tinycc/README

Tiny C Compiler - C Scripting Everywhere - The Smallest ANSI C compiler
-----------------------------------------------------------------------

Features:
--------

- SMALL! You can compile and execute C code everywhere, for example on
  rescue disks (25KB for x86 executable).

- FAST! tcc generates optimized x86 code. No byte code overhead.

- UNLIMITED! Any C dynamic library can be used directly. TCC is
  heading torward full ANSI C compliance. TCC can of course compile
  itself.

- Compile and execute C source directly. No linking or assembly
  necessary. Full C preprocessor included.

- C script supported : just add '#!/usr/local/bin/tcc' at the first
  line of your C source, and execute it directly from the command
  line.

Documentation:
-------------

1) Installation

***TCC currently only work on Linux x86***.

Type 'make install' to compile and install tcc in /usr/local and
/usr/local/lib/tcc.

2) Introduction

We assume here that you know ANSI C. Look at the example ex1.c to know
what the programs look like.

The main limitation of tcc is that you cannot use floats. 

The include file <tcclib.h> can be used if you want a small basic libc
include support (especially useful for floppy disks). Of course, you
can also use standard headers, although they are slower to compile.

You can begin your C script with '#!/usr/local/bin/tcc' on the first
line and set its execute bits (chmod a+x your_script). Then, you can
launch the C code as a shell or perl script :-) The command line
arguments are put in 'argc' and 'argv' of the main functions, as in
ANSI C.

3) Invokation

'-Idir' : specify an additionnal include path. The
default ones are: /usr/include, /usr/lib/tcc, /usr/local/lib/tcc.

'-Dsym' : define preprocessor symbol 'sym' to 1.

'-lxxx' : dynamically link your program with library
libxxx.so. Standard library paths are checked, including those
specificed with LD_LIBRARY_PATH.

Only one source code can be compiled. If you have multiple source
files, add one which includes all your sources.

4) Examples

ex1.c: simplest example (hello world). Can also be launched directly
as a script: ./ex2.c.

ex2.c: more complicated example: find a number with the four
operations given a list of numbers (benchmark).

ex3.c: compute fibonacci numbers (benchmark).

ex4.c: more complicated: X11 program. Very complicated test in fact
because standard headers are being used ! Currently slow because
parsing does not use hash tables.

ex5.c: 'hello world' with standard glibc headers.

tcc.c: TCC can compile itself. Used to check the code generator.

prog.c: auto test for TCC which tests many subtle possible bugs. Used
when doing 'make test'.

Exact differences with ANSI C:
-----------------------------

1) Preprocessor

 - the preprocessor tokens are the same as C. It means that in some
  rare cases, preprocessed numbers are not handled exactly as in ANSI
  C. This approach has the advantage of being simpler and FAST!

 - __LINE__, __FILE__, __DATE__, __TIME__ are currently not handled.

 - #line not handled

2) C language

- Parsing: variables cannot be initialized ('int a = 1' or 'int tab[2] =
  {1, 2}' not supported).

- Cannot pass struct/union as value. Cannot assign struct/union (use
  memcpy instead).

- Types: floating point numbers are not supported.

- (BUG) 'char' and 'short' casts do not truncate correctly.

- 'sizeof' may not work if too complex expression is given.

Supported C extensions:
----------------------

- 'inline' keyword is ignored.


Technical Description:
---------------------

This is not my first C compiler (see my 'fbcc' compiler) but it
contains the first C preprocessor I wrote. The project started as a
joke to make the smallest C compiler. Then I expanded it torward ANSI
compliance. This C compiler is particular because each feature was
added while trying to be as simple and compact as possible. For
example, no intermediate structure is used to store code or
expressions.

The TCC code generator directly generates linked binary code. It is
rather unusual these days (see gcc for example which generates text
assembly), but it allows to be very fast and surprisingly not so
complicated.

The TCC code generator is register based. It means that it could even
generate good code for RISC processors. On x86, three temporary
registers are used. When more registers are needed, one register is
flushed in a new local variable.

Constant propagation is done for all operations. Multiplications and
divisions are optimized to shifts when appropriate. Logical operators
are optimized by maintaining a special cache for the processor
flags. &&, || and ! are optimized by maintaining a special 'jmp
target' value. No other jmp optimization is currently performed
because it would require to store the code in a more abstract fashion.

The types and values descriptions are stored in a single 'int'
variable (see VT_xxx constants). It was choosen in the first stages of
development when tcc was much simpler. Now, it may not be the best
solution.

License:
-------

TCC is distributed under the GNU Generic Public License (see COPYING
file). 

I accept only patches where you give your copyright explictely to me
to simplify licensing issues.

Fabrice Bellard - Nov 11, 2001.
update 2001-11-11 18:01:29 +00:00			`Tiny C Compiler - C Scripting Everywhere - The Smallest ANSI C compiler`
			`-----------------------------------------------------------------------`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`Features:`
			`--------`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- SMALL! You can compile and execute C code everywhere, for example on`
update 2001-11-11 22:51:50 +00:00			`rescue disks (25KB for x86 executable).`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- FAST! tcc generates optimized x86 code. No byte code overhead.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- UNLIMITED! Any C dynamic library can be used directly. TCC is`
update 2001-11-11 22:51:50 +00:00			`heading torward full ANSI C compliance. TCC can of course compile`
update 2001-11-11 18:01:29 +00:00			`itself.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- Compile and execute C source directly. No linking or assembly`
			`necessary. Full C preprocessor included.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- C script supported : just add '#!/usr/local/bin/tcc' at the first`
update 2001-11-11 22:51:50 +00:00			`line of your C source, and execute it directly from the command`
			`line.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`Documentation:`
			`-------------`

			`1) Installation`

			`*TCC currently only work on Linux x86*.`

			`Type 'make install' to compile and install tcc in /usr/local and`
			`/usr/local/lib/tcc.`

			`2) Introduction`

			`We assume here that you know ANSI C. Look at the example ex1.c to know`
			`what the programs look like.`

update 2001-11-11 22:51:50 +00:00			`The main limitation of tcc is that you cannot use floats.`
update 2001-11-11 18:01:29 +00:00
			`The include file <tcclib.h> can be used if you want a small basic libc`
			`include support (especially useful for floppy disks). Of course, you`
			`can also use standard headers, although they are slower to compile.`

			`You can begin your C script with '#!/usr/local/bin/tcc' on the first`
			`line and set its execute bits (chmod a+x your_script). Then, you can`
			`launch the C code as a shell or perl script :-) The command line`
			`arguments are put in 'argc' and 'argv' of the main functions, as in`
			`ANSI C.`

			`3) Invokation`

			`'-Idir' : specify an additionnal include path. The`
			`default ones are: /usr/include, /usr/lib/tcc, /usr/local/lib/tcc.`

			`'-Dsym' : define preprocessor symbol 'sym' to 1.`

			`'-lxxx' : dynamically link your program with library`
			`libxxx.so. Standard library paths are checked, including those`
			`specificed with LD_LIBRARY_PATH.`

			`Only one source code can be compiled. If you have multiple source`
			`files, add one which includes all your sources.`

			`4) Examples`

			`ex1.c: simplest example (hello world). Can also be launched directly`
			`as a script: ./ex2.c.`

			`ex2.c: more complicated example: find a number with the four`
			`operations given a list of numbers (benchmark).`

			`ex3.c: compute fibonacci numbers (benchmark).`

			`ex4.c: more complicated: X11 program. Very complicated test in fact`
			`because standard headers are being used ! Currently slow because`
			`parsing does not use hash tables.`

			`ex5.c: 'hello world' with standard glibc headers.`

			`tcc.c: TCC can compile itself. Used to check the code generator.`

			`prog.c: auto test for TCC which tests many subtle possible bugs. Used`
			`when doing 'make test'.`

			`Exact differences with ANSI C:`
			`-----------------------------`

			`1) Preprocessor`

			`- the preprocessor tokens are the same as C. It means that in some`
			`rare cases, preprocessed numbers are not handled exactly as in ANSI`
			`C. This approach has the advantage of being simpler and FAST!`

			`- __LINE__, __FILE__, __DATE__, __TIME__ are currently not handled.`

			`- #line not handled`

			`2) C language`

			`- Parsing: variables cannot be initialized ('int a = 1' or 'int tab[2] =`
			`{1, 2}' not supported).`

			`- Cannot pass struct/union as value. Cannot assign struct/union (use`
			`memcpy instead).`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- Types: floating point numbers are not supported.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- (BUG) 'char' and 'short' casts do not truncate correctly.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- 'sizeof' may not work if too complex expression is given.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`Supported C extensions:`
			`----------------------`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`- 'inline' keyword is ignored.`
updated 2001-10-28 15:29:01 +00:00

update 2001-11-11 22:51:50 +00:00			`Technical Description:`
			`---------------------`

			`This is not my first C compiler (see my 'fbcc' compiler) but it`
			`contains the first C preprocessor I wrote. The project started as a`
			`joke to make the smallest C compiler. Then I expanded it torward ANSI`
			`compliance. This C compiler is particular because each feature was`
			`added while trying to be as simple and compact as possible. For`
			`example, no intermediate structure is used to store code or`
			`expressions.`

			`The TCC code generator directly generates linked binary code. It is`
			`rather unusual these days (see gcc for example which generates text`
			`assembly), but it allows to be very fast and surprisingly not so`
			`complicated.`

			`The TCC code generator is register based. It means that it could even`
			`generate good code for RISC processors. On x86, three temporary`
			`registers are used. When more registers are needed, one register is`
			`flushed in a new local variable.`

			`Constant propagation is done for all operations. Multiplications and`
			`divisions are optimized to shifts when appropriate. Logical operators`
			`are optimized by maintaining a special cache for the processor`
			`flags. &&, \|\| and ! are optimized by maintaining a special 'jmp`
			`target' value. No other jmp optimization is currently performed`
			`because it would require to store the code in a more abstract fashion.`

			`The types and values descriptions are stored in a single 'int'`
			`variable (see VT_xxx constants). It was choosen in the first stages of`
			`development when tcc was much simpler. Now, it may not be the best`
			`solution.`

update 2001-11-11 18:01:29 +00:00			`License:`
			`-------`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`TCC is distributed under the GNU Generic Public License (see COPYING`
			`file).`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 18:01:29 +00:00			`I accept only patches where you give your copyright explictely to me`
			`to simplify licensing issues.`
updated 2001-10-28 15:29:01 +00:00
update 2001-11-11 22:51:50 +00:00			`Fabrice Bellard - Nov 11, 2001.`