUL
- POPCNT
- ADX
- BMI2
- RDRND
- RDSEED
- RDTSCP
Programs may use CPUID
to confirm the presence or absence of optional
instruction sets. Please note that Blink does not follow the same
monotonic progress as Intel's hardware. For example, BMI2 is supported;
this is an AVX2-encoded (VEX) instruction set, which Blink is able to
decode, even though the AVX2 ISA isn't supported. Therefore it's
important to not glob ISAs into "levels" (as Windows software tends to
do) where it's assumed that BMI2 support implies AVX2 support; because
with Blink that currently isn't the case.
On the other hand, Blink does share Windows' x87 behavior w.r.t. double
(rather than long double) precision. It's not possible to use 80-bit
floating point precision with Blink, because Blink simply passes along
floating point operations to the host architecture, and very few
architectures support long double
precision. You can still use x87
with 80-bit words. Blink will just store 64-bit floating point values
inside them, and that's a legal configuration according to the x87 FPU
control word. If possible, it's recommended that long double
simply be
avoided. If 64-bit floating point is good enough for the rocket
scientists at
NASA
then it should be good enough for everybody. There are some peculiar
differences in behavior with double
across architectures (which Blink
currently does nothing to address) but they tend to be comparatively
minor, e.g. an op returning NAN
instead of -NAN
.
Blink has reasonably comprehensive coverage of the baseline ISAs,
including even support for BCD operations (even in long mode!). But there
are some truly fringe instructions Blink hasn't implemented, such as
BOUND
and ENTER
. Most of the unsupported instructions, are usually
ring-0 system instructions, since Blink is primarily a user-mode VM, and
therefore only has limited support for bare metal operating system
software (which we'll discuss more in-depth in a later section).
Blink advertises itself as Linux 4.5
in the uname()
system call and
uname -v
will report blink-1.0
. Programs may detect they're running
in Blink by issuing a CPUID
instruction where EAX
is set to the leaf
number:
-
Leaf
0x0
(or0x80000000
) reportsGenuineIntel
inEBX ‖ EDX ‖ ECX
-
Leaf
0x1
reports that Blink is a hypervisor in bit31
ofECX
-
Leaf
0x40000000
reportsGenuineBlink
as the hypervisor name inEBX ‖ ECX ‖ EDX
-
Leaf
0x40031337
reports the underlying operating system name inEBX ‖ ECX ‖ EDX
with zero filling for strings shorter than 12:Linux
for LinuxXNU
for macOSFreeBSD
for FreeBSDNetBSD
for NetBSDOpenBSD
for OpenBSDLinux
for LinuxCygwin
for Windows under CygwinWindows
for Windows under CosmopolitanUnknown
if compiled on unrecognized platform
-
Leaf
0x80000001
tells if Blink's JIT is enabled in bit31
inECX
Blink uses just-in-time compilation, which is supported on x86_64 and
aarch64. Blink takes the appropriate steps to work around restrictions
relating to JIT, on platforms like Apple and OpenBSD. We generate JIT
code using a printf-style domain-specific language. The JIT works by
generating functions at runtime which call the micro-op functions the
compiler created. To make micro-operations go faster, Blink determines
the byte length of the compiled function at runtime by scanning for a
RET instruction. Blink will then copy the compiled function into the
function that the JIT is generating. This works in most cases, however
some tools can cause problems. For example, OpenBSD RetGuard inserts
static memory relocations into every compiled function, which Blink's
JIT currently doesn't understand; so we need to use compiler flags to
disable that type of magic. In the event other such magic slips through,
Blink has a runtime check which will catch obvious problems, and then
gracefully fall back to using a CALL instruction. Since no JIT can be
fully perfect on all platforms, the blink -j
flag may be passed to
disable Blink's JIT. Please note that disabling JIT makes Blink go 10x
slower. With the blinkenlights
command, the -j
flag takes on the
opposite meaning, where it instead enables JIT. This can be useful for
troubleshooting the JIT, because the TUI display has a feature that lets
JIT path formation be visualized. Blink currently only enables the JIT
for programs running in long mode (64-bit) but we may support JITing
16-bit programs in the future.
Blink virtualizes memory using the same PML4T approach as the hardware
itself, where memory lookups are indirected through a four-level radix
tree. Since performing four separate page table lookups on every memory
access can be slow, Blink checks a translation lookaside buffer, which
contains the sixteen most recently used page table entries. The PML4T
allows all memory lookups in Blink to be "safe" but it still doesn't
offer the best possible performance. Therefore, on systems with a huge
address space (i.e. petabytes of virtual memory) Blink relies on itself
being loaded to a random location, and then identity maps guest memory
using a simple linear translation. For example, if the guest virtual
address is 0x400000
then the host address might be
0x400000+0x088800000000
. This means that each time a memory operation
is executed, only a simple addition needs to be performed. This goes
extremely fast, however it may present issues for programs that use
MAP_FIXED
. Some systems, such as modern Raspberry Pi, actually have a
larger address space than x86-64, which lets Blink offer the guest the
complete address space. However on some platforms, like 32-bit ones,
only a limited number of identity mappings are possible. There's also
compiler tools like TSAN which lay claim to much of the fixed address
space. Blink's solution is designed to meet the needs of Cosmopolitan
Libc, while working around Apple's restriction on 32-bit addresses, and
still remain fully compatible with ASAN's restrictions. In the event
that this translation scheme doesn't work on your system, the blink -m
flag may be passed to disable the linear translation optimization, and
instead use only the memory safe full virtualization approach of the
PML4T and TLB.
Blink stores generated functions by virtual address in a multithreaded
lockless hash table. The hottest operation in the codebase is reading
from this hash table, using a function called GetJitHook
. Since it'd
slow Blink down by more than 33% if a mutex were used here, Blink will
synchronize reads optimistically using only carefully ordered load
instructions, three of which have acquire semantics. This hash table
starts off at a reasonable size and grows gradually with the memory
requirements. This design is the primary reason Blink usually uses 40%
less peak resident memory than Qemu.
Even though JIT paths will always end at branching instructions, Blink will generate code so that paths tail call into each other, in order to avoid dropping back into the main interpreter loop. The average length of a JIT path is about ~5 opcodes. Connecting paths causes the average path length to be ~13 opcodes.
Since Blink only checks for asynchronous signal delivery and shutdown events from the main interpreter loop, Blink maintains a bidirectional map of edges between generated functions, so that path connections which would result in cycles are never introduced.
An exception is made for tight conditional branches, i.e. jumps whose taken path jump backwards to the start of the JIT path. Such branches are allowed to be self-referencing so that whole loops of non-system operations may be run in purely native code.
Blink has a 22mb global static variable that's set aside for JIT code. This limit was chosen because that's roughly the maximum displacement permitted on Arm64 architecture. Having that memory near the program image helps make Blink simpler, since generated functions call normal functions, without needing relocations or procedure linkage tables.
When Blink runs out of JIT memory, it simply clears all JIT hooks and lets the whole code generation process start again. Blink is very fast at generating code, and it wouldn't make sense during an OOM panic to arbitrarily choose a subset of pages to reset, since resetting pages requires tracing their dependencies and resetting those too. Starting over is much better. It's so much better in fact, that even if Blink only reserved less than a megabyte of memory for JIT, then the slowdown that'd be incurred running 40mb binaries like GCC CC1 would only be 3x.
Blink triggers the OOM panic when only 10% of its JIT memory remains. That's because in multi-threaded programs, there's no way to guarantee nothing is still executing on the retired code blocks. Blink solves this by letting retired blocks cool off at the back of a freelist queue, so the acyclicity invariant has abundant time to ensure threads drop out.
Many CPU architectures require esoteric rituals for flushing CPU caches when code modifies itself. That's not the case with x86 architecture, which takes care of this chore automatically. Blink is able to offer the same promises here as Intel and AMD, by abstracting fast and automatic invalidation of caches for programs using self-modifying code (SMC).
When Blink's JIT isn't enabled, self-modifying code always causes instruction caches to be invalidated immediately, at least within the same thread. That's because Blink compares the raw instruction bytes with what's in the instruction cache before fetching its decoded value.
When JITing is enabled, Blink will automatically invalidate JIT memory associated with code that's been modified. This happens on a 4096-byte page granularity. When a function like mprotect() is called that causes memory pages to transition from a non-executable to executable state, the impacted pages will be invalidated by the JIT. The JIT maintains a hash table where the key is the virtual address at which a generated function begins (which we call a "path") and the value is a function pointer to the generated code. When Blink is generating paths, it is careful to ensure that all the guest instructions which are added to a path, only exist within the confines of a single 4096-byte page. Thus when a page needs to be invalidated, Blink simply deletes any hook for each address within the page.
When RWX memory is used, Blink can't rely on mprotect() to communicate the intent of the guest program. What Blink will do instead is protect any RWX guest memory, so that it's registered as read-only in the host operating system. This way, whenever the guest writes to RWX memory, a SIGSEGV signal will be delivered to Blink, which then re-enables write permissions on the impacted RWX page, flips a bit to the thread in the SMC state and then permits execution to resume for at least one opcode before the interpreter loop notices the SMC state, invalidates the JIT and re-enables the memory protection. This means that:
- Memory ops in general aren't slowed down by Blink's SMC support
- RWX memory can be written-to with some overhead
- RWX memory can be read-from with zero overhead
- Changes take effect when a JIT path ends
Intel's sixteen thousand page manual lays out the following guidelines for conformant self-modifying code:
To write self-modifying code and ensure that it is compliant with current and future versions of the IA-32 architectures, use one of the following coding options:
(* OPTION 1 *)
Store modified code (as data) into code segment;
Jump to new code or an intermediate location;
Execute new code;(* OPTION 2 )
Store modified code (as data) into code segment;
Execute a serializing instruction; ( For example, CPUID instruction *)
Execute new code;──Quoth Intel Manual V.3, §8.1.3
Blink implements this behavior because branching instructions cause JIT paths to end, paths only jump into one another selectively , and lastly serializing instructions are never added to paths in the first place.
Intel's rules allow Blink some leeway to make writing to RWX memory go
fast, without causing any signal storms, or incurring too much system
call overhead. As an example, consider the internal statistics printed
by the smc2_test.c
program:
make -j8 o//blink/blink o//test/func/smc2_test.elf
o//blink/blink -Z o//test/func/smc2_test.elf
[...]
icache_resets = 1
jit_blocks = 1
jit_hooks_installed = 132
jit_hooks_deleted = 19
jit_page_resets = 21
smc_checks = 22
smc_flushes = 22
smc_enqueued = 22
smc_segfaults = 22
[...]
The above program performs 300+ independent write operations to RWX memory. However we can see very few of them resulted in segfaults, since most of those ops happened in the SlowMemCpy() function which uses a tight conditional branch loop rather than a proper jump. This let the program get more accomplished, before dropping out of JIT code back into the main interpreter loop, which is where Blink checks the SMC state in order to flush the caches reapply any missing write protection.
Blink has an xterm-compatible ANSI pseudoteletypewriter display implementation which allows Blink's TUI interface to host other TUI programs, within an embedded terminal display. For example, it's possible to use Antirez's Kilo text editor inside Blink's TUI. For the complete list of ANSI sequences which are supported, please refer to blink/pty.c.
In real mode, Blink's PTY can be configured via INT $0x16
to convert
CGA memory stored at address 0xb0000
into UNICODE block characters,
thereby making retro video gaming in the terminal possible.
Blink supports 16-bit BIOS programs, such as SectorLISP. To boot real
mode programs in Blink, the blinkenlights -r
flag may be passed, which
puts the virtual machine in i8086 mode. Currently only a limited set of
BIOS APIs are available. For example, Blink supports IBM PC Serial UART,
CGA, and MDA. We hope to expand our real mode support in the near
future, in order to run operating systems like ELKS.
Blink supports troubleshooting operating system bootloaders. Blink was designed for Cosmopolitan Libc, which embeds an operating system in each binary it compiles. Blink has helped us debug our bare metal support, since Blink is capable of running in the 16-bit, 32-bit, and 64-bit modes a bootloader requires at various stages. In order to do that, we needed to implement some ring0 hardware instructions. Blink has enough to support Cosmopolitan, but it'll take much more time to get Blink to a point where it can boot something like Windows.
Blink supports several different executable formats. You can run:
-
x86-64-linux ELF executables (both static and dynamic).
-
Actually Portable Executables, which have either the
MZqFpD
orjartsr
magic. -
Flat executables, which must end with the file extension
.bin
. In this case, you can make executables as small as 10 bytes in size, since they're treated as raw x86-64 code. Blink always loads flat executables to the address0x400000
and automatically appends 16mb of BSS memory. -
Real mode executables, which are loaded to the address
0x7c00
. These programs must be run using theblinkenlights
command with the-r
flag.
When Blink is built with the VFS feature enabled (--enable-vfs
),
it comes with three default filesystems:
hostfs
: A filesystem that mirrors a certain directory on the host's filesystem. Files onhostfs
mounts have everything read from and written directly to the corresponding host directory, with the exception ofst_dev
andst_ino
fields.st_dev
is managed by Blink's VFS subsystem, whilest_ino
is calculated using a hash function based on the host'sst_dev
andst_ino
value.proc
: A filesystem that emulates Linux's/proc
using information available to Blink.devfs
: A filesystem that emulates Linux's/dev
. Currently, this is only a wrapper forhostfs
.
When Blink is launched, these default mount points are added:
/
of typehostfs
pointing to the corresponding host directory. This is determined by querying$BLINK_PREFIX
and the-C
parameter in order and falls back to/
if neither are available./proc
of typeproc
./dev
of typedevfs
./SytemRoot
of typehostfs
pointing to the host's root/
.
It is possbile for programs to add additional mount points by using
the mount
syscall (for hostfs
mounts, pass the path to the
directory on the host as the source
argument), but see the quirks
below.
Here's the current list of Blink's known quirks and tradeoffs.
Flag dependencies may not carry across function call boundaries under
long mode. This is because when Blink's JIT is speculating whether or
not it's necessary for an arithmetic instruction to compute flags, it
considers RET
and CALL
terminal ops that break the chain. As such
64-bit code shouldn't do things we did in the DOS days, such as using
carry flag as a return value to indicate error. This should work fine
when STC
is used to set the carry flag, but if the code computes it
cleverly using instructions like SUB
, then EFLAGS might not change.
Blink may not report the precise program counter where a fault occurred
in ucontext_t::uc_mcontext::rip
when signalling a segmentation fault.
This is currently only possible when PUSH
or POP
access bad memory.
That's because Blink's JIT tries to avoid updating Machine::ip
on ops
it considers "pure" such as those that only access registers, which for
reasons of performance is defined to include pushing and popping.
Blink doesn't have a working implementation of set_robust_list()
yet,
which means robust mutexes might not get unlocked if a process crashes.
POSIX.1 provides almost no guarantees of coherency, synchronization, and
durability when it comes to MAP_SHARED
mappings and recommends that
msync() be explicitly used to synchronize memory with file contents. The
Linux Kernel implements shared memory so well, that this is rarely
necessary. However some platforms like OpenBSD lack write coherency.
This means if you change a shared writable memory map and then call
pread() on the associated file region, you might get stale data. Blink
isn't able to polyfill incoherent platforms to be as coherent as Linux,
therefore apps that run in Blink should assume the POSIX rules apply.
Blink uses SIGSYS
to deliver signals internally. This signal is
precious to Blink. It's currently not possible for guest applications to
capture it from external processes.
Blink offers guest programs a 48-bit virtual address space with a
4096-byte page size. When programs are run on (1) host systems that have
a larger page (e.g. Apple M1, Cygwin), and (2) the linear memory
optimization is enabled (i.e. you're not using blink -m
) then Blink
may need to relax memory protections in cases where the memory intervals
defined by the guest aren't aligned to the host system page size. This
means that, on system with a larger than 4096 byte page size:
- Misaligned read-only pages could become writable
- JIT hooks might not invalidate automatically on misaligned RWX pages
It's recommended, when calling functions like mmap() and mprotect(),
that both addr
and addr + size
be aliged to the host page size.
Blink reports that value to the guest program in getauxval(AT_PAGESZ)
,
which should be obtainable via the POSIX API sysconf(_SC_PAGESIZE)
if
the C library is implemented correctly. Please note that when Blink is
running in full virtualization mode (i.e. blink -m
) this concern no
longer applies. That's because Blink will allocate a full system page
for every 4096 byte page that's mapped from a file.
For builds with the VFS feature enabled (--enable-vfs), while a procfs
mount is available at /proc
, it is limited to information available
in a single process. Only /proc/self
and the corresponding PID folder
is available. This means programs can get the expected values at
/proc/self/exe
and similar files, but process management tools like
ps
will not work.
On Linux, some procfs
symlinks possess a hardlink-like ability of
being dereferenceable even after the target has been unlink
ed.
Blink's implementation currently does not support this use case.
For builds with the VFS feature enabled (--enable-vfs
), Blink does not
share mount information with other emulated processes. As a result,
commands like this may seem to work (by return a 0 status code):
mount -t hostfs /some/path/on/host folder
But subsequent calls to ls folder
on the same shell still does not
display the expected contents. This is because the mount
command
could only modify the mount table kept by itself (and propagated to
children through fork
), but not the one used by its parent shell.
In other words, Blink behaves as if CLONE_NEWNS
is added to every
clone
call, separating the mount namespace of the child from its
parent.
Some might view this behavior as a feature, but it diverges from classic system behavior; a mechanism for handling shared process state is being considered in #92.