=========================================
Internals of the Nim Compiler
=========================================
:Author: Andreas Rumpf :Version: |nimversion|
.. default-role:: code .. include:: rstcommon.rst .. contents::
"Abstraction is layering ignorance on top of reality." -- Richard Gabriel
The Nim project's directory structure is:
============ ===================================================
Path Purpose
============ ===================================================
bin
generated binary files
build
generated C code for the installation
compiler
the Nim compiler itself; note that this
code has been translated from a bootstrapping
version written in Pascal, so the code is **not**
a poster child of good Nim code
config
configuration files for Nim
dist
additional packages for the distribution
doc
the documentation; it is a bunch of
reStructuredText files
lib
the Nim library
============ ===================================================
Note: Add .
to your PATH so that koch
:cmd: can be used without the ./
.
Compiling the compiler is a simple matter of running:
nim c koch.nim
koch boot -d:release
For a debug version use:
nim c koch.nim
koch boot
And for a debug version compatible with GDB:
nim c koch.nim
koch boot --debuginfo --linedir:on
The koch
:cmd: program is Nim's maintenance script. It is a replacement for
make and shell scripting with the advantage that it is much more portable.
More information about its options can be found in the koch
documentation.
Set the compilation timestamp with the SOURCE_DATE_EPOCH
environment variable.
export SOURCE_DATE_EPOCH=$(git log -n 1 --format=%at)
koch boot # or `./build_all.sh`
There are often times when there is a bug that is caused by a regression in the compiler or stdlib. Bisecting the Nim repo commits is a useful tool to identify what commit introduced the regression.
Even if it's not known whether a bug is caused by a regression, bisection can reduce debugging time by ruling it out. If the bug is found to be a regression, then you focus on the changes introduced by that one specific commit.
koch temp
:cmd: returns 125 as the exit code in case the compiler
compilation fails. This exit code tells git bisect
:cmd: to skip the
current commit:
git bisect start bad-commit good-commit
git bisect run ./koch temp -r c test-source.nim
You can also bisect using custom options to build the compiler, for example if
you don't need a debug version of the compiler (which runs slower), you can replace
./koch temp
:cmd: by explicit compilation command, see [Bootstrapping the compiler].
Considering that a useful method of debugging the compiler is inserting debug
logging, or changing code and then observing the outcome of a testcase, it is
fastest to build a compiler that is instrumented for debugging from an
existing release build. koch temp
:cmd: provides a convenient method of doing
just that.
By default, running koch temp
:cmd: will build a lean version of the compiler
with -d:debug
:option: enabled. The compiler is written to bin/nim_temp
by
default. A lean version of the compiler lacks JS and documentation generation.
bin/nim_temp
can be directly used to run testcases, or used with testament
with testament --nim:bin/nim_temp r tests/category/tsometest
:cmd:.
koch temp
:cmd: will build the temporary compiler with the -d:debug
:option:
enabled. Here are compiler options that are of interest when debugging:
-d:debug
:option:: enables assert
statements and stacktraces and all
runtime checks--opt:speed
:option:: build with optimizations enabled--debugger:native
:option:: enables --debuginfo --lineDir:on
:option: for using
a native debugger like GDB, LLDB or CDB-d:nimDebug
:option: cause calls to quit
to raise an assertion exception-d:nimDebugUtils
:option:: enables various debugging utilities;
see compiler/debugutils
-d:stacktraceMsgs -d:nimCompilerStacktraceHints
:option:: adds some additional
stacktrace hints; see https://github.com/nim-lang/Nim/pull/13351-u:leanCompiler
:option:: enable JS and doc generationAnother method to build and run the compiler is directly through koch
:cmd::
koch temp [options] c test.nim
# (will build with js support)
koch temp [options] js test.nim
# (will build with doc support)
koch temp [options] doc test.nim
"Printf debugging" is still the most appropriate way to debug many problems arising in compiler development. The typical usage of breakpoints to debug the code is often less practical, because almost all code paths in the compiler will be executed hundreds of times before a particular section of the tested program is reached where the newly developed code must be activated.
To work around this problem, you'll typically introduce an if statement in the
compiler code detecting more precisely the conditions where the tested feature
is being used. One very common way to achieve this is to use the mdbg
condition,
which will be true only in contexts, processing expressions and statements from
the currently compiled main module:
# inside some compiler module
if mdbg:
debug someAstNode
Using the isCompilerDebug
:nim: condition along with inserting some statements
into the testcase provides more granular logging:
# compilermodule.nim
if isCompilerDebug():
debug someAstNode
# testcase.nim
proc main =
{.define(nimCompilerDebug).}
let a = 2.5 * 3
{.undef(nimCompilerDebug).}
Logging can also be scoped to a specific filename as well. This will of course match against every module with that name.
if `??`(conf, n.info, "module.nim"):
debug(n)
The above examples also makes use of the debug
:nim: proc, which is able to
print a human-readable form of an arbitrary AST tree. Other common ways to print
information about the internal compiler types include:
# pretty print PNode
# pretty prints the Nim ast
echo renderTree(someNode)
# pretty prints the Nim ast, but annotates symbol IDs
echo renderTree(someNode, {renderIds})
# pretty print ast as JSON
debug(someNode)
# print as YAML
echo treeToYaml(config, someNode)
# pretty print PType
# print type name
echo typeToString(someType)
# pretty print as JSON
debug(someType)
# print as YAML
echo typeToYaml(config, someType)
# pretty print PSym
# print the symbol's name
echo symbol.name.s
# pretty print as JSON
debug(symbol)
# print as YAML
echo symToYaml(config, symbol)
# pretty print TLineInfo
lineInfoToStr(lineInfo)
# print the structure of any type
repr(someVar)
Here are some other helpful utilities:
# how did execution reach this location?
writeStackTrace()
These procs may not already be imported by the module you're editing. You can import them directly for debugging:
from astalgo import debug
from types import typeToString
from renderer import renderTree
from msgs import `??`
Stepping through the compiler with a native debugger is a very powerful tool to
both learn and debug it. However, there is still the need to constrain when
breakpoints are triggered. The same methods as in [Debug logging] can be applied
here when combined with calls to the debug helpers enteringDebugSection()
:nim:
and exitingDebugSection()
:nim:.
#. Compile the temp compiler with --debugger:native -d:nimDebugUtils
:option:
#. Set your desired breakpoints or watchpoints.
#. Configure your debugger:
source tools/compiler.gdb
at startupcommand source tools/compiler.lldb
at startup
#. Use one of the scoping helpers like so: if isCompilerDebug():
enteringDebugSection()
else:
exitingDebugSection()
A caveat of this method is that all breakpoints and watchpoints are enabled or disabled. Also, due to a bug, only breakpoints can be constrained for LLDB.
Nim uses the classic compiler architecture: A lexer/scanner feeds tokens to a parser. The parser builds a syntax tree that is used by the code generators. This syntax tree is the interface between the parser and the code generator. It is essential to understand most of the compiler's code.
Semantic analysis is separated from parsing.
.. include:: filelist.txt
The syntax tree consists of nodes which may have an arbitrary number of children. Types and symbols are represented by other nodes, because they may contain cycles. The AST changes its shape after semantic checking. This is needed to make life easier for the code generators. See the "ast" module for the type definitions. The macros module contains many examples how the AST represents each syntactic structure.
Nim has two different runtimes, the "old runtime" and the "new runtime". The old
runtime supports the old GCs (markAndSweep, refc, Boehm), the new runtime supports
ARC/ORC. The new runtime is active when defined(nimV2)
.
T
, unless they are
pointers/references which start with P
.import package
:nim: over from package import symbol
:nim:.See also the API naming design document.
Porting Nim to a new architecture is pretty easy, since C is the most portable programming language (within certain limits) and Nim generates C code, porting the code generator is not necessary.
POSIX-compliant systems on conventional hardware are usually pretty easy to
port: Add the platform to platform
(if it is not already listed there),
check that the OS, System modules work and recompile Nim.
The only case where things aren't as easy is when old runtime's garbage
collectors need some assembler tweaking to work. The default
implementation uses C's setjmp
:c: function to store all registers
on the hardware stack. It may be necessary that the new platform needs to
replace this generic code by some assembler code.
Files that may need changed for your platform include:
compiler/platform.nim
Add os/cpu properties.lib/system.nim
Add os/cpu to the documentation for system.hostOS
and system.hostCPU
.compiler/options.nim
Add special os/cpu property checks in isDefined
.compiler/installer.ini
Add os/cpu to Project.Platforms
field.lib/system/platforms.nim
Add os/cpu.std/private/osseps.nim
Add os specializations.lib/pure/distros.nim
Add os, package handler.tools/niminst/makefile.nimf
Add os/cpu compiler/linker flags.tools/niminst/buildsh.nimf
Add os/cpu compiler/linker flags.If the --os
or --cpu
options aren't passed to the compiler, then Nim will
determine the current host os, cpu and endianness from system.cpuEndian
,
system.hostOS
and system.hostCPU
. Those values are derived from
compiler/platform.nim
.
In order for the new platform to be bootstrapped from the csources
, it must:
compiler/platform.nim
updatedcompiler/installer.ini
updatedtools/niminst/buildsh.nimf
updatedtools/niminst/makefile.nimf
updatedcsources
csources
must be pushedcsources
revision must be updated in config/build_config.txt
Note: This section describes the "old runtime".
Runtime type information (RTTI) is needed for several aspects of the Nim programming language:
Garbage collection
: The old GCs use the RTTI for traversing arbitrary Nim types, but usually
only the marker
field which contains a proc that does the traversal.
Complex assignments : Sequences and strings are implemented as pointers to resizable buffers, but Nim requires copying for assignments. Apart from RTTI the compiler also generates copy procedures as a specialization.
We already know the type information as a graph in the compiler.
Thus, we need to serialize this graph as RTTI for C code generation.
Look at the file lib/system/hti.nim
for more information.
The system
module contains the part of the RTL which needs support by
compiler magic. The C code generator generates the C code for it, just like any other
module. However, calls to some procedures like addInt
are inserted by
the generator. Therefore, there is a table (compilerprocs
)
with all symbols that are marked as compilerproc
. compilerprocs
are
needed by the code generator. A magic
proc is not the same as a
compilerproc
: A magic
is a proc that needs compiler magic for its
semantic checking, a compilerproc
is a proc that is used by the code
generator.
Code generation for closures is implemented by lambda lifting
:idx:.
A closure
proc var can call ordinary procs of the default Nim calling
convention. But not the other way round! A closure is implemented as a
tuple[prc, env]
. env
can be nil implying a call without a closure.
This means that a call through a closure generates an if
but the
interoperability is worth the cost of the if
. Thunk generation would be
possible too, but it's slightly more effort to implement.
Tests with GCC on Amd64 showed that it's really beneficial if the 'environment' pointer is passed as the last argument, not as the first argument.
Proper thunk generation is harder because the proc that is to wrap could stem from a complex expression:
receivesClosure(returnsDefaultCC[i])
A thunk would need to call returnsDefaultCC[i]
somehow and that would require
an additional closure generation... Ok, not really, but it requires to pass
the function to call. So we'd end up with 2 indirect calls instead of one.
Another much more severe problem with this solution is that it's not GC-safe
to pass a proc pointer around via a generic ref
type.
Example code:
proc add(x: int): proc (y: int): int {.closure.} =
return proc (y: int): int =
return x + y
var add2 = add(2)
echo add2(5) #OUT 7
This should produce roughly this code:
type
Env = ref object
x: int # data
proc anon(y: int, c: Env): int =
return y + c.x
proc add(x: int): tuple[prc, data] =
var env: Env
new env
env.x = x
result = (anon, env)
var add2 = add(2)
let tmp = if add2.data == nil: add2.prc(5) else: add2.prc(5, add2.data)
echo tmp
Beware of nesting:
proc add(x: int): proc (y: int): proc (z: int): int {.closure.} {.closure.} =
return lambda (y: int): proc (z: int): int {.closure.} =
return lambda (z: int): int =
return x + y + z
var add24 = add(2)(4)
echo add24(5) #OUT 11
This should produce roughly this code:
type
EnvX = ref object
x: int # data
EnvY = ref object
y: int
ex: EnvX
proc lambdaZ(z: int, ey: EnvY): int =
return ey.ex.x + ey.y + z
proc lambdaY(y: int, ex: EnvX): tuple[prc, data: EnvY] =
var ey: EnvY
new ey
ey.y = y
ey.ex = ex
result = (lambdaZ, ey)
proc add(x: int): tuple[prc, data: EnvX] =
var ex: EnvX
ex.x = x
result = (lambdaY, ex)
var tmp = add(2)
var tmp2 = tmp.fn(4, tmp.data)
var add24 = tmp2.fn(4, tmp2.data)
echo add24(5)
We could get rid of nesting environments by always inlining inner anon procs. More useful is escape analysis and stack allocation of the environment, however.
proc getAccumulator(start: int): proc (): int {.closure} =
var i = start
return lambda: int =
inc i
return i
proc p =
var delta = 7
proc accumulator(start: int): proc(): int =
var x = start-1
result = proc (): int =
x = x + delta
inc delta
return x
var a = accumulator(3)
var b = accumulator(4)
echo a() + b()
Lambda lifting is implemented as part of the transf
pass. The transf
pass generates code to set up the environment and to pass it around. However,
this pass does not change the types! So we have some kind of mismatch here; on
the one hand the proc expression becomes an explicit tuple, on the other hand
the tyProc(ccClosure) type is not changed. For C code generation it's also
important the hidden formal param is void*
:c: and not something more
specialized. However, the more specialized env type needs to passed to the
backend somehow. We deal with this by modifying s.ast[paramPos]
to contain
the formal hidden parameter, but not s.typ
!
To be expanded.
In Nim, there is a redundant way to specify the type of an integer literal. First, it should be unsurprising that every node has a node kind. The node of an integer literal can be any of the following values:
nkIntLit, nkInt8Lit, nkInt16Lit, nkInt32Lit, nkInt64Lit,
nkUIntLit, nkUInt8Lit, nkUInt16Lit, nkUInt32Lit, nkUInt64Lit
On top of that, there is also the typ
field for the type. The
kind of the typ
field can be one of the following ones, and it
should be matching the literal kind:
tyInt, tyInt8, tyInt16, tyInt32, tyInt64, tyUInt, tyUInt8,
tyUInt16, tyUInt32, tyUInt64
Then there is also the integer literal type. This is a specific type
that is implicitly convertible into the requested type if the
requested type can hold the value. For this to work, the type needs to
know the concrete value of the literal. For example an expression
321
will be of type int literal(321)
. This type is implicitly
convertible to all integer types and ranges that contain the value
321
. That would be all builtin integer types except uint8
and
int8
where 321
would be out of range. When this literal type is
assigned to a new var
or let
variable, it's type will be resolved
to just int
, not int literal(321)
unlike constants. A constant
keeps the full int literal(321)
type. Here is an example where that
difference matters.
proc foo(arg: int8) =
echo "def"
const tmp1 = 123
foo(tmp1) # OK
let tmp2 = 123
foo(tmp2) # Error
In a context with multiple overloads, the integer literal kind will
always prefer the int
type over all other types. If none of the
overloads is of type int
, then there will be an error because of
ambiguity.
proc foo(arg: int) =
echo "abc"
proc foo(arg: int8) =
echo "def"
foo(123) # output: abc
proc bar(arg: int16) =
echo "abc"
proc bar(arg: int8) =
echo "def"
bar(123) # Error ambiguous call
In the compiler these integer literal types are represented with the
node kind nkIntLit
, type kind tyInt
and the member n
of the type
pointing back to the integer literal node in the ast containing the
integer value. These are the properties that hold true for integer
literal types.
n.kind == nkIntLit
n.typ.kind == tyInt
n.typ.n == n
Other literal types, such as uint literal(123)
that would
automatically convert to other integer types, but prefers to
become a uint
are not part of the Nim language.
In an unchecked AST, the typ
field is nil. The type checker will set
the typ
field accordingly to the node kind. Nodes of kind nkIntLit
will get the integer literal type (e.g. int literal(123)
). Nodes of
kind nkUIntLit
will get type uint
(kind tyUint
), etc.
This also means that it is not possible to write a literal in an
unchecked AST that will after sem checking just be of type int
and
not implicitly convertible to other integer types. This only works for
all integer types that are not int
.