Kjetil S. Matheussen's notes (28-11-2000) Compiles under SAS/C again. Should also still compile under other Amiga compilers without big changes. I haven't checked if it still works under gcc, because I don't have gcc for Amiga. But I have updated 'Makefile', and hope it compiles fine. WHATS NEW: 1. Made a pretty big effort in preventing GC allocating-functions from returning chip-mem. The lower part of the new file AmigaOS.c does this in various ways, mainly by wrapping GC_malloc, GC_malloc_atomic, GC_malloc_uncollectable, GC_malloc_atomic_uncollectable, GC_malloc_ignore_off_page and GC_malloc_atomic_ignore_off_page. GC_realloc is also wrapped, but doesn't do the same effort in preventing to return chip-mem. Other allocating-functions (e.g., GC_*_typed) can probably be used without any problems, but beware that the warn hook will not be called. In case of problems, don't define GC_AMIGA_FASTALLOC. Programs using more time actually using the memory allocated (instead of just allocate and free rapidly) have the most to earn on this, but even gctest now normally runs twice as fast and uses less memory, on my poor 8 MB machine. The changes have only effect when there is no more fast-mem left. But with the way GC works, it could happen quite often. Beware that an atexit handler had to be added, so using the abort() function will make a big memory-loss. If you absolutely must call abort() instead of exit(), try calling the GC_amiga_free_all_mem function before abort(). New Amiga-specific compilation flags: GC_AMIGA_FASTALLOC - By NOT defining this option, GC will work like before, it will not try to force fast-mem out of the OS, and it will use normal calloc for allocation, and the rest of the following flags will have no effect. GC_AMIGA_ONLYFAST - Makes GC never to return chip-mem. GC_AMIGA_RETRY have no effect if this flag is set. GC_AMIGA_GC - If gc returns NULL, do a GC_gcollect, and try again. This usually is a success with the standard GC configuration. It is also the most important flag to set to prevent GC from returning chip-mem. Beware that it slows down a lot when a program is rapidly allocating/deallocating when there's either very little fast-memory left or very little chip-memory left. It's not a very common situation, but gctest sometimes (very rare) use many minutes because of this. GC_AMIGA_RETRY - If gc succeed allocating memory, but it is chip-mem, try again and see if it is fast-mem. Most of the time, it will actually return fast-mem for the second try. I have set max number of retries to 9 or size/5000. You can change this if you like. (see GC_amiga_rec_alloc()) GC_AMIGA_PRINTSTATS - Gather some statistics during the execution of a program, and prints out the info when the atexit-handler is called. My recommendation is to set all this flags, except GC_AMIGA_PRINTSTATS and GC_AMIGA_ONLYFAST. If your program demands high response-time, you should not define GC_AMIGA_GC, and possible also define GC_AMIGA_ONLYFAST. GC_AMIGA_RETRY does not seem to slow down much. Also, when compiling up programs, and GC_AMIGA_FASTALLOC was not defined when compiling gc, you can define GC_AMIGA_MAKINGLIB to avoid having these allocation- functions wrapped. (see gc.h) Note that GC_realloc must not be called before any of the other above mentioned allocating-functions have been called. (shouldn't be any programs doing so either, I hope). Another note. The allocation-function is wrapped when defining GC_AMIGA_FASTALLOC by letting the function go thru the new GC_amiga_allocwrapper_do function-pointer (see gc.h). Means that sending function-pointers, such as GC_malloc, GC_malloc_atomic, etc., for later to be called, e.g., like this, (*GC_malloc_function_pointer)(size), will not wrap the function. This is normally not a big problem, unless all allocation function is called like this, which will cause the atexit un-allocating function never to be called. Then you either have to manually add the atexit handler, or call the allocation- functions function-pointer functions like this; (*GC_amiga_allocwrapper_do)(size,GC_malloc_function_pointer). There are probably better ways this problem could be handled, unfortunately, I didn't find any without rewriting or replacing a lot of the GC-code, which I really didn't want to. (Making new GC_malloc_* functions, and just defining, e.g., GC_malloc as GC_amiga_malloc should work too). New Amiga-specific function: void GC_amiga_set_toany(void (*func)(void)); 'func' is a function that will be called right before gc has to change allocation-method from MEMF_FAST to MEMF_ANY. I.e., when it is likely it will return chip-mem. 2. A few small compiler-specific additions to make it compile with SAS/C again. 3. Updated and rewritten the SMakefile.amiga, so that it works again and that the "unnecessary" 'SCOPTIONS' files could be removed. Also included the cord-smakefile stuff in the main smakefile, so that the cord smakefile could be removed too. By typing "smake -f SMakefile.amiga", both gc.lib and cord.lib will be made. STILL MISSING: Programs can not be started from workbench, at least not for SAS/C. (Martin Tauchmanns note about that it now works with workbench is definitely wrong when concerning SAS/C). An iconx-script solves this problem. BEWARE! -To run gctest, set the stack to around 200000 bytes first. -SAS/C-specific: cord will crash if you compile gc.lib with either parm=reg or parm=both. (missing legal prototypes for function-pointers someplace is the reason I guess.). tested with software: Radium, http://www.stud.ifi.uio.no/~ksvalast/radium/ tested with hardware: MC68060 Martin Tauchmann's notes (1-Apr-99) Works now, also with the GNU-C compiler V2.7.2.1. Modify the `Makefile` CC=cc $(ABI_FLAG) to CC=gcc $(ABI_FLAG) TECHNICAL NOTES - `GC_get_stack_base()`, `GC_register_data_segments()` works now with every C compiler; also Workbench. - Removed AMIGA_SKIP_SEG, but the Code-Segment must not be scanned by GC. PROBLEMS - When the Linker, does`t merge all Code-Segments to an single one. LD of GCC do it always. - With ixemul.library V47.3, when an GC program launched from another program (example: `Make` or `if_mach M68K AMIGA gctest`), `GC_register_data_segments()` found the Segment-List of the caller program. Can be fixed, if the run-time initialization code (for C programs, usually *crt0*) support `__data` and `__bss`. - PowerPC Amiga currently not supported. - Dynamic libraries (dyn_load.c) not supported. TESTED WITH SOFTWARE `Optimized Oberon 2 C` (oo2c) TESTED WITH HARDWARE MC68030 Michel Schinz's notes WHO DID WHAT The original Amiga port was made by Jesper Peterson. I (Michel Schinz) modified it slightly to reflect the changes made in the new official distributions, and to take advantage of the new SAS/C 6.x features. I also created a makefile to compile the "cord" package (see the cord subdirectory). TECHNICAL NOTES In addition to Jesper's notes, I have the following to say: - gctest checks to see if the code segment is added to the root set or not, and complains if it is. The only problem is that, as far as I know, it is impossible to know which segments are code segments and which are data segments (there are indeed solutions to this problem, like scanning the program on disk or patch the LoadSeg functions, but they are rather complicated). The solution I have chosen (see os_dep.c) is to test whether the program counter is in the segment we are about to add to the root set, and if it is, to skip the segment. The problems are that this solution is rather awkward and that it works only for one code segment. This means that if your program has more than one code segment, all of them but one will be added to the root set. This isn't a big problem in fact, since the collector will continue to work correctly, but it may be slower. Anyway, the code which decides whether to skip a segment or not can be removed simply by not defining AMIGA_SKIP_SEG. But notice that if you do so, gctest will complain (it will say that "GC_is_visible produced wrong failure indication"). However, it may be useful if you happen to have pointers stored in a code segment (you really shouldn't). If anyone has a good solution to the problem of finding, when a program is loaded in memory, whether a segment is a code or a data segment, please let me know. Jesper Peterson's notes ADDITIONAL NOTES FOR AMIGA PORT These notes assume some familiarity with Amiga internals. WHY I PORTED TO THE AMIGA The sole reason why I made this port was as a first step in getting the Sather(*) language on the Amiga. A port of this language will be done as soon as the Sather 1.0 sources are made available to me. Given this motivation, the garbage collection (GC) port is rather minimal. (*) For information on Sather read the comp.lang.sather newsgroup. LIMITATIONS This port assumes that the startup code linked with target programs is that supplied with SAS/C versions 6.0 or later. This allows assumptions to be made about where to find the stack base pointer and data segments when programs are run from WorkBench, as opposed to running from the CLI. The compiler dependent code is all in the GC_get_stack_base() and GC_register_data_segments() functions, but may spread as I add Amiga specific features. Given that SAS/C was assumed, the port is set up to be built with "smake" using the "SMakefile". Compiler options in "SCoptions" can be set with "scopts" program. Both "smake" and "scopts" are part of the SAS/C commercial development system. In keeping with the porting philosophy outlined above, this port will not behave well with Amiga specific code. Especially not inter- process communications via messages, and setting up public structures like Intuition objects or anything else in the system lists. For the time being the use of this library is limited to single threaded ANSI/POSIX compliant or near-compliant code. (i.e., stick to stdio for now). Given this limitation there is currently no mechanism for allocating "CHIP" or "PUBLIC" memory under the garbage collector. I'll add this after giving it considerable thought. The major problem is the entire physical address space may have to me scanned, since there is no telling who we may have passed memory to. If you allocate your own stack in client code, you will have to assign the pointer plus stack size to GC_stackbottom. The initial stack size of the target program can be compiled in by setting the __stack symbol (see SAS documentation). It can be over- ridden from the CLI by running the AmigaDOS "stack" program, or from the WorkBench by setting the stack size in the tool types window. SAS/C COMPILER OPTIONS (SCoptions) You may wish to check the "CPU" code option is appropriate for your intended target system. Under no circumstances set the "StackExtend" code option in either compiling the library or *ANY* client code. All benign compiler warnings have been suppressed. These mainly involve lack of prototypes in the code, and dead assignments detected by the optimizer. THE GOOD NEWS The library as it stands is compatible with the GigaMem commercial virtual memory software, and probably similar PD software. The performance of "gctest" on an Amiga 2630 (68030 @ 25 MHz) compares favorably with an HP9000 with similar architecture (a 325 with a 68030 I think).