Native shebang
In short: Use the specimen language (native) for "scripting".
- Example
- If your language is "foo", then the test case of "echo.foo" runs in a terminal as "./echo.foo Hello, world!".
In long: Create a program (in the specimen language) that will automatically compile a test case (of the same specimen language) to a native binary executable and then transparently load and run this test case executable.
Make it so that all that is required is a custom shebangs at the start of the test case. e.g. "#!/usr/local/bin/script_foo"
Importantly: This task must be coded strictly in the specimen language, neither using a shell script nor any other 3rd language.
Optimise this progress so that the test program binary executable is only created if the original test program source code as been touched/edited.
Note: If the lauguage (or a specific implementation) handles this automatically, then simple provide an example of "echo.foo"
Background:
Simple shebangs can help with scripting, e.g. "#!/usr/bin/env python" at the top of a Python script will allow it to be run in a terminal as "./script.py".
The task Multiline shebang largely demonstrates how to use "shell" code in the shebang to compile and/or run source-code from a 3rd language, typically "#!/bin/bash" or "#!/bin/sh".
This task:
However in this task Native shebang task we are go native. In the shebang, instead of running a shell, we call a binary-executable generated from the original native language, e.g. when using C with gcc "#!/usr/local/bin/script_gcc" to extract, compile and run the native "script" source code.
Other small innovations required of this Native shebang task:
- Cache the executable in some appropriate place in a path, dependant on available write permissions.
- Generate a new cached executable only when the source has been touched.
- If a cached is available, then run this instead of regenerating a new executable.
Difficulties:
- Naturally, some languages are not compiled. These languages are forced to use shebang executables from another language, eg "#!/usr/bin/env python" uses the C binaries /usr/bin/env and /usr/bin/python. If this is the case, then simply document the details of the case.
- In a perfect world, the test file (e.g. echo.c) would still be a valid program, and would compile without error using the native compiler (e.g. gcc for text.c). The problem is that "#!" is syntactically incorrect on many languages, but in others it can be parsed as a comment.
- The "test binary" should be exec-ed and hence retain the original Process identifier.
Test case:
- Create a simple "script file" (in the same native language) called "echo" then use the "script" to output "Hello, world!"
ALGOL 68
Using ALGOL 68G to script ALGOL 68G
Note: With Algol68G the option "-O3" will compile the script file to a ".so" file, this ".so" file is a binary executable and dynamically loaded library. Also note that this ".so" will only be generated if the ".a68" source file has been touched.
File: echo.a68
#!/usr/bin/a68g --script #
# -*- coding: utf-8 -*- #
STRING ofs := "";
FOR i FROM 4 TO argc DO print((ofs, argv(i))); ofs:=" " OD
Test Execution:
$ ./echo.a68 Hello, world!
- Output:
Hello, world!
Arturo
Arturo is a scripting language and does not compile to a binary.
#!/usr/bin/env arturo
print "Hello from Arturo!"
- Output:
$> ./native_shebang.art Hello from Arturo!
C
Using gcc to script C
I was able to get this functional, by renaming the itoa() function to itoa_() NOTE, there is an itoa() function already. I will also write a 'correct' 2nd version of this example, that does not use a bash helper script (no reason for that). --JimF
File: script_gcc.c
#!/usr/local/bin/script_gcc.sh
/* Optional: this C code initially is-being/can-be boot strapped (compiled) using bash script_gcc.sh */
#include <errno.h>
#include <libgen.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/stat.h>
#include <unistd.h>
/* the actual shebang for C target scripts is:
#!/usr/local/bin/script_gcc.c
*/
/* general readability constants */
typedef char /* const */ *STRING;
typedef enum{FALSE=0, TRUE=1} BOOL;
const STRING ENDCAT = NULL;
/* script_gcc.c specific constants */
#define DIALECT "c" /* or cpp */
const STRING
CC="gcc",
COPTS="-lm -x "DIALECT,
IEXT="."DIALECT,
OEXT=".out";
const BOOL OPT_CACHE = TRUE;
/* general utility procedured */
char strcat_out[BUFSIZ];
STRING STRCAT(STRING argv, ... ){
va_list ap;
va_start(ap, argv);
STRING arg;
strcat_out[0]='\0';
for(arg=argv; arg != ENDCAT; arg=va_arg(ap, STRING)){
strncat(strcat_out, arg, sizeof strcat_out);
}
va_end(ap);
return strndup(strcat_out, sizeof strcat_out);
}
char itoa_out[BUFSIZ];
STRING itoa_(int i){
sprintf(itoa_out, "%d", i);
return itoa_out;
}
time_t modtime(STRING filename){
struct stat buf;
if(stat(filename, &buf) != EXIT_SUCCESS)perror(filename);
return buf.st_mtime;
}
/* script_gcc specific procedure */
BOOL compile(STRING srcpath, STRING binpath){
int out;
STRING compiler_command=STRCAT(CC, " ", COPTS, " -o ", binpath, " -", ENDCAT);
FILE *src=fopen(srcpath, "r"),
*compiler=popen(compiler_command, "w");
char buf[BUFSIZ];
BOOL shebang;
for(shebang=TRUE; fgets(buf, sizeof buf, src); shebang=FALSE)
if(!shebang)fwrite(buf, strlen(buf), 1, compiler);
out=pclose(compiler);
return out;
}
void main(int argc, STRING *argv, STRING *envp){
STRING binpath,
srcpath=argv[1],
argv0_basename=STRCAT(basename((char*)srcpath /*, .DIALECT */), ENDCAT),
*dirnamew, *dirnamex;
argv++; /* shift */
/* Warning: current dir "." is in path, AND * /tmp directories are common/shared */
STRING paths[] = {
dirname(strdup(srcpath)), /* not sure why strdup is required? */
STRCAT(getenv("HOME"), "/bin", ENDCAT),
"/usr/local/bin",
".",
STRCAT(getenv("HOME"), "/tmp", ENDCAT),
getenv("HOME"),
STRCAT(getenv("HOME"), "/Desktop", ENDCAT),
/* "/tmp" ... a bit of a security hole */
ENDCAT
};
for(dirnamew = paths; *dirnamew; dirnamew++){
if(access(*dirnamew, W_OK) == EXIT_SUCCESS) break;
}
/* if a CACHEd copy is not to be kept, then fork a sub-process to unlink the .out file */
if(OPT_CACHE == FALSE){
binpath=STRCAT(*dirnamew, "/", argv0_basename, itoa_(getpid()), OEXT, ENDCAT);
if(compile(srcpath, binpath) == EXIT_SUCCESS){
if(fork()){
sleep(0.1); unlink(binpath);
} else {
execvp(binpath, argv);
}
}
} else {
/* else a CACHEd copy is kept, so find it */
time_t modtime_srcpath = modtime(srcpath);
for(dirnamex = paths; *dirnamex; dirnamex++){
binpath=STRCAT(*dirnamex, "/", argv0_basename, OEXT, ENDCAT);
if((access(binpath, X_OK) == EXIT_SUCCESS) && (modtime(binpath) >= modtime_srcpath))
execvp(binpath, argv);
}
}
binpath=STRCAT(*dirnamew, "/", argv0_basename, OEXT, ENDCAT);
if(compile(srcpath, binpath) == EXIT_SUCCESS)
execvp(binpath, argv);
perror(STRCAT(binpath, ": executable not available", ENDCAT));
exit(errno);
}
Test Source File: echo.c
#!/usr/local/bin/script_gcc.c
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
int main(int argc, char **argv, char **envp){
char ofs = '\0';
for(argv++; *argv; argv++){
if(ofs)putchar(ofs); else ofs=' ';
fwrite(*argv, strlen(*argv), 1, stdout);
}
putchar('\n');
exit(EXIT_SUCCESS);
}
Test Execution:
$ ./echo.c Hello, world!
- Output:
Hello, world!
2nd version. Pure C, no extra bash script
File: script_gcc.c
/*
* rosettacode.org: Native shebang
*
* Copyright 2015, Jim Fougeron. Code placed in public domain. If you
* use this, please provide attribution to author. Code originally came
* from the code found on rosettacode.org/wiki/Native_shebang, however
* the code was about 80% rewritten. But the logic of the compile()
* function still strongly is based upon original code, and is a key
* part of the file.
*
* Native C language shebang scripting. Build this program to /usr/local/bin
* using:
* gcc -o/usr/local/bin/script_gcc script_gcc.c
*
* The name of the executable: "script_gcc" IS critical. It is used in knowing
* that we have have found the proper shebang file when parsing commandline
*
* the actual shebang for executable C source scripts is:
#!/usr/local/bin/script_gcc [extra compile/link options]
* If there additional lib's needed by your source file, then add the proper
* params to the shebang line. So for instance if gmp, openssl, and zlib
* were needed (and an additional include path), you would use this shebang:
#!/usr/local/bin/script_gcc -lgmp -lssl -lcrypto -lz -I/usr/local/include
* NOTE, we leak strdup calls, but they are 1 time leaks, and this process
* will simply exec another process, so we ignore them.
*/
#include <errno.h>
#include <libgen.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/stat.h>
#include <unistd.h>
#define shebangNAME "script_gcc"
#define CC "gcc"
#define CC_OPTS "-lm -x c"
#define IEXT ".c"
#define OEXT ".out"
/* return time of file modification. If file does not exit, return 0
* so that if we compare, it will always be older, and will be built */
time_t modtime(const char *filename) {
struct stat st;
if(stat(filename, &st) != EXIT_SUCCESS)
return 0;
return st.st_mtime;
}
/* join a pair of strings */
char *sjoin(const char *s1, const char *s2){
char buf[BUFSIZ];
if (!s1) s1=""; if (!s2) s2="";
snprintf(buf, sizeof(buf), "%s%s", s1, s2);
return strdup(buf);
}
/* compiles the original script file. It skips the first line (the shebang)
* and compiles using "gcc .... -x c -" which avoids having to write a temp
* source file (minus the shebang), we instead pipe source to gcc */
int compile(const char *srcpath, const char *binpath, const char *ex_comp_opts) {
char buf[BUFSIZ];
FILE *fsrc, *fcmp;
sprintf(buf, "%s %s %s -o %s -", CC, CC_OPTS, ex_comp_opts, binpath);
fsrc=fopen(srcpath, "r");
if (!fsrc) return -1;
fcmp=popen(buf, "w"); /* open up our gcc pipe to send it source */
if (!fcmp) { fclose(fsrc); return -1; }
/* skip shebang line, then compile rest of the file. */
fgets(buf, sizeof(buf), fsrc);
fgets(buf, sizeof(buf), fsrc);
while (!feof(fsrc)) {
fputs(buf, fcmp); /* compile this line of source with gcc */
fgets(buf, sizeof(buf), fsrc);
}
fclose(fsrc);
return pclose(fcmp);
}
/* tries to open the file 'argv0'. If we can open that file we read first line
* and make SURE it is a script_gcc file. If it is a script_gcc file, we
* look for any extra params for the compiler (params to the shebang line)
* and if we find them, they are returned in ex_comp_opts.
* return 0 if this is NOT a shebang file, return 1 if it IS the shebang file.
*/
int load_shebangline(const char *argv0, char **ex_comp_opts) {
char opt[BUFSIZ], *cp;
FILE *in = fopen(argv0, "r");
if (!in) return 0;
fgets(opt, sizeof(opt), in);
fclose(in);
/* ok, we found a readable file, but IS it our shebang file? */
strtok(opt, "\r\n");
if (strncmp(opt, "#!", 2) || !strstr(opt, shebangNAME))
return 0; /* nope, keep looking */
cp = strstr(opt, shebangNAME)+strlen(shebangNAME);
if (*cp) /* capture compiler extra params, if any */
*ex_comp_opts = strdup(cp);
return 1;
}
/* NOTE, the argv[] array is different than 'normal' C programs. argv[0] is
* the shebang exe file. then argv[1] ... argv[p] are the params that follow
* the shebang script name (from line1 of the script file). NOTE, some systems
* (Linux, cygwin), will pack all of these options into argv[1] with spaces.
* There is NO 'standard' on exactly what the layout it of these shebang params
* may be, we only know that there will be 0 or more params BEFORE the script
* name (which is the argv[0] we normally 'expect). Then argv[p+1] is the name
* of script being run. NOTE if there are no shebang args, argv[1] will be
* the script file name. The script file name is our expected argv[0], and
* all the params following that are the normal argv[1]...argv[n] we expect.
*/
int main(int argc, char *const argv[]) {
int i;
char exec_path[BUFSIZ], *argv0_basename, *ex_comp_opts=0, **dir,
*paths[] = {
NULL, /* paths[0] will be filled in later, to dir of the script */
"/usr/local/bin",
sjoin(getenv("HOME"), "/bin"),
sjoin(getenv("HOME"), "/tmp"),
getenv("HOME"),
sjoin(getenv("HOME"), "/Desktop"),
/* . and /tmp removed due to security concerns
".",
"/tmp", */
NULL
};
/* parse args, looking for the one that is the script. This would have been argv[0] if not exec'd as a shebang */
for (i = 1; i < argc; ++i) {
if (load_shebangline(argv[1], &ex_comp_opts)) {
argc -= i;
i = 0;
break;
}
++argv;
}
if (i)
return !fprintf(stderr, "could not locate proper %s shebang file!!\n", shebangNAME) | ENOENT;
++argv;
/* found it. Now argv[0] is the 'script' name, and rest of argv[] is params to the script */
argv0_basename = basename(strdup(argv[0]));
paths[0] = dirname(strdup(argv[0]));
/* find a cached version of the script, and if we find it, run it */
for(dir = paths; *dir; dir++) {
snprintf(exec_path, sizeof(exec_path), "%s/%s%s", *dir, argv0_basename, OEXT);
if(modtime(exec_path) >= modtime(argv[0]))
execvp(exec_path, argv); /* found a newer cached compiled file. Run it */
}
/* no cached file, or script is newer. So find a writeable dir */
for(dir = paths; *dir; dir++) {
if(!access(*dir, W_OK))
break;
}
if (!*dir)
return !fprintf(stderr, "No writeable directory for compile of the script %s\n", argv[0]) | EACCES;
/* compile and exec the result from our C script source file */
snprintf(exec_path, sizeof(exec_path), "%s/%s%s", *dir, argv0_basename, OEXT);
if(!compile(argv[0], exec_path, ex_comp_opts))
execvp(exec_path, argv);
return !fprintf(stderr, "%s : executable not available\n", exec_path) | ENOENT;
}
Test Source File: echo.c
#!/usr/local/bin/script_gcc
/*
* note, any additional libs or include paths would have params added after
* the script_gcc parts of the shebang line, such as:
* #!/usr/local/bin/script_gcc -lgmp -I/usr/local/include/gmp5
*/
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
int main(int argc, char **argv, char **envp){
char ofs = '\0';
for(argv++; *argv; argv++){
if(ofs)putchar(ofs); else ofs=' ';
fwrite(*argv, strlen(*argv), 1, stdout);
}
putchar('\n');
exit(EXIT_SUCCESS);
}
Test Execution:
$ ./echo.c Hello, world!
- Output:
Hello, world!
Forth
Such functionality can be added easily by the following definition:
: #! [COMPILE] \ ; immediate
Some Forth compilers - like 4tH or Gforth - support this functionality out of the box. This example program works as advertised:
#! /usr/local/bin/4th cxq
argn 1 ?do i args type space loop cr
FreeBASIC
#include once "file.bi"
Function GetCachePath(sourceFile As String) As String
Return Exepath & "\cache\" & sourceFile & ".exe"
End Function
Function NeedsRecompile(sourceFile As String, cacheFile As String) As Boolean
If Fileexists(cacheFile) = 0 Then Return True
Return Filedatetime(sourceFile) > Filedatetime(cacheFile)
End Function
Function CompileSource(sourceFile As String, cacheFile As String) As Boolean
Dim As String cmd = "fbc -x " & cacheFile & " " & sourceFile
Return Shell(cmd) = 0
End Function
' Main script handler
Dim sourceFile As String = Command(1)
If Len(sourceFile) = 0 Then End 1
' Create cache directory if needed
Mkdir Exepath & "\cache"
' Get cache path and check if recompilation needed
Dim As String cacheFile = GetCachePath(sourceFile)
If NeedsRecompile(sourceFile, cacheFile) Then
If CompileSource(sourceFile, cacheFile) = 0 Then End 1
End If
' Execute cached binary with arguments
Dim As String args = ""
For i As Integer = 2 To __fb_argc__-1
args &= " " & Command(i)
Next
Shell(cacheFile & args)
Free Pascal
Since FPC (FreePascal compiler) version 2.6.0 the distribution – e.g. the Debian or FreeBSD packages fpc-utils – come with the program instantfpc(1), or ifpc(1) for short. The program fulfills this task’s specifications, plus other goodies. The sources are available in trunk/utils/instantfpc/instantfpc.pas and are not repeated here. See the FreePascal wiki for ifpc usage.
Go
In Go, single line comments can only begin with // and so we have to use the former in place of a normal shebang (#!) to achieve the same effect.
The 'go run' command compiles a .go source code file to a binary executable and then runs the latter automatically. The executable is placed in a temporary directory which is then deleted when the process ends.
To cache the executable in the current directory, one would have to use 'go build' instead (replace the opening line with ///usr/bin/env go build echo.go; ./echo "$@"; exit).
The following works fine on Ubuntu 16.04.
///usr/bin/env go run echo.go "$@"; exit
package main
import (
"fmt"
"os"
)
func main() {
if len(os.Args) > 1 {
fmt.Println(os.Args[1])
}
}
- Output:
$ ./echo.go "Hello, world!" Hello, world!
J
As no compiling versions of J are currently available, the binaries are trivially empty and we shall store them in the empty path. We shall use /usr/local/bin/ijconsole (which was compiled using a C compiler) as the J interpreter, and echo each ARGV
as our sample code:
#!/usr/local/bin/ijconsole
echo each ARGV
jq
jq can be invoked on the shebang line, e.g. as
#!/usr/local/bin/jq -M -n -f
or
#!/usr/bin/env jq -M -n -f
Example 1:
$ cat echo.foo
#!/usr/bin/env/jq -M -n -r -f
"Klaatu barada nikto!"
$ ./echo.foo Klaatu barada nikto!
Command-line parameters of a script created with a shebang line in this manner are processed as jq command-line parameters. Thus, instead of being able to invoke the script along the lines of
$ ./echo.foo "Hello world!" # nope
one would have to introduce a named variable to hold the command-line parameter, as illustrated in the next example:
Example 2:
$ cat echo.foo
#!/usr/bin/env/jq -M -n -r -f
$x
- Output:
$ ./echo.foo --arg x "Hello, world!"
Hello, world!
Julia
usage: ./thisfile.jl "hello"
#!/usr/local/bin/julia
# Put the Julia code below this line. It will be compiled and run.
Base.banner()
println(ARGS)
- Output:
_ _ _ _(_)_ | Documentation: https://docs.julialang.org (_) | (_) (_) | _ _ _| |_ __ _ | Type "?" for help, "]?" for Pkg help. | | | | | | |/ _` | | | | |_| | | | (_| | | Version 1.1.1 (2019-05-16) _/ |\__'_|_|_|\__'_| | Official https://julialang.org/ release |__/ hello |
langur
Langur uses a hash mark to start single line comments, so a shebang is not a problem, as the compiler will ignore it.
File: echo.langur
#!/usr/bin/langur
writeln join(_args, by=" ")
Usage:
./echo.langur hello, people
- Output:
hello, people
Nim
Using env
Uses env -S to split up the commandline parameters,which is maybe cheating but apart from that housekeeping this ticks all the boxes:
- it compiles the source code to an executable, if and only if it has changed
- it then runs that executable with the supplied arguments
File: nativeshebang.nim
#!/usr/bin/env -S nim c -r --hints:off
import os,strutils
echo commandLineParams().join(" ")
Usage:
./nativeshebang.nim hello, world
- Output:
hello, world
Using a nim.cfg and/or nim r
Alternatively, accept all the compiler messages, or create a nim.cfg that silences them:
File: nim.cfg
--hints:off
File: nativeshebang2.nims
#!nim r
import os,strutils
echo commandLineParams().join(" ")
Usage:
./nativeshebang2.nim hello, world
- Output:
hello, world
OCaml
OCaml can run in script mode or compiled (compiled to bytecode or native binary).
File: echo.ml
#! /usr/bin/env ocaml
let () =
let argl = Array.to_list Sys.argv in
print_endline (String.concat " " (List.tl argl))
- Output:
$ chmod u+x echo.ml $ ./echo.ml Hello, world! Hello, world!
But we have to remove the shebang if we want to compile the code, or we get an error:
$ ocamlc -c echo.ml File "echo.ml", line 1, characters 0-2: Error: Syntax error
Perl
Perl is a script language. It's natural and easy to script native Perl code.
File: echo.pl
#!/usr/bin/perl
print "@ARGV\n";
Usage:
./echo.pl Hello, world!
- Output:
Hello, world!
Phix
Phix is a hybrid interpreter/compiler, so a shebang adds little value anyway, however should the first line of the main file start with #! it is ignored/skipped. The only difference between interpretation and compilation, apart from the executable file, is a -c flag on the command line, which I recommend omitting unless it proves helpful or necessary. Example (quietly ignored by pwa/p2js, and Phix in general):
#!/path/to/phix
You can also invoke the compiler directly as follows
without js -- (system_exec) string sourcefile = "test.exw", interpreter = get_interpreter(true), cmd = sprintf("%s %s",{interpreter,sourcefile}) integer res = system_exec(cmd)
See also demo/capture_console.exw which redirects stdin/out/err while interpreting a child process.
Python
Extract: "If you need to create a .pyc file for a module that is not imported, you can use the py_compile and compileall modules. The py_compile module can manually compile any module. One way is to use the py_compile.compile function in that module interactively:[1]:"
>>> import py_compile >>> py_compile.compile('echo.py')
File: echo.py
#!/path/to/python
# Although `#!/usr/bin/env python` may be better if the path to python can change
import sys
print " ".join(sys.argv[1:])
Usage:
./echo.py Hello, world!
- Output:
Hello, world!
Racket
Racket has raco: Racket Command Line Tools which can be used to compile to bytecode or compile to standalone executables (along with a whole load of other fun stuff to do with packages, unit testing and the likes).
To properly compile a file/program, one needs to invoke raco or go through invocations of racket to see what needs to be done. Compilation is expensive. Dependency management is expensive and difficult to do. The only one who can probably be trusted to do this is raco. So (as with Python), if you need to compile the program, do so with the compiler.
Once you have done this, however, racket (in the shebang) will use the 'compiled' version, not the source.
In this example:
File native-shebang.rkt contains the following:
#! /usr/local/racket-6.1/bin/racket
#lang racket
(displayln "hello")
My directory contains only this:
-bash-3.2$ ls native-shebang.rkt
Which runs:
-bash-3.2$ ./native-shebang.rkt hello
But has not self-compiled or anything like that:
-bash-3.2$ ls native-shebang.rkt
I run raco to compile it:
-bash-3.2$ raco make native-shebang.rkt -bash-3.2$ ls -R .: compiled native-shebang.rkt ./compiled: native-shebang_rkt.dep native-shebang_rkt.zo
The dependency file and byte-code -- .zo -- file are in a compiled directory.
I still run native-shebang.rkt from the script (with the racket shebang). Racket will use the compiled code instead of the source in the script:
-bash-3.2$ ./native-shebang.rkt hello
(although it's hard to prove)
Raku
(formerly Perl 6)
Raku is not installed by default on most systems and does not have a default install directory, so the path will vary by system.
File: echo.p6
#!/path/to/raku
put @*ARGS;
Usage:
./echo.p6 Hello, world!
- Output:
Hello, world!
REXX
Unix shebang
Using e.g. Regina open source REXX interpreter
#!/usr/local/bin/regina
/* Echo the command line argument */
say arg(1)
ARexx
Under AmigaOS, the obligatory REXX starting comment /* is recognised as a shebang of its own, automatically causing the file to be parsed by ARexx as long as the file's script flag is set.
/* Echo the command line argument */
say arg(1)
Ruby
Ruby does not compile to a binary, thankfully.
Sidef
Sidef is a scripting language and does not compile to a binary.
#!/usr/bin/sidef
say ARGV.join(" ")
- Output:
$ ./echo.sf Hello, World! Hello, World!
Swift
Using Swift REPL:
File: echo.swift
#!/usr/bin/swift
import Foundation
print(Process.arguments[1..<Process.arguments.count].joinWithSeparator(" "))
Usage:
./echo.swift Hello, world!
- Output:
Hello, world!
UNIX Shell
Using sh to script sh
In strictly shell this is natural, native and easy:
File: echo.sh
#!/bin/sh
echo "$@"
Usage:
./echo.sh Hello, world!
- Output:
Hello, world!
Using bash to script C
Note: this Native shebang task does not exactly apply to bash because bash is interpretive, but as a skeleton template the following script is an example of how compiled languages can implement the shebang. Also: this bash code can be used to automatically compile the C code in /usr/local/bin/script_gcc.c above.
File: script_gcc.sh
#!/bin/bash
# Actual shebang when using bash:
#!/usr/local/bin/script_gcc.sh
# Alternative shebang when using bash:
#!/bin/bash /usr/local/bin/script_gcc.sh
# CACHE=No # to turn off caching...
# Note: this shell should be re-written in actual C! :-)
DIALECT=c # or cpp
CC="gcc"
COPTS="-lm -x $DIALECT"
IEXT=.$DIALECT
OEXT=.out
ENOENT=2
srcpath="$1"; shift # => "$@"
#basename="$(basename "$srcpath" ."$DIALECT")"
basename="$(basename "$srcpath")"
# Warning: current dir "." is in path, AND */tmp directories are common/shared
paths="$(dirname "$srcpath")
$HOME/bin
/usr/local/bin
.
$HOME/tmp
$HOME
$HOME/Desktop"
#/tmp
while read dirnamew; do
[ -w "$dirnamew" ] && break
done << end_here_is
$paths
end_here_is
compile(){
sed -n '2,$p' "$srcpath" | "$CC" $COPTS -o "$binpath" -
}
if [ "'$CACHE'" = "'No'" ]; then
binpath="$dirnamew/$basename-v$$$OEXT"
if compile; then
( sleep 0.1; exec rm "$binpath" ) & exec "$binpath" "$@"
fi
else
while read dirnamex; do
binpath="$dirnamex/$basename$OEXT"
if [ -x "$binpath" -a "$binpath" -nt "$srcpath" ];
then exec "$binpath" "$@"; fi
done << end_here_is
$paths
end_here_is
binpath="$dirnamew/$basename$OEXT"
if compile; then exec "$binpath" "$@"; fi
echo "$binpath: executable not available" 1>&2
exit $ENOENT
fi
Test Source File: echo.c
#!/usr/local/bin/script_gcc.sh
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
int main(int argc, char **argv, char **envp){
char ofs = '\0';
for(argv++; *argv; argv++){
if(ofs)putchar(ofs); else ofs=' ';
fwrite(*argv, strlen(*argv), 1, stdout);
}
putchar('\n');
exit(EXIT_SUCCESS);
}
Test Execution:
$ ./echo.c Hello, world!
- Output:
Hello, world!
V (Vlang)
$ cat file.v
#!/usr/local/bin/v run
println('hello')
$ chmod 755 file.v
$ ./file.v
============ running ./file ============
hello
V also knows to compile & run .vsh files immediately, so you do not need a separate step to compile them.
An example deploy.vsh:
#!/usr/bin/env -S v
// Note: The shebang line above, associates the .vsh file to V on Unix-like systems,
// so it can be run just by specifying the path to the .vsh file...
Wren
Normally, Process.arguments[0] would return the (first) command line argument but here we need to use Process.arguments[1] because the first argument passed to Wren's command line interpreter is ./native_shebang.wren.
#!/bin/wren native_shebang.wren
import "os" for Process
System.print(Process.arguments[1])
- Output:
$ chmod +x native_shebang.wren $ ./native_shebang.wren "Hello world!" Hello world!
zkl
This isn't something that is usually done with zkl as the compiler is fast enough (for scripts) to just run the source and let it get compiled and run. But, it can be done. Note: The binary still "links" against zkl (the VM) so the #! is required.
Since the #! parsing is done by a compiler front end and was designed to be used from the command line, we'll do that by forking zkl to compile the source if it is newer than the binary.
#!/home/craigd/Bin/zkl
// This file: nativeShebang.zkl, compiles to nativeShebang.zsc
// zkl --#! . -c nativeShebang -o.
// chmod a+x nativeShebang.z*
// ./nativeShebang.zsc
// If this [source] file is newer than the compiled version (or the
// compiled file doesn't exist), compile up a new version
runningName :=System.argv[1]; // argv==("zkl","nativeShebang.zkl|zsc")
parts,path :=File.splitFileName(runningName),parts[0,2].concat() or ".";
srcName :=parts[0,-1].concat() + ".zkl";
compiledName:=parts[0,-1].concat() + ".zsc";
if(not File.exists(compiledName) or
File.info(srcName)[2] > File.info(compiledName)[2]){ // compare modifed dates
System.cmd("zkl --#! . -c %s -o%s --exit".fmt(srcName,path));
System.cmd("chmod a+x %s".fmt(compiledName));
}
////////////// the script:
println("Hello world!");
- Output:
#run the source in the usual manner to generate a binary #could use ./nativeShebang.zkl if chmod'd it $ zkl nativeShebang.zkl Compiled Class(nativeShebang) (0.0 seconds, ??? lines/sec) Wrote Class(nativeShebang) to ./nativeShebang.zsc Hello world! #eyeball the binary $ zkl hexDump nativeShebang.zsc 0: 23 21 2f 68 6f 6d 65 2f | 63 72 61 69 67 64 2f 42 #!/home/craigd/B 16: 69 6e 2f 7a 6b 6c 0a 7a | 6b 44 00 00 28 31 2e 31 in/zkl.zkD..(1.1 32: 00 5a 4b 4c 20 53 65 72 | 69 61 6c 69 7a 65 64 20 .ZKL Serialized 48: 43 6c 61 73 73 00 6e 61 | 74 69 76 65 53 68 65 62 Class.nativeSheb 64: 61 6e 67 00 00 02 00 00 | 34 2b 61 74 74 72 69 62 ang.....4+attrib 80: 75 74 65 73 3a 73 74 61 | 74 69 63 20 63 72 65 61 utes:static crea 96: 74 65 52 65 74 75 72 6e | 73 53 65 6c 66 00 6e 61 teReturnsSelf.na 112: 74 69 76 65 53 68 65 62 | 61 6e 67 00 00 00 01 00 tiveShebang..... ... #run the binary $ ./nativeShebang.zsc Hello world! #see if update works $ touch ./nativeShebang.zkl $ ./nativeShebang.zsc Compiled Class(nativeShebang) (0.0 seconds, ??? lines/sec) Wrote Class(nativeShebang) to ./nativeShebang.zsc Hello world! #yep, new binary generated