Nim Compiler User Guide (original) (raw)

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"Look at you, hacker. A pathetic creature of meat and bone, panting and sweating as you run through my corridors. How can you challenge a perfect, immortal machine?"

Introduction

This document describes the usage of the Nim compiler on the different supported platforms. It is not a definition of the Nim programming language (which is covered in the manual).

Nim is free software; it is licensed under the MIT License.

Compiler Usage

Command-line switches

All options that take a PATH or DIR argument are subject to path substitution:

• $nim: The global nim prefix path
• $lib: The stdlib path
• $home and ~: The user's home path
• $config: The directory of the module currently being compiled
• $projectname: The project file's name without file extension
• projectpathandprojectpath and projectpathandprojectdir: The project file's path
• $nimcache: The nimcache path

Basic command-line switches are:

Usage:

nim command [options] [projectfile] [arguments]

Command:

compile, c

compile project with default code generator (C)

r

compile to $nimcache/projname, run with

arguments

using backend specified by

--backend

(default: c)

doc

generate the documentation for inputfile for backend specified by

--backend

(default: c)

Arguments: arguments are passed to the program being run (if --run option is selected)

Options:

-p, --path:PATH

add path to search paths

-d, --define:SYMBOL(:VAL)

define a conditional symbol (Optionally: Define the value for that symbol, see: "compile time define pragmas")

-u, --undef:SYMBOL

undefine a conditional symbol

-f, --forceBuild:on|off

force rebuilding of all modules

--stackTrace:on|off

turn stack tracing on|off

--lineTrace:on|off

turn line tracing on|off

--threads:on|off

turn support for multi-threading on|off

-x, --checks:on|off

turn all runtime checks on|off

-a, --assertions:on|off

turn assertions on|off

--opt:none|speed|size

optimize not at all or for speed|size Note: use -d:release for a release build!

--debugger:native

use native debugger (gdb)

--app:console|gui|lib|staticlib

generate a console app|GUI app|DLL|static library

-r, --run

run the compiled program with given arguments

--eval:cmd

evaluate nim code directly; e.g.:

nim --eval:"echo 1"

defaults to

e

(nimscript) but customizable:

nim r --eval:'for a in stdin.lines: echo a'

--fullhelp

show all command line switches

-v, --version

show detailed version information

Note, single letter options that take an argument require a colon. E.g. -p:PATH.

Advanced command-line switches are:

Advanced commands:

compileToC, cc

compile project with C code generator

compileToCpp, cpp

compile project to C++ code

compileToOC, objc

compile project to Objective C code

js

compile project to Javascript

md2html

convert a Markdown file to HTML use

--docCmd:skip

to skip compiling snippets

rst2html

convert a reStructuredText file to HTML use

--docCmd:skip

to skip compiling snippets

md2tex

convert a Markdown file to LaTeX

rst2tex

convert a reStructuredText file to LaTeX

doc2tex

extract the documentation to a LaTeX file

jsondoc

extract the documentation to a json file

buildIndex

build an index for the whole documentation

genDepend

generate a DOT file containing the module dependency graph

dump

dump all defined conditionals and search paths see also: --dump.format:json (useful with:

| jq

)

check

checks the project for syntax and semantics (can be combined with --defusages)

Runtime checks (see -x):

--objChecks:on|off

turn obj conversion checks on|off

--fieldChecks:on|off

turn case variant field checks on|off

--rangeChecks:on|off

turn range checks on|off

--boundChecks:on|off

turn bound checks on|off

--overflowChecks:on|off

turn int over-/underflow checks on|off

--floatChecks:on|off

turn all floating point (NaN/Inf) checks on|off

--nanChecks:on|off

turn NaN checks on|off

--infChecks:on|off

turn Inf checks on|off

Advanced options:

--defusages:FILE,LINE,COL

find the definition and all usages of a symbol

-o:FILE, --out:FILE

set the output filename

--outdir:DIR

set the path where the output file will be written

--usenimcache

will use

outdir=$$nimcache

, whichever it resolves to after all options have been processed

--stdout:on|off

output to stdout

--colors:on|off

turn compiler messages coloring on|off

--filenames:abs|canonical|legacyRelProj

customize how filenames are rendered in compiler messages, defaults to

abs

(absolute)

--processing:dots|filenames|off

show files as they're being processed by nim compiler

--unitsep:on|off

use the ASCII unit separator (31) between error messages, useful for IDE-like tooling

--declaredLocs:on|off

show declaration locations in messages

--spellSuggest:num

show at most

num >= 0

spelling suggestions on typos. if

num

is not specified (or

auto

), return an implementation defined set of suggestions.

--hints:on|off|list

on|off

enables or disables hints.

list

reports which hints are selected.

--hint:X:on|off

turn specific hint X on|off.

hint:X

means

hint:X:on

, as with similar flags.

all

is the set of all hints (only

all:off

is supported).

--hintAsError:X:on|off

turn specific hint X into an error on|off

-w:on|off|list, --warnings:on|off|list

on|off

enables or disables warnings.

list

reports which warnings are selected.

--warning:X:on|off

turn specific warning X on|off.

warning:X

means

warning:X:on

, as with similar flags.

all

is the set of all warning (only

all:off

is supported).

--warningAsError:X:on|off

turn specific warning X into an error on|off

--styleCheck:off|hint|error

--styleCheck:usages

only enforce consistent spellings of identifiers, do not enforce the style on declarations

--showAllMismatches:on|off

show all mismatching candidates in overloading resolution

--lib:PATH

set the system library path

--import:PATH

add an automatically imported module see also

patchFile

in nimscript which offers more flexibility.

--include:PATH

add an automatically included module

-c, --compileOnly:on|off

compile Nim files only; do not assemble or link

--noLinking:on|off

compile Nim and generated files but do not link

--noMain:on|off

do not generate a main procedure

--genScript:on|off

generate a compile script (in the 'nimcache' subdirectory named 'compile_$$project$$scriptext'), and a '.deps' file containing the dependencies; implies --compileOnly

--os:SYMBOL

set the target operating system (cross-compilation)

--cpu:SYMBOL

set the target processor (cross-compilation)

--debuginfo:on|off

enables debug information

-t, --passC:OPTION

pass an option to the C compiler

-l, --passL:OPTION

pass an option to the linker

--cc:SYMBOL

specify the C compiler

--cincludes:DIR

modify the C compiler header search path

--clibdir:DIR

modify the linker library search path

--clib:LIBNAME

link an additional C library (you should omit platform-specific extensions)

--project

document the whole project (doc)

--docRoot:path

nim doc --docRoot:/foo --project --outdir:docs /foo/sub/main.nim

generates: docs/sub/main.html if path == @pkg, will use nimble file enclosing dir if path == @path, will use first matching dir in

--path

if path == @default (the default and most useful), will use best match among @pkg,@path. if these are nonexistent, will use project path

-b, --backend:c|cpp|js|objc

sets backend to use with commands like

nim doc

or

nim r

--docCmd:cmd

if

cmd == skip

, skips runnableExamples else, runs runnableExamples with given options, e.g.:

--docCmd:"-d:foo --threads:on"

--docSeeSrcUrl:url

activate 'see source' for doc command (see doc.item.seesrc in config/nimdoc.cfg)

--docInternal

also generate documentation for non-exported symbols

--lineDir:on|off

generation of #line directive on|off

--embedsrc:on|off

embeds the original source code as comments in the generated output

--tlsEmulation:on|off

turn thread local storage emulation on|off

--implicitStatic:on|off

turn implicit compile time evaluation on|off

--trmacros:on|off

turn term rewriting macros on|off

--multimethods:on|off

turn multi-methods on|off

--hotCodeReloading:on|off

turn support for hot code reloading on|off

--excessiveStackTrace:on|off

stack traces use full file paths

--stackTraceMsgs:on|off

enable user defined stack frame msgs via

setFrameMsg

--skipCfg:on|off

do not read the nim installation's configuration file

--skipUserCfg:on|off

do not read the user's configuration file

--skipParentCfg:on|off

do not read the parent dirs' configuration files

--skipProjCfg:on|off

do not read the project's configuration file

--mm:orc|arc|refc|markAndSweep|boehm|go|none|regions

select which memory management to use; default is 'orc'

--exceptions:setjmp|cpp|goto|quirky

select the exception handling implementation

--index:on|off|only

docgen: turn index file generation on|off (

only

means not generate output files like HTML)

--noImportdoc:on|off

turn loading documentation

.idx

files on|off

--putenv:key=value

set an environment variable

--NimblePath:PATH

add a path for Nimble support

--noNimblePath

deactivate the Nimble path

--clearNimblePath

empty the list of Nimble package search paths

--cppCompileToNamespace:namespace

use the provided namespace for the generated C++ code, if no namespace is provided "Nim" will be used

--nimMainPrefix:prefix

use

{prefix}NimMain

instead of

NimMain

in the produced C/C++ code

--expandMacro:MACRO

dump every generated AST from MACRO

--expandArc:PROCNAME

show how PROCNAME looks like after diverse optimizations before the final backend phase (mostly ARC/ORC specific)

--excludePath:PATH

exclude a path from the list of search paths

--dynlibOverride:SYMBOL

marks SYMBOL so that dynlib:SYMBOL has no effect and can be statically linked instead; symbol matching is fuzzy so that --dynlibOverride:lua matches dynlib: "liblua.so.3"

--dynlibOverrideAll

disables the effects of the dynlib pragma

--listCmd

list the compilation commands; can be combined with

--hint:exec:on

and

--hint🔗on

--asm

produce assembler code

--parallelBuild:0|1|...

perform a parallel build value = number of processors (0 for auto-detect)

--incremental:on|off

only recompile the changed modules (experimental!)

--verbosity:0|1|2|3

set Nim's verbosity level (1 is default)

--errorMax:N

stop compilation after N errors; 0 means unlimited

--maxLoopIterationsVM:N

set max iterations for all VM loops

--maxCallDepthVM:N

set max call depth in the VM

--experimental:$1

enable experimental language feature

--legacy:$2

enable obsolete/legacy language feature

--benchmarkVM:on|off

turn benchmarking of VM code with cpuTime() on|off

--profileVM:on|off

turn compile time VM profiler on|off

--panics:on|off

turn panics into process terminations (default: off)

--deepcopy:on|off

enable 'system.deepCopy' for

--mm:arc|orc

--jsbigint64:on|off

toggle the use of BigInt for 64-bit integers for the JavaScript backend (default: on)

--nimBasePattern:nimbase.h

allows to specify a custom pattern for

nimbase.h

List of warnings

Each warning can be activated individually with --warning:NAME:on|off or in a push pragma with {.warning[NAME]:on|off.}.

List of hints

Each hint can be activated individually with --hint:NAME:on|off or in a push pragma with {.hint[NAME]:on|off.}.

Verbosity levels

Compile-time symbols

Through the -d:x or --define:x switch you can define compile-time symbols for conditional compilation. The defined switches can be checked in source code with the when statement and defined proc. The typical use of this switch is to enable builds in release mode (-d:release) where optimizations are enabled for better performance. Another common use is the -d:ssl switch to activate SSL sockets.

Additionally, you may pass a value along with the symbol: -d:x=y which may be used in conjunction with the compile-time define pragmas to override symbols during build time.

Compile-time symbols are completely case insensitive and underscores are ignored too. --define:FOO and --define:foo are identical.

Compile-time symbols starting with the nim prefix are reserved for the implementation and should not be used elsewhere.

Configuration files

Note: The project file name is the name of the .nim file that is passed as a command-line argument to the compiler.

The nim executable processes configuration files in the following directories (in this order; later files overwrite previous settings):

1. $nim/config/nim.cfg, /etc/nim/nim.cfg (UNIX) or <Nim's installation directory>\config\nim.cfg (Windows). This file can be skipped with the --skipCfg command line option.
2. If environment variable XDG_CONFIG_HOME is defined, $XDG_CONFIG_HOME/nim/nim.cfg or ~/.config/nim/nim.cfg (POSIX) or %APPDATA%/nim/nim.cfg (Windows). This file can be skipped with the --skipUserCfg command line option.
3. parentDir/nim.cfgwhereparentDir/nim.cfg where parentDir/nim.cfgwhereparentDir stands for any parent directory of the project file's path. These files can be skipped with the --skipParentCfg command-line option.
4. projectDir/nim.cfgwhereprojectDir/nim.cfg where projectDir/nim.cfgwhereprojectDir stands for the project file's path. This file can be skipped with the --skipProjCfg command-line option.
5. A project can also have a project-specific configuration file named project.nim.cfgthatresidesinthesamedirectoryasproject.nim.cfg that resides in the same directory as project.nim.cfgthatresidesinthesamedirectoryasproject.nim. This file can be skipped with the --skipProjCfg command-line option.

NimScript files can also be used for configuration.

Command-line settings have priority over configuration file settings.

The default build of a project is a debug build. To compile a release build define the release symbol:

nim c -d:release myproject.nim

To compile a dangerous release build define the danger symbol:

nim c -d:danger myproject.nim

Search path handling

Nim has the concept of a global search path (PATH) that is queried to determine where to find imported modules or include files. If multiple files are found an ambiguity error is produced.

nim dump shows the contents of the PATH.

However before the PATH is used the current directory is checked for the file's existence. So if PATH contains libandlib and libandlib/bar and the directory structure looks like this:

$lib/x.nim $lib/bar/x.nim foo/x.nim foo/main.nim other.nim

And main imports x, foo/x is imported. If other imports x then both lib/x.nimandlib/x.nim and lib/x.nimandlib/bar/x.nim match but $lib/x.nim is used as it is the first match.

Generated C code directory

The generated files that Nim produces all go into a subdirectory called nimcache. Its full path is

• XDGCACHEHOME/nim/XDG_CACHE_HOME/nim/XDGCACHEHOME/nim/projectname(_r|_d) or ~/.cache/nim/$projectname(_r|_d) on Posix
• HOMEnimcacheHOME\nimcache\HOMEnimcacheprojectname(_r|_d) on Windows.

The _r suffix is used for release builds, _d is for debug builds.

This makes it easy to delete all generated files.

The --nimcache compiler switch can be used to to change the nimcache directory.

However, the generated C code is not platform-independent. C code generated for Linux does not compile on Windows, for instance. The comment on top of the C file lists the OS, CPU, and CC the file has been compiled for.

Compiler Selection

To change the compiler from the default compiler (at the command line):

nim c --cc:llvm_gcc --compile_only myfile.nim

This uses the configuration defined in config\nim.cfg for llvm_gcc.

If nimcache already contains compiled code from a different compiler for the same project, add the -f flag to force all files to be recompiled.

The default compiler is defined at the top of config\nim.cfg. Changing this setting affects the compiler used by koch to (re)build Nim.

To use the CC environment variable, use nim c --cc:env myfile.nim. To use the CXX environment variable, use nim cpp --cc:env myfile.nim. --cc:env is available since Nim version 1.4.

Cross-compilation

To cross compile, use for example:

nim c --cpu:i386 --os:linux --compileOnly --genScript myproject.nim

Then move the C code and the compile script compile_myproject.sh to your Linux i386 machine and run the script.

Another way is to make Nim invoke a cross compiler toolchain:

nim c --cpu:arm --os:linux myproject.nim

For cross compilation, the compiler invokes a C compiler named like cpu.cpu.cpu.os.$cc (for example arm.linux.gcc) with options defined in cpu.cpu.cpu.os.$cc.options.always. The configuration system is used to provide meaningful defaults. For example, for Linux on a 32-bit ARM CPU, your configuration file should contain something like:

arm.linux.gcc.path = "/usr/bin" arm.linux.gcc.exe = "arm-linux-gcc" arm.linux.gcc.linkerexe = "arm-linux-gcc" arm.linux.gcc.options.always = "-w -fmax-errors=3"

Cross-compilation for Windows

To cross-compile for Windows from Linux or macOS using the MinGW-w64 toolchain:

nim c -d:mingw myproject.nim

nim r -d:mingw --eval:'import os; echo "a" / "b"'

Use --cpu:i386 or --cpu:amd64 to switch the CPU architecture.

The MinGW-w64 toolchain can be installed as follows:

apt install mingw-w64
yum install mingw32-gcc yum install mingw64-gcc brew install mingw-w64

Cross-compilation for Android

There are two ways to compile for Android: terminal programs (Termux) and with the NDK (Android Native Development Kit).

The first one is to treat Android as a simple Linux and use Termux to connect and run the Nim compiler directly on android as if it was Linux. These programs are console-only programs that can't be distributed in the Play Store.

Use regular nim c inside termux to make Android terminal programs.

Normal Android apps are written in Java, to use Nim inside an Android app you need a small Java stub that calls out to a native library written in Nim using the NDK. You can also use native-activity to have the Java stub be auto-generated for you.

Use nim c -c --cpu:arm --os:android -d:androidNDK --noMain:on to generate the C source files you need to include in your Android Studio project. Add the generated C files to CMake build script in your Android project. Then do the final compile with Android Studio which uses Gradle to call CMake to compile the project.

Because Nim is part of a library it can't have its own C-style main() so you would need to define your own android_main and init the Java environment, or use a library like SDL2 or GLFM to do it. After the Android stuff is done, it's very important to call NimMain() in order to initialize Nim's garbage collector and to run the top level statements of your program.

proc NimMain() {.importc.} proc glfmMain*(display: ptr GLFMDisplay) {.exportc.} = NimMain()

The name NimMain can be influenced via the --nimMainPrefix:prefix switch. Use --nimMainPrefix:MyLib and the function to call is named MyLibNimMain.

Cross-compilation for iOS

To cross-compile for iOS you need to be on a macOS computer and use XCode. Normal languages for iOS development are Swift and Objective C. Both of these use LLVM and can be compiled into object files linked together with C, C++ or Objective C code produced by Nim.

Use nim c -c --os:ios --noMain:on to generate C files and include them in your XCode project. Then you can use XCode to compile, link, package and sign everything.

Because Nim is part of a library it can't have its own C-style main() so you would need to define main that calls autoreleasepool and UIApplicationMain to do it, or use a library like SDL2 or GLFM. After the iOS setup is done, it's very important to call NimMain() to initialize Nim's garbage collector and to run the top-level statements of your program.

proc NimMain() {.importc.} proc glfmMain*(display: ptr GLFMDisplay) {.exportc.} = NimMain()

Note: XCode's "make clean" gets confused about the generated nim.c files, so you need to clean those files manually to do a clean build.

The name NimMain can be influenced via the --nimMainPrefix:prefix switch. Use --nimMainPrefix:MyLib and the function to call is named MyLibNimMain.

Cross-compilation for Nintendo Switch

Simply add --os:nintendoswitch to your usual nim c or nim cpp command and set the passC and passL command line switches to something like:

nim c ... --d:nimAllocPagesViaMalloc --mm:orc --passC="-I$DEVKITPRO/libnx/include" ... --passL="-specs=$DEVKITPRO/libnx/switch.specs -L$DEVKITPRO/libnx/lib -lnx"

or setup a nim.cfg file like so:

#nim.cfg --mm:orc --d:nimAllocPagesViaMalloc --define:nimInheritHandles --passC="-I$DEVKITPRO/libnx/include" --passL="-specs=$DEVKITPRO/libnx/switch.specs -L$DEVKITPRO/libnx/lib -lnx"

The devkitPro setup must be the same as the default with their new installer here for Mac/Linux or here for Windows.

For example, with the above-mentioned config:

nim c --os:nintendoswitch switchhomebrew.nim

This will generate a file called switchhomebrew.elf which can then be turned into an nro file with the elf2nro tool in the devkitPro release. Examples can be found at the nim-libnx github repo.

There are a few things that don't work because the devkitPro libraries don't support them. They are:

1. Waiting for a subprocess to finish. A subprocess can be started, but right now it can't be waited on, which sort of makes subprocesses a bit hard to use
2. Dynamic calls. Switch OS (Horizon) doesn't support dynamic libraries, so dlopen/dlclose are not available.
3. mqueue. Sadly there are no mqueue headers.
4. ucontext. No headers for these either. No coroutines for now :(
5. nl_types. No headers for this.
6. As mmap is not supported, the nimAllocPagesViaMalloc option has to be used.

GPU Compilation

Compiling for GPU computation can be achieved with --cc:nvcc for CUDA with nvcc, or with --cc:hipcc for AMD GPUs with HIP. Both compilers require building for C++ with nim cpp.

Here's a very simple CUDA kernel example using emit, which can be compiled with nim cpp --cc:nvcc --define:"useMalloc" hello_kernel.nim assuming you have the CUDA toolkit installed.

{.emit: """ global void add(int a, int b) { int c; c = a + b; } """.}

proc main() = {.emit: """ add<<<1,1>>>(2,7); """.}

main()

DLL generation

Note: The same rules apply to lib*.so shared object files on UNIX. For better readability only the DLL version is described here.

Nim supports the generation of DLLs. However, there must be only one instance of the GC per process/address space. This instance is contained in nimrtl.dll. This means that every generated Nim DLL depends on nimrtl.dll. To generate the "nimrtl.dll" file, use the command:

nim c -d:release lib/nimrtl.nim

To link against nimrtl.dll use the command:

nim c -d:useNimRtl myprog.nim

Additional compilation switches

The standard library supports a growing number of useX conditional defines affecting how some features are implemented. This section tries to give a complete list.

Additional Features

This section describes Nim's additional features that are not listed in the Nim manual. Some of the features here only make sense for the C code generator and are subject to change.

LineDir option

The --lineDir option can be turned on or off. If turned on the generated C code contains #line directives. This may be helpful for debugging with GDB.

StackTrace option

If the --stackTrace option is turned on, the generated C contains code to ensure that proper stack traces are given if the program crashes or some uncaught exception is raised.

LineTrace option

The --lineTrace option implies the stackTrace option. If turned on, the generated C contains code to ensure that proper stack traces with line number information are given if the program crashes or an uncaught exception is raised.

DynlibOverride

By default Nim's dynlib pragma causes the compiler to generate GetProcAddress (or their Unix counterparts) calls to bind to a DLL. With the dynlibOverride command line switch this can be prevented and then via --passL the static library can be linked against. For instance, to link statically against Lua this command might work on Linux:

nim c --dynlibOverride:lua --passL:liblua.lib program.nim

Backend language options

The typical compiler usage involves using the compile or c command to transform a .nim file into one or more .c files which are then compiled with the platform's C compiler into a static binary. However, there are other commands to compile to C++, Objective-C, or JavaScript. More details can be read in the Nim Backend Integration document.

Nim documentation tools

Nim provides the doc command to generate HTML documentation from .nim source files. Only exported symbols will appear in the output. For more details see the docgen documentation.

Nim idetools integration

Nim provides language integration with external IDEs through the idetools command. See the documentation of idetools for further information.

Nim for embedded systems

While the default Nim configuration is targeted for optimal performance on modern PC hardware and operating systems with ample memory, it is very well possible to run Nim code and a good part of the Nim standard libraries on small embedded microprocessors with only a few kilobytes of memory.

A good start is to use the any operating target together with the malloc memory allocator and the arc garbage collector. For example:

nim c --os:any --mm:arc -d:useMalloc [...] x.nim

• --mm:arc will enable the reference counting memory management instead of the default garbage collector. This enables Nim to use heap memory which is required for strings and seqs, for example.
• The --os:any target makes sure Nim does not depend on any specific operating system primitives. Your platform should support only some basic ANSI C library stdlib and stdio functions which should be available on almost any platform.
• The -d:useMalloc option configures Nim to use only the standard C memory manage primitives malloc(), free(), realloc().

If your platform does not provide these functions it should be trivial to provide an implementation for them and link these to your program.

For targets with very restricted memory, it might be beneficial to pass some additional flags to both the Nim compiler and the C compiler and/or linker to optimize the build for size. For example, the following flags can be used when targeting a gcc compiler:

--opt:size -d:lto -d:strip

The --opt:size flag instructs Nim to optimize code generation for small size (with the help of the C compiler), the -d:lto flags enable link-time optimization in the compiler and linker, the -d:strip strips debug symbols.

Check the Cross-compilation section for instructions on how to compile the program for your target.

nimAllocPagesViaMalloc

Nim's default allocator is based on TLSF, this algorithm was designed for embedded devices. This allocator gets blocks/pages of memory via a currently undocumented osalloc API which usually uses POSIX's mmap call. On many environments mmap is not available but C's malloc is. You can use the nimAllocPagesViaMalloc define to use malloc instead of mmap. nimAllocPagesViaMalloc is currently only supported with --mm:arc or --mm:orc. (Since version 1.6)

nimPage256 / nimPage512 / nimPage1k

Adjust the page size for Nim's GC allocator. This enables using nimAllocPagesViaMalloc on devices with less RAM. The default page size requires too much RAM to work.

Recommended settings:

• < 32 kB of RAM use nimPage256
• < 512 kB of RAM use nimPage512
• < 2 MB of RAM use nimPage1k

Initial testing hasn't shown much difference between 512B or 1kB page sizes in terms of performance or latency. Using nimPages256 will limit the total amount of allocatable RAM.

nimMemAlignTiny

Sets MemAlign to 4 bytes which reduces the memory alignment to better match some embedded devices.

Thread stack size

Nim's thread API provides a simple wrapper around more advanced RTOS task features. Customizing the stack size and stack guard size can be done by setting -d:nimThreadStackSize=16384 or -d:nimThreadStackGuard=32.

Currently only Zephyr, NuttX and FreeRTOS support these configurations.

Nim for realtime systems

See the --mm:arc or --mm:orc memory management settings in MM for further information.

Signal handling in Nim

The Nim programming language has no concept of Posix's signal handling mechanisms. However, the standard library offers some rudimentary support for signal handling, in particular, segmentation faults are turned into fatal errors that produce a stack trace. This can be disabled with the -d:noSignalHandler switch.

Optimizing for Nim

Nim has no separate optimizer, but the C code that is produced is very efficient. Most C compilers have excellent optimizers, so usually it is not needed to optimize one's code. Nim has been designed to encourage efficient code: The most readable code in Nim is often the most efficient too.

However, sometimes one has to optimize. Do it in the following order:

1. switch off the embedded debugger (it is slow!)
2. turn on the optimizer and turn off runtime checks
3. profile your code to find where the bottlenecks are
4. try to find a better algorithm
5. do low-level optimizations

This section can only help you with the last item.

Optimizing string handling

String assignments are sometimes expensive in Nim: They are required to copy the whole string. However, the compiler is often smart enough to not copy strings. Due to the argument passing semantics, strings are never copied when passed to subroutines. The compiler does not copy strings that are a result of a procedure call, because the callee returns a new string anyway. Thus it is efficient to do:

var s = procA()

However, it is not efficient to do:

var s = varA

For let symbols a copy is not always necessary:

let s = varA

The compiler optimizes string case statements: A hashing scheme is used for them if several different string constants are used. So code like this is reasonably efficient:

case normalize(k.key) of "name": c.name = v of "displayname": c.displayName = v of "version": c.version = v of "os": c.oses = split(v, {';'}) of "cpu": c.cpus = split(v, {';'}) of "authors": c.authors = split(v, {';'}) of "description": c.description = v of "app": case normalize(v) of "console": c.app = appConsole of "gui": c.app = appGUI else: quit(errorStr(p, "expected: console or gui")) of "license": c.license = UnixToNativePath(k.value) else: quit(errorStr(p, "unknown variable: " & k.key))