CBQN-specific documentation • source code overview

1. make
   • Third-party packages and other ways to run BQN are listed here
   • Add FFI=0 if your system doesn't have libffi
   • Use gmake on BSD
   • Add REPLXX=0 if C++ is unavailable (will remove line editing/coloring/name completion in the REPL)
   • Run sudo make install afterwards to install into /usr/local/bin/bqn (a PREFIX=/some/path argument will install to /some/path/bin/bqn); sudo make uninstall to uninstall
   • make clean if anything breaks and you want a clean build slate
2. ./BQN somefile.bqn to execute a file, or ./BQN for a REPL

The default configuration enables REPLXX & Singeli, and, if not done before, implicitly runs make for-build to build a CBQN for running build/src/build.bqn and compiling Singeli.

(TL;DR: use make o3n for local builds on x86-64, but make is fine on other architectures)

The default target (make o3) will target optimizations for the current architecture, but not any further extensions the specific CPU may have.

Thus, performance can be significantly improved by targeting the specific CPU via make o3n (with the usual drawback of -march=native of it not producing a binary portable to other CPUs of the same architecture).

On x86-64, a native build will enable usage of AVX2 (i.e. ability to use 256-bit SIMD vectors instead of 128-bit ones, among other things), and BMI2 if available. But, on aarch64, NEON is always available, so a native build won't give significant benefits.

To produce a binary utilizing AVX2 not specific to any processor, it's possible to do make o3 has=avx2. (has=avx2,bmi2 for targeting both AVX2 & BMI2)

Additionally, on AMD Zen 1 & Zen 2, make o3n has=slow-pdep will further improve certain builtins (Zen 1/2 support BMI2, but their implementation of pdep/pext is so slow that not using it for certain operations is very beneficial).

CBQN currently does not utilize AVX-512 or SVE, or have any SIMD optimizations specific to any architectures other than x86-64 and aarch64.

For native builds, targeted extensions are determined by /proc/cpuinfo (or sysctl machdep.cpu on macOS) and C macros defined as a result of -march=native.

notui=1 - display build progress in a plain-text format
version=... - specify the version to report in --version (default is commit hash)
nogit=1 - error if something attempts to use git CC=... - choose a different C compiler (default is clang, or cc if unavailable; CBQN is more tuned for clang, but gcc also works)
CXX=... - choose a different C++ compiler; needed only for REPLXX (default is c++)
OUTPUT=path/to/somewhere - change output location; for emcc-o3 it will be the destination folder for BQN.js and BQN.wasm, for everything else - the filename
target_arch=(x86-64|aarch64|generic) - target architecture. Inferred from uname by default. Used for deciding target optimizations.
target_os=(linux|bsd|macos|windows) - target OS. Inferred from uname by default. Used for determining default output names and slight configuration changes.
j=8 - override the default parallel job count (default is the output of nproc)
has=... - assume specified architecture extensions/properties (x86-64-only). Takes a comma-separated list which, beyond what is architecturally guaranteed, infer additional extensions as noted which hold on existing hardware (at least as of the time of writing):

• pclmul (implies SSE4.2)
• avx2 (implies pclmul, POPCNT, BMI1)
• bmi2 (implies pclmul, AVX1)
• slow-pdep (specifies Zen 1 & Zen 2's slow pdep/pext)

REPLXX=0 - disable REPLXX singeli=0 - disable usage of Singeli
FFI=0 - disable •FFI, thus not depending on libffi
usz=64 - support arrays with length over 2³²

f=... - add extra C compiler flags for CBQN file compilation
lf=... - add extra linking flags (LDFLAGS is a synonym)
CCFLAGS=... - add flags for all CC/CXX/linking invocations
REPLXX_FLAGS=... - override replxx build flags (default is -std=c++11 -Os)
CXXFLAGS=... - add additional CXX flags

Alternatively, build/build (aka build.bqn) can be invoked manually, though note that it has slightly different argument naming (see build/build --help) and doesn't have predefined build types (i.e. make o3ng is done as build/build replxx singeli native g)

• make o3 - the default build
• make o3g - effectively make o3 f=-g (custom f=... can still be added on)
• make c - make o3 but without -O3
• make shared-o3 - produce a shared library libcbqn.so/libcbqn.dylib/cbqn.dll
• make shared-c - like make c but for a shared library
• make emcc-o3 - build with Emscripten emcc
• make wasi-o3 - build targeting WASI
• make wasi-reactor-o3 - build producing a WASI Reactor
• make debug - unoptimized build with extra assertion checks (also includes -g)
• make static-bin - build a statically linked executable (for a fully standalone binary, try make static-bin CC=musl-gcc REPLXX=0)
• make static-lib - build a static library archive

All of the above will go through build.bqn. If that causes problems, make o3-makeonly or make c-makeonly can be used. These still enable REPLXX by default, but do not support Singeli. Furthermore, these targets don't support some of the build flags that the others do.

• The current default is to use unsigned 32-bit integers for array lengths, limiting array size to about 2^32 elements. This can be switched to 64-bit via usz=64, but will have limited effect as some builtins don't have implementations for indices larger than 32-bit (search functions, ⊔, /𝕩, /⁼𝕩 & similar). Additionally, some things may fail even before 2^31 and may even crash CBQN.

• Throwing & catching errors will leak memory: the garbage collector has no way to scan for objects on the C stack, and checks for objects with an incorrect reference count (comparing to the expected from other heap objects / GC roots) to estimate that. Error catching is implemented as a longjmp, thus making the GC permanently think those are still on the C stack. Between REPL lines, a full GC can run (as then there's a guarantee of no BQN code being mid-execution), but that doesn't apply to any other context.

• Freeing highly nested objects will crash: object freeing is done recursively, and there is nothing preventing arbitrarily-nested objects.

CBQN requires either gcc or clang as the C compiler (by default it attempts clang as things are primarily optimized for clang, but, if unavailable, it'll fall back to cc; override with CC=your-cc), and, optionally, libffi for •FFI and C++ (requires ≥C++11; defaults to c++, override with CXX=your-c++) for replxx.

There aren't hard requirements for versions of any of those, but nevertheless here are some configurations that CBQN is tested on by dzaima:

x86-64 (Linux):
  gcc 9.5; gcc 12.1.0; clang 10.0.0; clang 17-trunk
  libffi 3.4.2
  cpu microarchitecture: Haswell
  replxx: g++ 12.1.0
x86 (Linux):
  clang 17-trunk; CBQN is known to break on gcc x86 - https://gcc.gnu.org/bugzilla/show_bug.cgi?id=58416
  running on the above x86-64 system, compiled with CCFLAGS=-m32
AArch64 ARMv8-A (within Termux on Android 8):
  using a `lf=-landroid-spawn` make arg after `pkg install libandroid-spawn` to get •SH to work
  clang 16.0.6
  libffi 3.4.4 (structs were broken as of 3.4.3)
  replxx: clang++ 16.0.6

Additionally, CBQN is known to compile as-is on macOS. Windows builds can be made by cross-compilation (Docker setup).

The build will attempt to use pkg-config to find libffi, uname to determine target_arch & target_os, and nproc for parallel job count, with defaults if unavailable (-lffi for linking libffi (+ -ldl on non-BSD), target_arch=generic, target_os=linux, j=4; these can of course also be specified manually).

Furthermore, git is used to determine the version to present for --version (override with version=...), and to update submodules.

Submodules are used for Singeli, replxx, and precompiled bytecode. To avoid automatic usage of git, link local copies to build/singeliLocal, build/replxxLocal, and build/bytecodeLocal.

CBQN uses the self-hosted BQN compiler & some parts of the runtime, and therefore needs to be bootstrapped. By default, the CBQN will use precompiled bytecode.

In order to build everything from source, you can:

1. dzaima/BQN is a BQN implementation that is completely implemented in Java (clone it & run ./build)
2. clone mlochbaum/BQN
3. mkdir -p build/bytecodeLocal/gen
4. other-bqn-impl ./build/genRuntime path/to/mlochbaum/BQN build/bytecodeLocal
   In the case of the Java impl, java -jar path/to/dzaima/BQN/BQN.jar ./build/genRuntime path/to/mlochbaum/BQN build/bytecodeLocal

1. clone mlochbaum/BQN
2. mkdir -p build/bytecodeLocal/gen && make for-bootstrap && ./BQN build/bootstrap.bqn path/to/mlochbaum/BQN

Note that, after either of those, the compiled bytecode may become desynchronized if you later update CBQN without also rebuilding the bytecode. Usage of the submodule can be restored by removing build/bytecodeLocal.

You must manually set up a cross-compilation environment. It's possible to pass flags to all CC/CXX/linking invocations via CCFLAGS=..., and LDFLAGS=... to pass ones to the linking step specifically (more configuration options above).

A target_arch=(x86-64|aarch64|generic) make argument must be present (generic will work always, but a more specific argument will enable significant optimizations), as otherwise it'll choose based on uname.

Furthermore, all build targets (except -makeonly ones) will need a non-cross-compiled version of CBQN at build time to run build.bqn and Singeli. For those, a make for-build will need to be ran before the primary build, configured to not cross-compile. (this step only needs a C compiler (default is CC=cc here), and doesn't need libffi, nor a C++ compiler).

First, some exceptions to the general licensing:

• timsort implementation - src/builtins/sortTemplate.h: MIT; original repo
• Ryu - src/utils/ryu.c & files in src/utils/ryu/: Apache 2.0 or Boost 1.0; original repo

Everything else (i.e. all files except src/builtins/sortTemplate.h, src/utils/ryu.c, and everything in src/utils/ryu/) may be treated as under any of the following licenses, as if they had the respective notice:

• GNU LGPLv3 only

Copyright (C) 2021-2023 dzaima and contributors

This program is free software: you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public License
along with this program.  If not, see <https://www.gnu.org/licenses/>.

• GNU GPLv3 only

Copyright (C) 2021-2023 dzaima and contributors

This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU General Public License for more details.

You should have received a copy of the GNU General Public License
along with this program.  If not, see <https://www.gnu.org/licenses/>.

• MPL 2.0

This Source Code Form is subject to the terms of the Mozilla Public
License, v. 2.0. If a copy of the MPL was not distributed with this
file, You can obtain one at http://mozilla.org/MPL/2.0/.