Skip to content

baryluk/dmt

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

37 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

Python-like indentation in D programming language

This is a simple, yet powerful, code translator allowing to use Python-like syntax to write D programs.

It operates by interpreting indents, and some keywords to translate it to a standard D programming language program.

Functions need to be prefixed by def, to make it clear to the parser that they are functions. Other whitelisted constructs do not require that, as they already start with a specific keyword and finish with a colon.

This allows to write D code like this:

import std.stdio

class A:
  public:
  int f
  def this():
    f = 4
    writefln("Constructor")
  def ~this():
    writefln("Deconstructor")

  def void times(int k):
    writefln("%d", k * g())

  private:
  def int g():
    return f + 5

def int main(string[] args):
  auto a = new A()
  a.times(10)
  return 0

See tests/test*.dt files for more examples.

Enjoy.

Usage

By default dmt tool will convert a source code in files ending with the .dt extension, and pass it to a D compiler. By default the dmd compiler will be used. The compiler can be changed by environment variable DMD, for example: DMD=ldc2 dmt test4.dt. If multiple files are passed, they are all converted and passed together to dmd.

Options:

  • --keep - keep transformed temporary files (.d files)
  • --convert - just convert and keep temporary files, do not call dmd or remove files.
  • --overwrite - overwrite temporary files if they already exist
  • --run - compile first .dt source and run it, passing remaining arguments
  • --pipe - transform a single .dt file to .d and output it on a standard output.

*.d and *.o arguments, and all other options starting with a dash, like for example -O, -inline, -c, are passed to dmd untouched in the same order and relations to file as on the dmt command line.

#! (sh-bang) support.

Just add on a first line of the "script" this:

#!/usr/bin/env -S dmt --run

and make the script executable. And make sure that dmt is in your PATH (or use an absolute path to dmt). Extra arguments from the execution will be passed to your script main function as normal.

You can change dmd to ldc2 using DMD=ldc2 environment variable, or do it explicitly in the script #!:

#!/usr/bin/env -S DMD=ldc2 dmt --run

You can also manually run script, by using -run when invoking dmt:

dmt -run foo.dt

You can pass multiple source files if you wish.

Using import std to import entire Phobos is handy, but if you script is on a network connected file system (like sshfs), it will considerably slow down the compilation, as the compiler is trying to find files to import relative to the currently compiled file first, and parse more files too. It is ok for some prototyping, but importing more specific modules is a better long term solution (less likely to break too).

Building

dmt has just one source file: dmt.d. Compile it as you like into executable, using your favorite D compiler.

You can also just use make (if using dmd), or DMD=ldc2 DMDFLAGS= make (if using ldc), or DMD=gdc DMDFLAGS= make (if using gdc).

Indentation

Indentations only follow after a line starts with a specific keyword, and is finished with colon.

For example:

  if (x):
     f()
  ...

Function and methods should be prefixed with def:

def int f(int b, int c):
  ...
  
  
class C:
  def int f():
     ...

If you want to declare a function (i.e. C function) or define an interface method, you can do that on a single line without using def, just be sure not to finish it with the colon. Semicolon (;) is optional and should be avoided, as dmt will add one for you.

extern(C) int g(int a, char* c)

interface IFoo:
  int f()

List of keywords introducing indents (if line finishes with colon):

  • def
  • if, else
  • for, foreach, foreach_reverse
  • while, do
  • struct, union
  • class, interface, abstract class, final class
  • enum (but read limitations section how to use them)
  • template
  • mixin template definition
  • in, out, body sections of a function, method or interface contract
  • invariant
  • try, catch, finally
  • switch, final switch
    • case and default can be indented or not, your choice
  • with
  • scope(exit), scope(failure), scope(success)
    • only these three, with no spaces between tokens.
  • synchronized
  • static if, static foreach, static foreach_reverse
  • version
  • unittest
  • asm

Note: scope class (storage type constraint on class instances) is not supported, becasue it is officially deprecated feature of the language, and might be removed in the future. If you really want to use it, use def scope class ...:

Note: public:, private:, protected:, package:, export:, extern(...):, pragma(.....):, @nogc:, nothrow:, @trusted:, @safe, pure:, @system:, @live, @property, static:, extern:, abstract:, final:, override:, auto: (yikes!), shared:, __gshared: and similar existing attributes used in attribute: form, or user defined UDAs, neighter allow new indent level by themselves, nor they introduce any {}-style block for subsequent statement. However, if set in some specific scope, they only applies to the definitions in that scope, at that nesting level, up until the end of that scope. This is the same semantic as in a normal D programming language.

This allows easier changing of attributes for subsequent symbols and declaration in the module, classes and other places, which IMHO is more common form than, block style changes of attributes.

So for example in following class:

class A:
  private:
  int a
  float b
  public string c
  def auto sum():
    return a + b

members, a, b, sum will be private. c will be public.

If you want, you can use line continuation form together with def: still to achive block-level change:

class A:
  private \
  def:
    int a
    float b
    public string c
  def auto sum():
    return a + b

In this case, a and b will be private, but sum and c will be public (sum because this is a default visibility level, and c because it was explicitly set so more specifically).

Multi-line array literls and expressions

Arrays and associative arrays, unfortunately can't be formatted with alignment or indents at the moment:

int[] a = [
  1,
  2,
  3,
]

will not work. Sorry.

enums

Also enum support is limited, but can be done with some workarounds:

enum E { A, B, }
enum E:
  A, \
  B \

Line-end continuation:

Examples:

  def auto f():
     return x + \
     y + z

and

  def auto f():
     return x + \
            y + z

Multi-line alignment using line-end continuation

Examples:

writeln(a, b, \
        c + 5)
int z = (a + b + \
         c + d)

Indentation semantics

You can use space or tabs, or mix of them. But consistency is required for matching indent levels.

If you open a new indent level, the next line must have the same indent as the previous line + new indent.

So for example, this is allowed:

  if (a):
  \tif (b):
  \t  if (c):
  \t    f(a, b, c)

but this is not:

  if (a):
  \tif (b):
      if (c)
  \t    f(a, b, c)

Also, the if/else, in/out/body, case/default, try/catch/finally must match properly:

This is ok:

  if (a):
    if (b):
      f(a, b)
  else:
    f(0, 0)

but this is not:

  if (a):
    if (b):
      f(a, b)
   else:
     f(0, 0)

Indentations INSIDE the if/else (and other matching ones) blocks can differ if you want.

This is ok, but is not recommended:

  if (a):
    f(a)
  else:
       f(0)

Multi-statement lines. You can put multiple statements on a line, by simply using semicolon:

  if (a):
    f(a); g(a)
  else:
       f(0); g(0)

You should avoid putting a semicolon (;) after the last statement, as this will most likely trigger a D compiler warning.

Empty blocks. You can put an empty block, by not indenting, or by putting manually {} as an empty statement:

  while (a-- && b--):
  writefln(a, b)

or more readable:

  while (a-- && b--):
    {}
  writefln(a, b)

If you are unhappy with this form, create a nop function called pass, and do:

  while (a-- && b--):
    pass
  writefln(a, b)

Non-indented forms. It is possible to do non-indented forms, by omitting the colon at end, like:

  if (a) f(a)
  while (a--) writefln(a)

Note, that you can't do more than one statement, unless you actually put it in brackets

  if (a) f(a); g(a)    // WRONG / MISLEADING

Because, this will call g even if f is not called. This is because this code is literally translated to D just like on the input (plus semicolon at the end).

Use instead:

  if (a) { f(a); g(a); }  // BETTER

For the same reason, you should be careful about opening curly brackets

  if (a) { f(a);
  g(a); }

It works, but defeats the entire purpose of the dmt.

Also, at the moment dmt is kind of all or nothing. You can't just throw an existing D code into it, because it most likely has indent in it, that will not work. At least dmt will detect it:

  if (a) {
    f(a);    // UNEXPECTED INDENT
    g(a);
  }

In the future it might be possible to add pragma or comment based directives, to enable / disable dmt processing.

Another issue is commenting blocks of code:

def void f(int a):
  /+
  if (a):
    return 5;
  else:
    if (a > 10):
      return a * 10
    return 1
  +/

Will not-work. Because of unexpected indent in the processed lines.

The line continuation marker (\ at the end of the line), allows you do indent next line arbitarly, and does not introduce the { in translated code. The line continuation can be continued on subsequent lines, but should respect indentations and de-indentations.

writeln(a + (c \
             + d * (x \
                    - y) \
             + e))

should work. Additionally, it is allowed to put line comments (block comments will lead to unintended results) between such lines:

auto x = a \
         + b \
         // foo bar
         + c \
         + d

(this is somehow implicit - the semicolon will be inserted, but because it is in a comment, it will not be a problem).

If you want to split a template or function signature declaration across multiple lines, use this trick:

int f(int a, int b, \
      int c, int d) \
def:
  return a + b + c + d

(do can also be used instead of def).

Short term TODO

  • Refactor convert API to allow unittests of it.
  • Once refactored, make convert functionality available as a CTFE-able function. Together with q{} strings and import() expressions, this could be really cool.
  • Add directives and flags and environment variables to enforce indent style (i.e. tabs, spaces, amount, etc)
  • Make dmt self hosting (dmt.d converted to dmt.dt, and provide a bootstrap binary, or a simplified / older implementation of dmt.d, to do a bootstrap process)
  • Parse comments better and handle them properly.
  • Improve support for function / method contracts (in, out, do, body), with line-continuations it now works, but would be nice to make it even better
  • Syntax highlighting and auto-indent hints for mcedit, vim, emacs and vs code
  • Convert to a dub package?
  • Enforce same alignment of case and default in switch. This is should be possible to disable tho, because of ability to add switch case cases using static foreach for example
  • Enforce catch and finally to have same indent as try, similar how else needs to have same indent as if.
  • Once gdc compiler catches up and supports do (instead of body). DMD 2.097.0 will start producing deprecation notices about usage of body. Once this is in gdc, we can also start using body as identifier, instead of bdy (i.e. in decompose and convert).
  • Similarly once gdc compiler supports "new" short style versions of function contracts (in (AssertExpression), out ([ref] ident; AssertExpression)), convert to using them.

Speed

There was no profiling or deeper optimizations done yet with dmt, but on my machine in release mode, it processes 1.14 million lines per second, and processes 37MB/s (this is quite dependent on the average line length in the source file) from the input. Pretty good. This certainly can be improved, but is plenty fast, and for big projects with many files, the conversion process can be fully parallelized in the build system. A moderatly complex module with 1000 lines converts in just 5ms.

Limitations and notices

Note that some features familiar from Python, are not implemented and not supported. They might be supported in the future, but that will require a more complex parser. Some examples are listed below.

Multi-line alignment limitations

def auto f(a, b,
           c, d):
  // ...

will not work.

This is unlikely to be implemented. It is quite limiting and can be annoying, but at the same time, some might argue it is a good thing. Just keep your lines reasonably short, or assign sub-expression to own variables.

This could be easily resolved for the majority of cases, but probably will not be implemented.

For statements and expressions, as a work around, simply put everything on a single line, or use line continuations:

auto x = f(a, b, \
           c, d)

For function, method, class, templates, and other definitions / declarations, maybe try this:

auto f(a, b, \
       c, d) \
def:
   // ...

or for functions and methods specifically:

auto f(a, b, \
       c, d) \
do:
   // ...

(do is equivalent to body).

Other example:

class A : B, \
          C!int, \
          D!int \
def:
   def int f():
     return 1

Empty aggregate definitions

A trick might be to use a dummy private: or a comment.

def class A:
  private:
def interface I:
  // nothing

using {}, will not work, because directly inside aggregate declarations are expected, not BlockStatement.

Mixed colon and single line statements

Note, that this will definitely not work or be implemented:

  if (a): f(a)
  if (a): f(a); f(b)
  while (a--): writefln(a); f(a)

because, it is really tricky to parse without a full D language parser.

Multi-line comments

Multi-line comments using block comments are limited. Each line must not start with space, and must be all aligned to same as first line:

/** Foo
 * bar
 */

is not allowed, because a second line is indented more than the first one.

/** Foo
** bar
**/

could work. Other option is to do this:

/*
Foo
bar
*/

Note, however, that dmt adds a semicolon (;) at the end of each line, so this is equivalent to:

/*;
Foo;
bar;
*/;

Note the semicolon at the very end of the last line. This could be important if you put a comment after for example if statement, without curly braces:

  if (a)
  /*
  Foo
  bar
  */
  g()

In this case the body of if will be EMPTY. And g will be called unconditionally.

Do not do silly things. And just use //-style comments if possible.

Also mentioned before, you might opt out of some indenting features, but that makes it awkward and not nice at all:

  if (a) {
  f(a)
  } else {
  g(a)
  }

Do not do that. Hopefully in the future, dmt will actually reject such constructs.

Multi-line string literals

Multi-line string literals / raw literals, and quoted tokens, will often not work properly:

  int a = "foo
bar
baz"

will make the dmt confused, and generate an error.

Only option is to use string concatenation operator (~) together with explicit line continuation (to prevent emitting a semicolon by dmt):

  int a = "foo\n" \
  ~ "bar\n" \
  ~ "baz"

That however, requires implementing multi-line continuation first in dmt.

Multi-line formatted arrays / lists

Multi-line formatted arrays / lists, like this:

  auto a = [
     "foo": 1,
     "bar": 3,
  ]

will not work. Sorry.

One of the easier option is to introduce explicit keyword, and maybe do this:

  def_array auto a = [
  ]

Comments after colon

Comments are not supported after a colon (:)

  foreach (a; l):  // iterate list
    f(a)

will not work.

Functions and delegate literals

  int a = 5
  auto l = delegate int(int b):
    return a + b

will not work.

  int a = 5
  auto l = delegate int(int b) {\
  return a + b
  }

is an option probably, so is:

  int a = 5
  auto l = delegate int(int b) \
  def:
    return a + b
  ;

(Note explicit semicolon ; after finishing the def: block, to finish the assignment statement.)

Other option is to abandon anonymous delegates, and define named inner function:

  int a = 5;
  def int f(int b):
    return a + b
  auto l = &f

Some annotations on declarations are not easily possible

extern (C++) interface IFoo:
  ...

private class X:
  ...

To work around this, simply add a def at the start:

def extern (C++) interface IFoo:
  ...

def private class X:
  ...

Inline assembler

asm can be used, but all instructions and labels must be at the same level of indentation:

asm:
    call L1
    L1:
    pop  EBX
    mov  pc[EBP],EBX ; // pc now points to code at L1

A scope block

There is no easy way to introduce a new local scope. Just use if (true) for the moment:

if (true):
  auto x = 6
  writefln(x)
// writefln(x)  // x not in local scope.

or better def with nothing after:

def:
  auto x = 6
  writefln(x)
// writefln(x)  // x not in local scope.

It is a bit awkward, but works.

Enums

Named and anonymous enum definitions are not currently supported:

enum X:
  A,
  B,
  C

The reason is because they require commas at the end of each line, but dmt inserts semicolons at the end of each such line. Possible solutions would be make special case for enum indents, but that requires more than a simple one-level hack, because of things like this:

enum X:
  A = 1
  version(a):
    B = 5
  else:
    B = 9

One of the options would be to explicitly prefix enumerations with some keyword:

enum X:
  enumvalue A = 1
  version(a):
    enumvalue B = 5
  else:
    enumvalue B = 9

This should also be possible then (because trailing commas are ok):

enum X:
  enumvalue A, B, C
  enumvalue D, E, F

As a workaround use line continuations:

enum X:
  A, \
  B, \
  C \

The line continuation marker is required after the last element of the enum too, even if it is end of the file. It is safe to de-indent on a next line:

enum X:
  A, \
  B, \
  C \
enum Y:
  F, \

Unittests

To add attributes to unittests, use def:

def @safe nothrow unittest:
  {}
/// Bzium
def private unittest:
  {}

parentheses in if, while, for, ...

At the moment, it is required to put parentheses around the conditions, just like in D:

  if (a > 5 && b > 3):
    f()

but it should not be hard to allow also these forms:

  if a > 5 && b > 3:
    f()

At the moment it is not supported. This requires a bit of evaluation, to not hide possible coding errors, like if (a = 5):, which are currently detected by D compilers.

@disabled functions / methods

Simply do not use def for declaration of @disabled functions

class C:
  @disable int foo();

because def requires colon and opens a new scope:

class C:
  def @disable int foo():
    return int.init;

and that will most likely upset the compiler. Making the return type a void could help.

Function contracts

Unfortunately, dmt at the moments does not support contracts.

def int f(int b):
  in:
    assert(b < 10)
  out (ret):
    assert(ret < 1000)
  do:
    return b * b * b
def int f(int b):
  in (b < 10)
  out (ret; ret < 1000)
  body:
    return b * b * b

unfortuantely will not compile. A workaround is to use line-continuations in a bit hacky, but a reasonable way:

int f(int b) \
in:
  assert(b < 10)
out (ret):
  assert(ret < 1000)
do:
  return b * b * b
def int f(int b) \
in (b < 10) \
out (ret; ret < 1000) \
body:
  return b * b * b

Pipeline / UCFS heavy range processing is tricky:

A D code like this:

import std.stdio, std.array, std.algorithm;

void main() {
    stdin
        .byLineCopy
        .array
        .sort!((a, b) => a > b) // descending order
        .each!writeln;
}

is somehow tricky to convert to dmt format, without introducing ugly code:

import std.stdio, std.array, std.algorithm

def void main():
    stdin \
        .byLineCopy \
        .array \
        .sort!((a, b) => a > b) \
        .each!writeln

Releases

No releases published

Packages

No packages published