gcc/boehm-gc/include/private/gcconfig.h
2003-04-16 18:28:29 +00:00

1929 lines
59 KiB
C

/*
* Copyright 1988, 1989 Hans-J. Boehm, Alan J. Demers
* Copyright (c) 1991-1994 by Xerox Corporation. All rights reserved.
* Copyright (c) 1996 by Silicon Graphics. All rights reserved.
* Copyright (c) 2000 by Hewlett-Packard Company. All rights reserved.
*
* THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY EXPRESSED
* OR IMPLIED. ANY USE IS AT YOUR OWN RISK.
*
* Permission is hereby granted to use or copy this program
* for any purpose, provided the above notices are retained on all copies.
* Permission to modify the code and to distribute modified code is granted,
* provided the above notices are retained, and a notice that the code was
* modified is included with the above copyright notice.
*/
#ifndef GCCONFIG_H
# define GCCONFIG_H
/* Machine dependent parameters. Some tuning parameters can be found */
/* near the top of gc_private.h. */
/* Machine specific parts contributed by various people. See README file. */
/* First a unified test for Linux: */
# if defined(linux) || defined(__linux__)
# define LINUX
# endif
/* And one for NetBSD: */
# if defined(__NetBSD__)
# define NETBSD
# endif
/* And one for OpenBSD: */
# if defined(__OpenBSD__)
# define OPENBSD
# endif
/* And one for FreeBSD: */
# if defined(__FreeBSD__)
# define FREEBSD
# endif
/* Determine the machine type: */
# if defined(__arm__) || defined(__thumb__)
# define ARM32
# if !defined(LINUX) && !defined(NETBSD)
# define NOSYS
# define mach_type_known
# endif
# endif
# if defined(sun) && defined(mc68000)
# define M68K
# define SUNOS4
# define mach_type_known
# endif
# if defined(hp9000s300)
# define M68K
# define HP
# define mach_type_known
# endif
# if defined(OPENBSD) && defined(m68k)
# define M68K
# define mach_type_known
# endif
# if defined(OPENBSD) && defined(__sparc__)
# define SPARC
# define mach_type_known
# endif
# if defined(NETBSD) && defined(m68k)
# define M68K
# define mach_type_known
# endif
# if defined(NETBSD) && defined(__powerpc__)
# define POWERPC
# define mach_type_known
# endif
# if defined(NETBSD) && defined(__arm__)
# define ARM32
# define mach_type_known
# endif
# if defined(vax)
# define VAX
# ifdef ultrix
# define ULTRIX
# else
# define BSD
# endif
# define mach_type_known
# endif
# if defined(mips) || defined(__mips) || defined(_mips)
# define MIPS
# if defined(nec_ews) || defined(_nec_ews)
# define EWS4800
# endif
# if !defined(LINUX) && !defined(EWS4800) && !defined(NETBSD)
# if defined(ultrix) || defined(__ultrix)
# define ULTRIX
# else
# if defined(_SYSTYPE_SVR4) || defined(SYSTYPE_SVR4) \
|| defined(__SYSTYPE_SVR4__)
# define IRIX5 /* or IRIX 6.X */
# else
# define RISCOS /* or IRIX 4.X */
# endif
# endif
# endif /* !LINUX */
# define mach_type_known
# endif
# if defined(sequent) && (defined(i386) || defined(__i386__))
# define I386
# define SEQUENT
# define mach_type_known
# endif
# if defined(sun) && (defined(i386) || defined(__i386__))
# define I386
# define SUNOS5
# define mach_type_known
# endif
# if (defined(__OS2__) || defined(__EMX__)) && defined(__32BIT__)
# define I386
# define OS2
# define mach_type_known
# endif
# if defined(ibm032)
# define RT
# define mach_type_known
# endif
# if defined(sun) && (defined(sparc) || defined(__sparc))
# define SPARC
/* Test for SunOS 5.x */
# include <errno.h>
# ifdef ECHRNG
# define SUNOS5
# else
# define SUNOS4
# endif
# define mach_type_known
# endif
# if defined(sparc) && defined(unix) && !defined(sun) && !defined(linux) \
&& !defined(__OpenBSD__) && !(__NetBSD__)
# define SPARC
# define DRSNX
# define mach_type_known
# endif
# if defined(_IBMR2)
# define RS6000
# define mach_type_known
# endif
# if defined(__NetBSD__) && defined(__sparc__)
# define SPARC
# define mach_type_known
# endif
# if defined(_M_XENIX) && defined(_M_SYSV) && defined(_M_I386)
/* The above test may need refinement */
# define I386
# if defined(_SCO_ELF)
# define SCO_ELF
# else
# define SCO
# endif
# define mach_type_known
# endif
# if defined(_AUX_SOURCE)
# define M68K
# define SYSV
# define mach_type_known
# endif
# if defined(_PA_RISC1_0) || defined(_PA_RISC1_1) || defined(_PA_RISC2_0) \
|| defined(hppa) || defined(__hppa__)
# define HP_PA
# ifndef LINUX
# define HPUX
# endif
# define mach_type_known
# endif
# if defined(__ia64) && defined(_HPUX_SOURCE)
# define IA64
# define HPUX
# define mach_type_known
# endif
# if defined(__BEOS__) && defined(_X86_)
# define I386
# define BEOS
# define mach_type_known
# endif
# if defined(LINUX) && (defined(i386) || defined(__i386__))
# define I386
# define mach_type_known
# endif
# if defined(LINUX) && defined(__x86_64__)
# define X86_64
# define mach_type_known
# endif
# if defined(LINUX) && (defined(__ia64__) || defined(__ia64))
# define IA64
# define mach_type_known
# endif
# if defined(LINUX) && (defined(powerpc) || defined(__powerpc__))
# define POWERPC
# define mach_type_known
# endif
# if defined(LINUX) && defined(__mc68000__)
# define M68K
# define mach_type_known
# endif
# if defined(LINUX) && (defined(sparc) || defined(__sparc__))
# define SPARC
# define mach_type_known
# endif
# if defined(LINUX) && defined(__arm__)
# define ARM32
# define mach_type_known
# endif
# if defined(LINUX) && defined(__sh__)
# define SH
# define mach_type_known
# endif
# if defined(__alpha) || defined(__alpha__)
# define ALPHA
# if !defined(LINUX) && !defined(NETBSD) && !defined(OPENBSD) && !defined(FREEBSD)
# define OSF1 /* a.k.a Digital Unix */
# endif
# define mach_type_known
# endif
# if defined(_AMIGA) && !defined(AMIGA)
# define AMIGA
# endif
# ifdef AMIGA
# define M68K
# define mach_type_known
# endif
# if defined(THINK_C) || defined(__MWERKS__) && !defined(__powerc)
# define M68K
# define MACOS
# define mach_type_known
# endif
# if defined(__MWERKS__) && defined(__powerc)
# define POWERPC
# define MACOS
# define mach_type_known
# endif
# if defined(macosx) || \
defined(__APPLE__) && defined(__MACH__) && defined(__ppc__)
# define MACOSX
# define POWERPC
# define mach_type_known
# endif
# if defined(__APPLE__) && defined(__MACH__) && defined(__i386__)
# define MACOSX
# define I386
--> Not really supported, but at least we recognize it.
# endif
# if defined(NeXT) && defined(mc68000)
# define M68K
# define NEXT
# define mach_type_known
# endif
# if defined(NeXT) && (defined(i386) || defined(__i386__))
# define I386
# define NEXT
# define mach_type_known
# endif
# if defined(__OpenBSD__) && (defined(i386) || defined(__i386__))
# define I386
# define OPENBSD
# define mach_type_known
# endif
# if defined(FREEBSD) && (defined(i386) || defined(__i386__))
# define I386
# define mach_type_known
# endif
# if defined(__NetBSD__) && (defined(i386) || defined(__i386__))
# define I386
# define mach_type_known
# endif
# if defined(bsdi) && (defined(i386) || defined(__i386__))
# define I386
# define BSDI
# define mach_type_known
# endif
# if !defined(mach_type_known) && defined(__386BSD__)
# define I386
# define THREE86BSD
# define mach_type_known
# endif
# if defined(_CX_UX) && defined(_M88K)
# define M88K
# define CX_UX
# define mach_type_known
# endif
# if defined(DGUX)
# define M88K
/* DGUX defined */
# define mach_type_known
# endif
# if defined(_WIN32_WCE)
/* SH3, SH4, MIPS already defined for corresponding architectures */
# if defined(SH3) || defined(SH4)
# define SH
# endif
# if defined(x86)
# define I386
# endif
# if defined(ARM)
# define ARM32
# endif
# define MSWINCE
# define mach_type_known
# else
# if (defined(_MSDOS) || defined(_MSC_VER)) && (_M_IX86 >= 300) \
|| defined(_WIN32) && !defined(__CYGWIN32__) && !defined(__CYGWIN__)
# define I386
# define MSWIN32 /* or Win32s */
# define mach_type_known
# endif
# endif
# if defined(__DJGPP__)
# define I386
# ifndef DJGPP
# define DJGPP /* MSDOS running the DJGPP port of GCC */
# endif
# define mach_type_known
# endif
# if defined(__CYGWIN32__) || defined(__CYGWIN__)
# define I386
# define CYGWIN32
# define mach_type_known
# endif
# if defined(__MINGW32__)
# define I386
# define MSWIN32
# define mach_type_known
# endif
# if defined(__BORLANDC__)
# define I386
# define MSWIN32
# define mach_type_known
# endif
# if defined(_UTS) && !defined(mach_type_known)
# define S370
# define UTS4
# define mach_type_known
# endif
# if defined(__pj__)
# define PJ
# define mach_type_known
# endif
# if defined(__embedded__) && defined(PPC)
# define POWERPC
# define NOSYS
# define mach_type_known
# endif
/* Ivan Demakov */
# if defined(__WATCOMC__) && defined(__386__)
# define I386
# if !defined(OS2) && !defined(MSWIN32) && !defined(DOS4GW)
# if defined(__OS2__)
# define OS2
# else
# if defined(__WINDOWS_386__) || defined(__NT__)
# define MSWIN32
# else
# define DOS4GW
# endif
# endif
# endif
# define mach_type_known
# endif
# if defined(__s390__) && defined(LINUX)
# define S390
# define mach_type_known
# endif
# if defined(__GNU__)
# if defined(__i386__)
/* The Debian Hurd running on generic PC */
# define HURD
# define I386
# define mach_type_known
# endif
# endif
/* Feel free to add more clauses here */
/* Or manually define the machine type here. A machine type is */
/* characterized by the architecture. Some */
/* machine types are further subdivided by OS. */
/* the macros ULTRIX, RISCOS, and BSD to distinguish. */
/* Note that SGI IRIX is treated identically to RISCOS. */
/* SYSV on an M68K actually means A/UX. */
/* The distinction in these cases is usually the stack starting address */
# ifndef mach_type_known
--> unknown machine type
# endif
/* Mapping is: M68K ==> Motorola 680X0 */
/* (SUNOS4,HP,NEXT, and SYSV (A/UX), */
/* MACOS and AMIGA variants) */
/* I386 ==> Intel 386 */
/* (SEQUENT, OS2, SCO, LINUX, NETBSD, */
/* FREEBSD, THREE86BSD, MSWIN32, */
/* BSDI,SUNOS5, NEXT, other variants) */
/* NS32K ==> Encore Multimax */
/* MIPS ==> R2000 or R3000 */
/* (RISCOS, ULTRIX variants) */
/* VAX ==> DEC VAX */
/* (BSD, ULTRIX variants) */
/* RS6000 ==> IBM RS/6000 AIX3.X */
/* RT ==> IBM PC/RT */
/* HP_PA ==> HP9000/700 & /800 */
/* HP/UX, LINUX */
/* SPARC ==> SPARC v7/v8/v9 */
/* (SUNOS4, SUNOS5, LINUX, */
/* DRSNX variants) */
/* ALPHA ==> DEC Alpha */
/* (OSF1 and LINUX variants) */
/* M88K ==> Motorola 88XX0 */
/* (CX_UX and DGUX) */
/* S370 ==> 370-like machine */
/* running Amdahl UTS4 */
/* S390 ==> 390-like machine */
/* running LINUX */
/* ARM32 ==> Intel StrongARM */
/* IA64 ==> Intel IPF */
/* (e.g. Itanium) */
/* (LINUX and HPUX) */
/* IA64_32 ==> IA64 w/32 bit ABI */
/* (HPUX) */
/* SH ==> Hitachi SuperH */
/* (LINUX & MSWINCE) */
/* X86_64 ==> AMD x86-64 */
/*
* For each architecture and OS, the following need to be defined:
*
* CPP_WORD_SZ is a simple integer constant representing the word size.
* in bits. We assume byte addressibility, where a byte has 8 bits.
* We also assume CPP_WORD_SZ is either 32 or 64.
* (We care about the length of pointers, not hardware
* bus widths. Thus a 64 bit processor with a C compiler that uses
* 32 bit pointers should use CPP_WORD_SZ of 32, not 64. Default is 32.)
*
* MACH_TYPE is a string representation of the machine type.
* OS_TYPE is analogous for the OS.
*
* ALIGNMENT is the largest N, such that
* all pointer are guaranteed to be aligned on N byte boundaries.
* defining it to be 1 will always work, but perform poorly.
*
* DATASTART is the beginning of the data segment.
* On UNIX systems, the collector will scan the area between DATASTART
* and DATAEND for root pointers.
*
* DATAEND, if not `end' where `end' is defined as ``extern int end[];''.
* RTH suggests gaining access to linker script synth'd values with
* this idiom instead of `&end' where `end' is defined as ``extern int end;'' .
* Otherwise, ``GCC will assume these are in .sdata/.sbss'' and it will, e.g.,
* cause failures on alpha*-*-* with ``-msmall-data or -fpic'' or mips-*-*
* without any special options.
*
* ALIGN_DOUBLE of GC_malloc should return blocks aligned to twice
* the pointer size.
*
* STACKBOTTOM is the cool end of the stack, which is usually the
* highest address in the stack.
* Under PCR or OS/2, we have other ways of finding thread stacks.
* For each machine, the following should:
* 1) define STACK_GROWS_UP if the stack grows toward higher addresses, and
* 2) define exactly one of
* STACKBOTTOM (should be defined to be an expression)
* HEURISTIC1
* HEURISTIC2
* If either of the last two macros are defined, then STACKBOTTOM is computed
* during collector startup using one of the following two heuristics:
* HEURISTIC1: Take an address inside GC_init's frame, and round it up to
* the next multiple of STACK_GRAN.
* HEURISTIC2: Take an address inside GC_init's frame, increment it repeatedly
* in small steps (decrement if STACK_GROWS_UP), and read the value
* at each location. Remember the value when the first
* Segmentation violation or Bus error is signalled. Round that
* to the nearest plausible page boundary, and use that instead
* of STACKBOTTOM.
*
* Gustavo Rodriguez-Rivera points out that on most (all?) Unix machines,
* the value of environ is a pointer that can serve as STACKBOTTOM.
* I expect that HEURISTIC2 can be replaced by this approach, which
* interferes far less with debugging. However it has the disadvantage
* that it's confused by a putenv call before the collector is initialized.
* This could be dealt with by intercepting putenv ...
*
* If no expression for STACKBOTTOM can be found, and neither of the above
* heuristics are usable, the collector can still be used with all of the above
* undefined, provided one of the following is done:
* 1) GC_mark_roots can be changed to somehow mark from the correct stack(s)
* without reference to STACKBOTTOM. This is appropriate for use in
* conjunction with thread packages, since there will be multiple stacks.
* (Allocating thread stacks in the heap, and treating them as ordinary
* heap data objects is also possible as a last resort. However, this is
* likely to introduce significant amounts of excess storage retention
* unless the dead parts of the thread stacks are periodically cleared.)
* 2) Client code may set GC_stackbottom before calling any GC_ routines.
* If the author of the client code controls the main program, this is
* easily accomplished by introducing a new main program, setting
* GC_stackbottom to the address of a local variable, and then calling
* the original main program. The new main program would read something
* like:
*
* # include "gc_private.h"
*
* main(argc, argv, envp)
* int argc;
* char **argv, **envp;
* {
* int dummy;
*
* GC_stackbottom = (ptr_t)(&dummy);
* return(real_main(argc, argv, envp));
* }
*
*
* Each architecture may also define the style of virtual dirty bit
* implementation to be used:
* MPROTECT_VDB: Write protect the heap and catch faults.
* PROC_VDB: Use the SVR4 /proc primitives to read dirty bits.
*
* An architecture may define DYNAMIC_LOADING if dynamic_load.c
* defined GC_register_dynamic_libraries() for the architecture.
*
* An architecture may define PREFETCH(x) to preload the cache with *x.
* This defaults to a no-op.
*
* PREFETCH_FOR_WRITE(x) is used if *x is about to be written.
*
* An architecture may also define CLEAR_DOUBLE(x) to be a fast way to
* clear the two words at GC_malloc-aligned address x. By default,
* word stores of 0 are used instead.
*/
/* If we are using a recent version of gcc, we can use __builtin_unwind_init()
* to push the relevant registers onto the stack. This generally makes
* USE_GENERIC_PUSH_REGS the preferred approach for marking from registers.
*/
# if defined(__GNUC__) && ((__GNUC__ >= 3) || \
(__GNUC__ == 2 && __GNUC_MINOR__ >= 8))
# define HAVE_BUILTIN_UNWIND_INIT
# endif
# define STACK_GRAN 0x1000000
# ifdef M68K
# define MACH_TYPE "M68K"
# define ALIGNMENT 2
# ifdef OPENBSD
# define OS_TYPE "OPENBSD"
# define HEURISTIC2
extern char etext[];
# define DATASTART ((ptr_t)(etext))
# endif
# ifdef NETBSD
# define OS_TYPE "NETBSD"
# define HEURISTIC2
extern char etext[];
# define DATASTART ((ptr_t)(etext))
# endif
# ifdef LINUX
# define OS_TYPE "LINUX"
# define STACKBOTTOM ((ptr_t)0xf0000000)
/* # define MPROTECT_VDB - Reported to not work 9/17/01 */
# ifdef __ELF__
# define DYNAMIC_LOADING
# include <features.h>
# if defined(__GLIBC__)&& __GLIBC__>=2
# define LINUX_DATA_START
# else /* !GLIBC2 */
extern char **__environ;
# define DATASTART ((ptr_t)(&__environ))
/* hideous kludge: __environ is the first */
/* word in crt0.o, and delimits the start */
/* of the data segment, no matter which */
/* ld options were passed through. */
/* We could use _etext instead, but that */
/* would include .rodata, which may */
/* contain large read-only data tables */
/* that we'd rather not scan. */
# endif /* !GLIBC2 */
extern int _end[];
# define DATAEND (_end)
# else
extern int etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0xfff) & ~0xfff))
# endif
# endif
# ifdef SUNOS4
# define OS_TYPE "SUNOS4"
extern char etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0x1ffff) & ~0x1ffff))
# define HEURISTIC1 /* differs */
# define DYNAMIC_LOADING
# endif
# ifdef HP
# define OS_TYPE "HP"
extern char etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0xfff) & ~0xfff))
# define STACKBOTTOM ((ptr_t) 0xffeffffc)
/* empirically determined. seems to work. */
# include <unistd.h>
# define GETPAGESIZE() sysconf(_SC_PAGE_SIZE)
# endif
# ifdef SYSV
# define OS_TYPE "SYSV"
extern etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0x3fffff) \
& ~0x3fffff) \
+((word)etext & 0x1fff))
/* This only works for shared-text binaries with magic number 0413.
The other sorts of SysV binaries put the data at the end of the text,
in which case the default of etext would work. Unfortunately,
handling both would require having the magic-number available.
-- Parag
*/
# define STACKBOTTOM ((ptr_t)0xFFFFFFFE)
/* The stack starts at the top of memory, but */
/* 0x0 cannot be used as setjump_test complains */
/* that the stack direction is incorrect. Two */
/* bytes down from 0x0 should be safe enough. */
/* --Parag */
# include <sys/mmu.h>
# define GETPAGESIZE() PAGESIZE /* Is this still right? */
# endif
# ifdef AMIGA
# define OS_TYPE "AMIGA"
/* STACKBOTTOM and DATASTART handled specially */
/* in os_dep.c */
# define DATAEND /* not needed */
# define GETPAGESIZE() 4096
# endif
# ifdef MACOS
# ifndef __LOWMEM__
# include <LowMem.h>
# endif
# define OS_TYPE "MACOS"
/* see os_dep.c for details of global data segments. */
# define STACKBOTTOM ((ptr_t) LMGetCurStackBase())
# define DATAEND /* not needed */
# define GETPAGESIZE() 4096
# endif
# ifdef NEXT
# define OS_TYPE "NEXT"
# define DATASTART ((ptr_t) get_etext())
# define STACKBOTTOM ((ptr_t) 0x4000000)
# define DATAEND /* not needed */
# endif
# endif
# ifdef POWERPC
# define MACH_TYPE "POWERPC"
# ifdef MACOS
# define ALIGNMENT 2 /* Still necessary? Could it be 4? */
# ifndef __LOWMEM__
# include <LowMem.h>
# endif
# define OS_TYPE "MACOS"
/* see os_dep.c for details of global data segments. */
# define STACKBOTTOM ((ptr_t) LMGetCurStackBase())
# define DATAEND /* not needed */
# endif
# ifdef LINUX
# define ALIGNMENT 4 /* Guess. Can someone verify? */
/* This was 2, but that didn't sound right. */
# define OS_TYPE "LINUX"
# define DYNAMIC_LOADING
# define LINUX_STACKBOTTOM
/* Stack usually starts at 0x80000000 */
# define LINUX_DATA_START
extern int _end[];
# define DATAEND (_end)
# endif
# ifdef MACOSX
/* There are reasons to suspect this may not be reliable. */
# define ALIGNMENT 4
# define OS_TYPE "MACOSX"
# define DATASTART ((ptr_t) get_etext())
# define STACKBOTTOM ((ptr_t) 0xc0000000)
# define DATAEND /* not needed */
# undef MPROTECT_VDB
# include <unistd.h>
# define GETPAGESIZE() getpagesize()
# endif
# ifdef NETBSD
# define ALIGNMENT 4
# define OS_TYPE "NETBSD"
# define HEURISTIC2
extern char etext[];
# define DATASTART GC_data_start
# define DYNAMIC_LOADING
# endif
# ifdef NOSYS
# define ALIGNMENT 4
# define OS_TYPE "NOSYS"
extern void __end[], __dso_handle[];
# define DATASTART (__dso_handle) /* OK, that's ugly. */
# define DATAEND (__end)
/* Stack starts at 0xE0000000 for the simulator. */
# undef STACK_GRAN
# define STACK_GRAN 0x10000000
# define HEURISTIC1
# endif
# endif
# ifdef VAX
# define MACH_TYPE "VAX"
# define ALIGNMENT 4 /* Pointers are longword aligned by 4.2 C compiler */
extern char etext[];
# define DATASTART ((ptr_t)(etext))
# ifdef BSD
# define OS_TYPE "BSD"
# define HEURISTIC1
/* HEURISTIC2 may be OK, but it's hard to test. */
# endif
# ifdef ULTRIX
# define OS_TYPE "ULTRIX"
# define STACKBOTTOM ((ptr_t) 0x7fffc800)
# endif
# endif
# ifdef RT
# define MACH_TYPE "RT"
# define ALIGNMENT 4
# define DATASTART ((ptr_t) 0x10000000)
# define STACKBOTTOM ((ptr_t) 0x1fffd800)
# endif
# ifdef SPARC
# define MACH_TYPE "SPARC"
# if defined(__arch64__) || defined(__sparcv9)
# define ALIGNMENT 8
# define CPP_WORDSZ 64
# define ELF_CLASS ELFCLASS64
# else
# define ALIGNMENT 4 /* Required by hardware */
# define CPP_WORDSZ 32
# endif
# define ALIGN_DOUBLE
# ifdef SUNOS5
# define OS_TYPE "SUNOS5"
extern int _etext[];
extern int _end[];
extern char * GC_SysVGetDataStart();
# define DATASTART (ptr_t)GC_SysVGetDataStart(0x10000, _etext)
# define DATAEND (_end)
# if !defined(USE_MMAP) && defined(REDIRECT_MALLOC)
# define USE_MMAP
/* Otherwise we now use calloc. Mmap may result in the */
/* heap interleaved with thread stacks, which can result in */
/* excessive blacklisting. Sbrk is unusable since it */
/* doesn't interact correctly with the system malloc. */
# endif
# ifdef USE_MMAP
# define HEAP_START (ptr_t)0x40000000
# else
# define HEAP_START DATAEND
# endif
# define PROC_VDB
/* HEURISTIC1 reportedly no longer works under 2.7. */
/* HEURISTIC2 probably works, but this appears to be preferable. */
/* Apparently USRSTACK is defined to be USERLIMIT, but in some */
/* installations that's undefined. We work around this with a */
/* gross hack: */
# include <sys/vmparam.h>
# ifdef USERLIMIT
/* This should work everywhere, but doesn't. */
# define STACKBOTTOM USRSTACK
# else
# define HEURISTIC2
# endif
# include <unistd.h>
# define GETPAGESIZE() sysconf(_SC_PAGESIZE)
/* getpagesize() appeared to be missing from at least one */
/* Solaris 5.4 installation. Weird. */
# define DYNAMIC_LOADING
# endif
# ifdef SUNOS4
# define OS_TYPE "SUNOS4"
/* [If you have a weak stomach, don't read this.] */
/* We would like to use: */
/* # define DATASTART ((ptr_t)((((word) (etext)) + 0x1fff) & ~0x1fff)) */
/* This fails occasionally, due to an ancient, but very */
/* persistent ld bug. etext is set 32 bytes too high. */
/* We instead read the text segment size from the a.out */
/* header, which happens to be mapped into our address space */
/* at the start of the text segment. The detective work here */
/* was done by Robert Ehrlich, Manuel Serrano, and Bernard */
/* Serpette of INRIA. */
/* This assumes ZMAGIC, i.e. demand-loadable executables. */
# define TEXTSTART 0x2000
# define DATASTART ((ptr_t)(*(int *)(TEXTSTART+0x4)+TEXTSTART))
# define MPROTECT_VDB
# define HEURISTIC1
# define DYNAMIC_LOADING
# endif
# ifdef DRSNX
# define OS_TYPE "DRSNX"
extern char * GC_SysVGetDataStart();
extern int etext[];
# define DATASTART (ptr_t)GC_SysVGetDataStart(0x10000, etext)
# define MPROTECT_VDB
# define STACKBOTTOM ((ptr_t) 0xdfff0000)
# define DYNAMIC_LOADING
# endif
# ifdef LINUX
# define OS_TYPE "LINUX"
# ifdef __ELF__
# define DYNAMIC_LOADING
# else
Linux Sparc/a.out not supported
# endif
extern int _end[];
extern int _etext[];
# define DATAEND (_end)
# define SVR4
# ifdef __arch64__
/* libc_stack_end is not set reliably for sparc64 */
# define STACKBOTTOM ((ptr_t) 0x80000000000)
# define DATASTART (ptr_t)GC_SysVGetDataStart(0x100000, _etext)
# else
# define LINUX_STACKBOTTOM
# define DATASTART (ptr_t)GC_SysVGetDataStart(0x10000, _etext)
# endif
# endif
# ifdef OPENBSD
# define OS_TYPE "OPENBSD"
# define STACKBOTTOM ((ptr_t) 0xf8000000)
extern int etext[];
# define DATASTART ((ptr_t)(etext))
# endif
# ifdef NETBSD
# define OS_TYPE "NETBSD"
# define HEURISTIC2
# ifdef __ELF__
# define DATASTART GC_data_start
# define DYNAMIC_LOADING
# else
extern char etext[];
# define DATASTART ((ptr_t)(etext))
# endif
# endif
# endif
# ifdef I386
# define MACH_TYPE "I386"
# define ALIGNMENT 4 /* Appears to hold for all "32 bit" compilers */
/* except Borland. The -a4 option fixes */
/* Borland. */
/* Ivan Demakov: For Watcom the option is -zp4. */
# ifndef SMALL_CONFIG
# define ALIGN_DOUBLE /* Not strictly necessary, but may give speed */
/* improvement on Pentiums. */
# endif
# ifdef HAVE_BUILTIN_UNWIND_INIT
# define USE_GENERIC_PUSH_REGS
# endif
# ifdef SEQUENT
# define OS_TYPE "SEQUENT"
extern int etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0xfff) & ~0xfff))
# define STACKBOTTOM ((ptr_t) 0x3ffff000)
# endif
# ifdef BEOS
# define OS_TYPE "BEOS"
# include <OS.h>
# define GETPAGESIZE() B_PAGE_SIZE
extern int etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0xfff) & ~0xfff))
# endif
# ifdef SUNOS5
# define OS_TYPE "SUNOS5"
extern int _etext[], _end[];
extern char * GC_SysVGetDataStart();
# define DATASTART GC_SysVGetDataStart(0x1000, _etext)
# define DATAEND (_end)
/* # define STACKBOTTOM ((ptr_t)(_start)) worked through 2.7, */
/* but reportedly breaks under 2.8. It appears that the stack */
/* base is a property of the executable, so this should not break */
/* old executables. */
/* HEURISTIC2 probably works, but this appears to be preferable. */
# include <sys/vm.h>
# define STACKBOTTOM USRSTACK
/* At least in Solaris 2.5, PROC_VDB gives wrong values for dirty bits. */
/* It appears to be fixed in 2.8 and 2.9. */
# ifdef SOLARIS25_PROC_VDB_BUG_FIXED
# define PROC_VDB
# endif
# define DYNAMIC_LOADING
# if !defined(USE_MMAP) && defined(REDIRECT_MALLOC)
# define USE_MMAP
/* Otherwise we now use calloc. Mmap may result in the */
/* heap interleaved with thread stacks, which can result in */
/* excessive blacklisting. Sbrk is unusable since it */
/* doesn't interact correctly with the system malloc. */
# endif
# ifdef USE_MMAP
# define HEAP_START (ptr_t)0x40000000
# else
# define HEAP_START DATAEND
# endif
# endif
# ifdef SCO
# define OS_TYPE "SCO"
extern int etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0x3fffff) \
& ~0x3fffff) \
+((word)etext & 0xfff))
# define STACKBOTTOM ((ptr_t) 0x7ffffffc)
# endif
# ifdef SCO_ELF
# define OS_TYPE "SCO_ELF"
extern int etext[];
# define DATASTART ((ptr_t)(etext))
# define STACKBOTTOM ((ptr_t) 0x08048000)
# define DYNAMIC_LOADING
# define ELF_CLASS ELFCLASS32
# endif
# ifdef LINUX
# ifndef __GNUC__
/* The Intel compiler doesn't like inline assembly */
# define USE_GENERIC_PUSH_REGS
# endif
# define OS_TYPE "LINUX"
# define LINUX_STACKBOTTOM
# if 0
# define HEURISTIC1
# undef STACK_GRAN
# define STACK_GRAN 0x10000000
/* STACKBOTTOM is usually 0xc0000000, but this changes with */
/* different kernel configurations. In particular, systems */
/* with 2GB physical memory will usually move the user */
/* address space limit, and hence initial SP to 0x80000000. */
# endif
# if !defined(GC_LINUX_THREADS) || !defined(REDIRECT_MALLOC)
# define MPROTECT_VDB
# else
/* We seem to get random errors in incremental mode, */
/* possibly because Linux threads is itself a malloc client */
/* and can't deal with the signals. */
# endif
# ifdef __ELF__
# define DYNAMIC_LOADING
# ifdef UNDEFINED /* includes ro data */
extern int _etext[];
# define DATASTART ((ptr_t)((((word) (_etext)) + 0xfff) & ~0xfff))
# endif
# include <features.h>
# if defined(__GLIBC__) && __GLIBC__ >= 2
# define LINUX_DATA_START
# else
extern char **__environ;
# define DATASTART ((ptr_t)(&__environ))
/* hideous kludge: __environ is the first */
/* word in crt0.o, and delimits the start */
/* of the data segment, no matter which */
/* ld options were passed through. */
/* We could use _etext instead, but that */
/* would include .rodata, which may */
/* contain large read-only data tables */
/* that we'd rather not scan. */
# endif
extern int _end[];
# define DATAEND (_end)
# else
extern int etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0xfff) & ~0xfff))
# endif
# ifdef USE_I686_PREFETCH
# define PREFETCH(x) \
__asm__ __volatile__ (" prefetchnta %0": : "m"(*(char *)(x)))
/* Empirically prefetcht0 is much more effective at reducing */
/* cache miss stalls for the targetted load instructions. But it */
/* seems to interfere enough with other cache traffic that the net */
/* result is worse than prefetchnta. */
# if 0
/* Using prefetches for write seems to have a slight negative */
/* impact on performance, at least for a PIII/500. */
# define PREFETCH_FOR_WRITE(x) \
__asm__ __volatile__ (" prefetcht0 %0": : "m"(*(char *)(x)))
# endif
# endif
# ifdef USE_3DNOW_PREFETCH
# define PREFETCH(x) \
__asm__ __volatile__ (" prefetch %0": : "m"(*(char *)(x)))
# define PREFETCH_FOR_WRITE(x) \
__asm__ __volatile__ (" prefetchw %0": : "m"(*(char *)(x)))
# endif
# endif
# ifdef CYGWIN32
# define OS_TYPE "CYGWIN32"
extern int _data_start__[];
extern int _data_end__[];
extern int _bss_start__[];
extern int _bss_end__[];
/* For binutils 2.9.1, we have */
/* DATASTART = _data_start__ */
/* DATAEND = _bss_end__ */
/* whereas for some earlier versions it was */
/* DATASTART = _bss_start__ */
/* DATAEND = _data_end__ */
/* To get it right for both, we take the */
/* minumum/maximum of the two. */
# define MAX(x,y) ((x) > (y) ? (x) : (y))
# define MIN(x,y) ((x) < (y) ? (x) : (y))
# define DATASTART ((ptr_t) MIN(_data_start__, _bss_start__))
# define DATAEND ((ptr_t) MAX(_data_end__, _bss_end__))
# undef STACK_GRAN
# define STACK_GRAN 0x10000
# define HEURISTIC1
# endif
# ifdef OS2
# define OS_TYPE "OS2"
/* STACKBOTTOM and DATASTART are handled specially in */
/* os_dep.c. OS2 actually has the right */
/* system call! */
# define DATAEND /* not needed */
# define USE_GENERIC_PUSH_REGS
# endif
# ifdef MSWIN32
# define OS_TYPE "MSWIN32"
/* STACKBOTTOM and DATASTART are handled specially in */
/* os_dep.c. */
# ifndef __WATCOMC__
# define MPROTECT_VDB
# endif
# define DATAEND /* not needed */
# endif
# ifdef MSWINCE
# define OS_TYPE "MSWINCE"
# define DATAEND /* not needed */
# endif
# ifdef DJGPP
# define OS_TYPE "DJGPP"
# include "stubinfo.h"
extern int etext[];
extern int _stklen;
extern int __djgpp_stack_limit;
# define DATASTART ((ptr_t)((((word) (etext)) + 0x1ff) & ~0x1ff))
/* # define STACKBOTTOM ((ptr_t)((word) _stubinfo + _stubinfo->size \
+ _stklen)) */
# define STACKBOTTOM ((ptr_t)((word) __djgpp_stack_limit + _stklen))
/* This may not be right. */
# endif
# ifdef OPENBSD
# define OS_TYPE "OPENBSD"
# endif
# ifdef FREEBSD
# define OS_TYPE "FREEBSD"
# ifndef GC_FREEBSD_THREADS
# define MPROTECT_VDB
# endif
# define SIG_SUSPEND SIGUSR1
# define SIG_THR_RESTART SIGUSR2
# define FREEBSD_STACKBOTTOM
# ifdef __ELF__
# define DYNAMIC_LOADING
# endif
/* Handle unmapped hole i386*-*-freebsd[45]* may put between etext and edata. */
extern char etext[];
extern char edata[];
extern char end[];
# define NEED_FIND_LIMIT
# define DATASTART ((ptr_t)(etext))
# define MIN(x,y) ((x) < (y) ? (x) : (y))
# define DATAEND (MIN (GC_find_limit (DATASTART, TRUE), DATASTART2))
# define DATASTART2 ((ptr_t)(edata))
# define DATAEND2 ((ptr_t)(end))
# endif
# ifdef NETBSD
# define OS_TYPE "NETBSD"
# ifdef __ELF__
# define DYNAMIC_LOADING
# endif
# endif
# ifdef THREE86BSD
# define OS_TYPE "THREE86BSD"
# endif
# ifdef BSDI
# define OS_TYPE "BSDI"
# endif
# if defined(OPENBSD) || defined(NETBSD) \
|| defined(THREE86BSD) || defined(BSDI)
# define HEURISTIC2
extern char etext[];
# define DATASTART ((ptr_t)(etext))
# endif
# ifdef NEXT
# define OS_TYPE "NEXT"
# define DATASTART ((ptr_t) get_etext())
# define STACKBOTTOM ((ptr_t)0xc0000000)
# define DATAEND /* not needed */
# endif
# ifdef DOS4GW
# define OS_TYPE "DOS4GW"
extern long __nullarea;
extern char _end;
extern char *_STACKTOP;
/* Depending on calling conventions Watcom C either precedes
or does not precedes with undescore names of C-variables.
Make sure startup code variables always have the same names. */
#pragma aux __nullarea "*";
#pragma aux _end "*";
# define STACKBOTTOM ((ptr_t) _STACKTOP)
/* confused? me too. */
# define DATASTART ((ptr_t) &__nullarea)
# define DATAEND ((ptr_t) &_end)
# endif
# ifdef HURD
# define OS_TYPE "HURD"
# define STACK_GROWS_DOWN
# define HEURISTIC2
extern int __data_start[];
# define DATASTART ( (ptr_t) (__data_start))
extern int _end[];
# define DATAEND ( (ptr_t) (_end))
/* # define MPROTECT_VDB Not quite working yet? */
# define DYNAMIC_LOADING
# endif
# endif
# ifdef NS32K
# define MACH_TYPE "NS32K"
# define ALIGNMENT 4
extern char **environ;
# define DATASTART ((ptr_t)(&environ))
/* hideous kludge: environ is the first */
/* word in crt0.o, and delimits the start */
/* of the data segment, no matter which */
/* ld options were passed through. */
# define STACKBOTTOM ((ptr_t) 0xfffff000) /* for Encore */
# endif
# ifdef MIPS
# define MACH_TYPE "MIPS"
# ifdef LINUX
/* This was developed for a linuxce style platform. Probably */
/* needs to be tweaked for workstation class machines. */
# define OS_TYPE "LINUX"
# define DYNAMIC_LOADING
extern int _end[];
# define DATAEND (_end)
extern int __data_start[];
# define DATASTART ((ptr_t)(__data_start))
# define ALIGNMENT 4
# define USE_GENERIC_PUSH_REGS
# define LINUX_STACKBOTTOM
# endif /* Linux */
# ifdef EWS4800
# define HEURISTIC2
# if defined(_MIPS_SZPTR) && (_MIPS_SZPTR == 64)
extern int _fdata[], _end[];
# define DATASTART ((ptr_t)_fdata)
# define DATAEND ((ptr_t)_end)
# define CPP_WORDSZ _MIPS_SZPTR
# define ALIGNMENT (_MIPS_SZPTR/8)
# else
extern int etext[], edata[], end[];
extern int _DYNAMIC_LINKING[], _gp[];
# define DATASTART ((ptr_t)((((word)etext + 0x3ffff) & ~0x3ffff) \
+ ((word)etext & 0xffff)))
# define DATAEND (edata)
# define DATASTART2 (_DYNAMIC_LINKING \
? (ptr_t)(((word)_gp + 0x8000 + 0x3ffff) & ~0x3ffff) \
: (ptr_t)edata)
# define DATAEND2 (end)
# define ALIGNMENT 4
# endif
# define OS_TYPE "EWS4800"
# define USE_GENERIC_PUSH_REGS 1
# endif
# ifdef ULTRIX
# define HEURISTIC2
# define DATASTART (ptr_t)0x10000000
/* Could probably be slightly higher since */
/* startup code allocates lots of stuff. */
# define OS_TYPE "ULTRIX"
# define ALIGNMENT 4
# endif
# ifdef RISCOS
# define HEURISTIC2
# define DATASTART (ptr_t)0x10000000
# define OS_TYPE "RISCOS"
# define ALIGNMENT 4 /* Required by hardware */
# endif
# ifdef IRIX5
# define HEURISTIC2
extern int _fdata[];
# define DATASTART ((ptr_t)(_fdata))
# ifdef USE_MMAP
# define HEAP_START (ptr_t)0x30000000
# else
# define HEAP_START DATASTART
# endif
/* Lowest plausible heap address. */
/* In the MMAP case, we map there. */
/* In either case it is used to identify */
/* heap sections so they're not */
/* considered as roots. */
# define OS_TYPE "IRIX5"
# define MPROTECT_VDB
# ifdef _MIPS_SZPTR
# define CPP_WORDSZ _MIPS_SZPTR
# define ALIGNMENT (_MIPS_SZPTR/8)
# if CPP_WORDSZ != 64
# define ALIGN_DOUBLE
# endif
# else
# define ALIGNMENT 4
# define ALIGN_DOUBLE
# endif
# define DYNAMIC_LOADING
# endif
# ifdef MSWINCE
# define OS_TYPE "MSWINCE"
# define ALIGNMENT 4
# define DATAEND /* not needed */
# endif
# if defined(NETBSD)
# define OS_TYPE "NETBSD"
# define ALIGNMENT 4
# define HEURISTIC2
# define USE_GENERIC_PUSH_REGS
extern int _fdata[];
# define DATASTART ((ptr_t)(_fdata))
extern int _end[];
# define DATAEND ((ptr_t)(_end))
# define DYNAMIC_LOADING
# endif
# endif
# ifdef RS6000
# define MACH_TYPE "RS6000"
# ifdef __64BIT__
# define ALIGNMENT 8
# define CPP_WORDSZ 64
# else
# define ALIGNMENT 4
# define CPP_WORDSZ 32
# endif
extern int _data[], _end[];
# define DATASTART ((ptr_t)((ulong)_data))
# define DATAEND ((ptr_t)((ulong)_end))
extern int errno;
# define STACKBOTTOM ((ptr_t)((ulong)&errno))
# define USE_GENERIC_PUSH_REGS
# define DYNAMIC_LOADING
/* For really old versions of AIX, this may have to be removed. */
# endif
# ifdef HP_PA
# define MACH_TYPE "HP_PA"
# ifdef __LP64__
# define CPP_WORDSZ 64
# define ALIGNMENT 8
# else
# define CPP_WORDSZ 32
# define ALIGNMENT 4
# define ALIGN_DOUBLE
# endif
# if !defined(GC_HPUX_THREADS) && !defined(GC_LINUX_THREADS)
# ifndef LINUX /* For now. */
# define MPROTECT_VDB
# endif
# else
# define GENERIC_COMPARE_AND_SWAP
/* No compare-and-swap instruction. Use pthread mutexes */
/* when we absolutely have to. */
# ifdef PARALLEL_MARK
# define USE_MARK_BYTES
/* Minimize compare-and-swap usage. */
# endif
# endif
# define STACK_GROWS_UP
# ifdef HPUX
# define OS_TYPE "HPUX"
extern int __data_start[];
# define DATASTART ((ptr_t)(__data_start))
# if 0
/* The following appears to work for 7xx systems running HP/UX */
/* 9.xx Furthermore, it might result in much faster */
/* collections than HEURISTIC2, which may involve scanning */
/* segments that directly precede the stack. It is not the */
/* default, since it may not work on older machine/OS */
/* combinations. (Thanks to Raymond X.T. Nijssen for uncovering */
/* this.) */
# define STACKBOTTOM ((ptr_t) 0x7b033000) /* from /etc/conf/h/param.h */
# else
/* Gustavo Rodriguez-Rivera suggested changing HEURISTIC2 */
/* to this. Note that the GC must be initialized before the */
/* first putenv call. */
extern char ** environ;
# define STACKBOTTOM ((ptr_t)environ)
# endif
# define DYNAMIC_LOADING
# include <unistd.h>
# define GETPAGESIZE() sysconf(_SC_PAGE_SIZE)
# ifndef __GNUC__
# define PREFETCH(x) { \
register long addr = (long)(x); \
(void) _asm ("LDW", 0, 0, addr, 0); \
}
# endif
# endif /* HPUX */
# ifdef LINUX
# define OS_TYPE "LINUX"
# define LINUX_STACKBOTTOM
# define DYNAMIC_LOADING
# define LINUX_DATA_START
extern int _end[];
# define DATAEND (_end)
# endif /* LINUX */
# endif /* HP_PA */
# ifdef ALPHA
# define MACH_TYPE "ALPHA"
# define ALIGNMENT 8
# ifdef NETBSD
# define OS_TYPE "NETBSD"
# define HEURISTIC2
# define DATASTART GC_data_start
# define ELFCLASS32 32
# define ELFCLASS64 64
# define ELF_CLASS ELFCLASS64
# define CPP_WORDSZ 64
# define DYNAMIC_LOADING
# endif
# ifdef OPENBSD
# define OS_TYPE "OPENBSD"
# define HEURISTIC2
# define CPP_WORDSZ 64
# ifdef __ELF__ /* since OpenBSD/Alpha 2.9 */
# define DATASTART GC_data_start
# define ELFCLASS32 32
# define ELFCLASS64 64
# define ELF_CLASS ELFCLASS64
# else /* ECOFF, until OpenBSD/Alpha 2.7 */
# define DATASTART ((ptr_t) 0x140000000)
# endif
# endif
# ifdef FREEBSD
# define OS_TYPE "FREEBSD"
/* MPROTECT_VDB is not yet supported at all on FreeBSD/alpha. */
# define SIG_SUSPEND SIGUSR1
# define SIG_THR_RESTART SIGUSR2
# define FREEBSD_STACKBOTTOM
# ifdef __ELF__
# define DYNAMIC_LOADING
# endif
/* Handle unmapped hole alpha*-*-freebsd[45]* puts between etext and edata. */
extern char etext[];
extern char edata[];
extern char end[];
# define NEED_FIND_LIMIT
# define DATASTART ((ptr_t)(etext))
# define DATAEND (GC_find_limit (DATASTART, TRUE))
# define DATASTART2 ((ptr_t)(edata))
# define DATAEND2 ((ptr_t)(end))
# define CPP_WORDSZ 64
# endif
# ifdef OSF1
# define OS_TYPE "OSF1"
# define DATASTART ((ptr_t) 0x140000000)
extern int _end[];
# define DATAEND ((ptr_t) _end)
extern char ** environ;
/* round up from the value of environ to the nearest page boundary */
/* Probably breaks if putenv is called before collector */
/* initialization. */
# define STACKBOTTOM ((ptr_t)(((word)(environ) | (getpagesize()-1))+1))
/* # define HEURISTIC2 */
/* Normally HEURISTIC2 is too conervative, since */
/* the text segment immediately follows the stack. */
/* Hence we give an upper pound. */
/* This is currently unused, since we disabled HEURISTIC2 */
extern int __start[];
# define HEURISTIC2_LIMIT ((ptr_t)((word)(__start) & ~(getpagesize()-1)))
# define CPP_WORDSZ 64
# define MPROTECT_VDB
# define DYNAMIC_LOADING
# endif
# ifdef LINUX
# define OS_TYPE "LINUX"
# define CPP_WORDSZ 64
# define STACKBOTTOM ((ptr_t) 0x120000000)
# ifdef __ELF__
# define SEARCH_FOR_DATA_START
# define DATASTART GC_data_start
# define DYNAMIC_LOADING
# else
# define DATASTART ((ptr_t) 0x140000000)
# endif
extern int _end[];
# define DATAEND (_end)
# define MPROTECT_VDB
/* Has only been superficially tested. May not */
/* work on all versions. */
# endif
# endif
# ifdef IA64
# define MACH_TYPE "IA64"
# define USE_GENERIC_PUSH_REGS
/* We need to get preserved registers in addition to register */
/* windows. That's easiest to do with setjmp. */
# ifdef PARALLEL_MARK
# define USE_MARK_BYTES
/* Compare-and-exchange is too expensive to use for */
/* setting mark bits. */
# endif
# ifdef HPUX
# ifdef _ILP32
# define CPP_WORDSZ 32
# define ALIGN_DOUBLE
/* Requires 8 byte alignment for malloc */
# define ALIGNMENT 4
# else
# ifndef _LP64
---> unknown ABI
# endif
# define CPP_WORDSZ 64
# define ALIGN_DOUBLE
/* Requires 16 byte alignment for malloc */
# define ALIGNMENT 8
# endif
# define OS_TYPE "HPUX"
extern int __data_start[];
# define DATASTART ((ptr_t)(__data_start))
/* Gustavo Rodriguez-Rivera suggested changing HEURISTIC2 */
/* to this. Note that the GC must be initialized before the */
/* first putenv call. */
extern char ** environ;
# define STACKBOTTOM ((ptr_t)environ)
# define DYNAMIC_LOADING
# include <unistd.h>
# define GETPAGESIZE() sysconf(_SC_PAGE_SIZE)
/* The following was empirically determined, and is probably */
/* not very robust. */
/* Note that the backing store base seems to be at a nice */
/* address minus one page. */
# define BACKING_STORE_DISPLACEMENT 0x1000000
# define BACKING_STORE_ALIGNMENT 0x1000
# define BACKING_STORE_BASE \
(ptr_t)(((word)GC_stackbottom - BACKING_STORE_DISPLACEMENT - 1) \
& ~(BACKING_STORE_ALIGNMENT - 1))
# endif
# ifdef LINUX
# define CPP_WORDSZ 64
# define ALIGN_DOUBLE
/* Requires 16 byte alignment for malloc */
# define ALIGNMENT 8
# define OS_TYPE "LINUX"
/* The following works on NUE and older kernels: */
/* # define STACKBOTTOM ((ptr_t) 0xa000000000000000l) */
/* This does not work on NUE: */
# define LINUX_STACKBOTTOM
/* We also need the base address of the register stack */
/* backing store. This is computed in */
/* GC_linux_register_stack_base based on the following */
/* constants: */
# define BACKING_STORE_ALIGNMENT 0x100000
# define BACKING_STORE_DISPLACEMENT 0x80000000
extern char * GC_register_stackbottom;
# define BACKING_STORE_BASE ((ptr_t)GC_register_stackbottom)
# define SEARCH_FOR_DATA_START
# define DATASTART GC_data_start
# ifdef __GNUC__
# define DYNAMIC_LOADING
# else
/* In the Intel compiler environment, we seem to end up with */
/* statically linked executables and an undefined reference */
/* to _DYNAMIC */
# endif
# define MPROTECT_VDB
/* Requires Linux 2.3.47 or later. */
extern int _end[];
# define DATAEND (_end)
# ifdef __GNUC__
# define PREFETCH(x) \
__asm__ (" lfetch [%0]": : "r"((void *)(x)))
# define PREFETCH_FOR_WRITE(x) \
__asm__ (" lfetch.excl [%0]": : "r"((void *)(x)))
# define CLEAR_DOUBLE(x) \
__asm__ (" stf.spill [%0]=f0": : "r"((void *)(x)))
# endif
# endif
# endif
# ifdef M88K
# define MACH_TYPE "M88K"
# define ALIGNMENT 4
# define ALIGN_DOUBLE
extern int etext[];
# ifdef CX_UX
# define OS_TYPE "CX_UX"
# define DATASTART ((((word)etext + 0x3fffff) & ~0x3fffff) + 0x10000)
# endif
# ifdef DGUX
# define OS_TYPE "DGUX"
extern char * GC_SysVGetDataStart();
# define DATASTART (ptr_t)GC_SysVGetDataStart(0x10000, etext)
# endif
# define STACKBOTTOM ((char*)0xf0000000) /* determined empirically */
# endif
# ifdef S370
# define MACH_TYPE "S370"
# define ALIGNMENT 4 /* Required by hardware */
# define USE_GENERIC_PUSH_REGS
# ifdef UTS4
# define OS_TYPE "UTS4"
extern int etext[];
extern int _etext[];
extern int _end[];
extern char * GC_SysVGetDataStart();
# define DATASTART (ptr_t)GC_SysVGetDataStart(0x10000, _etext)
# define DATAEND (_end)
# define HEURISTIC2
# endif
# endif
# ifdef S390
# define MACH_TYPE "S390"
# define USE_GENERIC_PUSH_REGS
# ifndef __s390x__
# define ALIGNMENT 4
# define CPP_WORDSZ 32
# else
# define ALIGNMENT 8
# define CPP_WORDSZ 64
# define HBLKSIZE 4096
# endif
# ifdef LINUX
# define OS_TYPE "LINUX"
# define LINUX_STACKBOTTOM
# define DYNAMIC_LOADING
extern int __data_start[];
# define DATASTART ((ptr_t)(__data_start))
extern int _end[];
# define DATAEND (_end)
# define CACHE_LINE_SIZE 256
# define GETPAGESIZE() 4096
# endif
# endif
# if defined(PJ)
# define ALIGNMENT 4
extern int _etext[];
# define DATASTART ((ptr_t)(_etext))
# define HEURISTIC1
# endif
# ifdef ARM32
# define CPP_WORDSZ 32
# define MACH_TYPE "ARM32"
# define ALIGNMENT 4
# ifdef NETBSD
# define OS_TYPE "NETBSD"
# define HEURISTIC2
# ifdef __ELF__
# define DATASTART GC_data_start
# define DYNAMIC_LOADING
# else
extern char etext[];
# define DATASTART ((ptr_t)(etext))
# endif
# define USE_GENERIC_PUSH_REGS
# endif
# ifdef LINUX
# define OS_TYPE "LINUX"
# define HEURISTIC1
# undef STACK_GRAN
# define STACK_GRAN 0x10000000
# define USE_GENERIC_PUSH_REGS
# ifdef __ELF__
# define DYNAMIC_LOADING
# include <features.h>
# if defined(__GLIBC__) && __GLIBC__ >= 2
# define LINUX_DATA_START
# else
extern char **__environ;
# define DATASTART ((ptr_t)(&__environ))
/* hideous kludge: __environ is the first */
/* word in crt0.o, and delimits the start */
/* of the data segment, no matter which */
/* ld options were passed through. */
/* We could use _etext instead, but that */
/* would include .rodata, which may */
/* contain large read-only data tables */
/* that we'd rather not scan. */
# endif
extern int _end[];
# define DATAEND (_end)
# else
extern int etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0xfff) & ~0xfff))
# endif
# endif
# ifdef MSWINCE
# define OS_TYPE "MSWINCE"
# define DATAEND /* not needed */
# endif
# ifdef NOSYS
/* __data_start is usually defined in the target linker script. */
extern int __data_start[];
# define DATASTART (ptr_t)(__data_start)
# define USE_GENERIC_PUSH_REGS
/* __stack_base__ is set in newlib/libc/sys/arm/crt0.S */
extern void *__stack_base__;
# define STACKBOTTOM ((ptr_t) (__stack_base__))
# endif
#endif
# ifdef SH
# define MACH_TYPE "SH"
# define ALIGNMENT 4
# ifdef MSWINCE
# define OS_TYPE "MSWINCE"
# define DATAEND /* not needed */
# endif
# ifdef LINUX
# define OS_TYPE "LINUX"
# define STACKBOTTOM ((ptr_t) 0x7c000000)
# define USE_GENERIC_PUSH_REGS
# define DYNAMIC_LOADING
# define LINUX_DATA_START
extern int _end[];
# define DATAEND (_end)
# endif
# endif
# ifdef SH4
# define MACH_TYPE "SH4"
# define OS_TYPE "MSWINCE"
# define ALIGNMENT 4
# define DATAEND /* not needed */
# endif
# ifdef X86_64
# define MACH_TYPE "X86_64"
# define ALIGNMENT 8
# define CPP_WORDSZ 64
# define HBLKSIZE 4096
# define CACHE_LINE_SIZE 64
# define USE_GENERIC_PUSH_REGS
# ifdef LINUX
# define OS_TYPE "LINUX"
# define LINUX_STACKBOTTOM
# if !defined(GC_LINUX_THREADS) || !defined(REDIRECT_MALLOC)
# define MPROTECT_VDB
# else
/* We seem to get random errors in incremental mode, */
/* possibly because Linux threads is itself a malloc client */
/* and can't deal with the signals. */
# endif
# ifdef __ELF__
# define DYNAMIC_LOADING
# ifdef UNDEFINED /* includes ro data */
extern int _etext[];
# define DATASTART ((ptr_t)((((word) (_etext)) + 0xfff) & ~0xfff))
# endif
# include <features.h>
# define LINUX_DATA_START
extern int _end[];
# define DATAEND (_end)
# else
extern int etext[];
# define DATASTART ((ptr_t)((((word) (etext)) + 0xfff) & ~0xfff))
# endif
# define PREFETCH(x) \
__asm__ __volatile__ (" prefetch %0": : "m"(*(char *)(x)))
# define PREFETCH_FOR_WRITE(x) \
__asm__ __volatile__ (" prefetchw %0": : "m"(*(char *)(x)))
# endif
# endif
#ifdef LINUX_DATA_START
/* Some Linux distributions arrange to define __data_start. Some */
/* define data_start as a weak symbol. The latter is technically */
/* broken, since the user program may define data_start, in which */
/* case we lose. Nonetheless, we try both, prefering __data_start. */
/* We assume gcc. */
# pragma weak __data_start
extern int __data_start[];
# pragma weak data_start
extern int data_start[];
# define DATASTART ((ptr_t)(__data_start != 0? __data_start : data_start))
#endif
#if defined(LINUX) && defined(REDIRECT_MALLOC)
/* Rld appears to allocate some memory with its own allocator, and */
/* some through malloc, which might be redirected. To make this */
/* work with collectable memory, we have to scan memory allocated */
/* by rld's internal malloc. */
# define USE_PROC_FOR_LIBRARIES
#endif
# ifndef STACK_GROWS_UP
# define STACK_GROWS_DOWN
# endif
# ifndef CPP_WORDSZ
# define CPP_WORDSZ 32
# endif
# ifndef OS_TYPE
# define OS_TYPE ""
# endif
# ifndef DATAEND
extern int end[];
# define DATAEND (end)
# endif
# if defined(SVR4) && !defined(GETPAGESIZE)
# include <unistd.h>
# define GETPAGESIZE() sysconf(_SC_PAGESIZE)
# endif
# ifndef GETPAGESIZE
# if defined(SUNOS5) || defined(IRIX5)
# include <unistd.h>
# endif
# define GETPAGESIZE() getpagesize()
# endif
# if defined(SUNOS5) || defined(DRSNX) || defined(UTS4)
/* OS has SVR4 generic features. Probably others also qualify. */
# define SVR4
# endif
# if defined(SUNOS5) || defined(DRSNX)
/* OS has SUNOS5 style semi-undocumented interface to dynamic */
/* loader. */
# define SUNOS5DL
/* OS has SUNOS5 style signal handlers. */
# define SUNOS5SIGS
# endif
# if defined(HPUX)
# define SUNOS5SIGS
# endif
# if defined(SVR4) || defined(LINUX) || defined(IRIX) || defined(HPUX) \
|| defined(OPENBSD) || defined(NETBSD) || defined(FREEBSD) \
|| defined(BSD) || defined(_AIX) || defined(MACOSX) || defined(OSF1)
# define UNIX_LIKE /* Basic Unix-like system calls work. */
# endif
# if CPP_WORDSZ != 32 && CPP_WORDSZ != 64
-> bad word size
# endif
# ifdef PCR
# undef DYNAMIC_LOADING
# undef STACKBOTTOM
# undef HEURISTIC1
# undef HEURISTIC2
# undef PROC_VDB
# undef MPROTECT_VDB
# define PCR_VDB
# endif
# ifdef SRC_M3
/* Postponed for now. */
# undef PROC_VDB
# undef MPROTECT_VDB
# endif
# ifdef SMALL_CONFIG
/* Presumably not worth the space it takes. */
# undef PROC_VDB
# undef MPROTECT_VDB
# endif
# ifdef USE_MUNMAP
# undef MPROTECT_VDB /* Can't deal with address space holes. */
# endif
# ifdef PARALLEL_MARK
# undef MPROTECT_VDB /* For now. */
# endif
# if !defined(PCR_VDB) && !defined(PROC_VDB) && !defined(MPROTECT_VDB)
# define DEFAULT_VDB
# endif
# ifndef PREFETCH
# define PREFETCH(x)
# define NO_PREFETCH
# endif
# ifndef PREFETCH_FOR_WRITE
# define PREFETCH_FOR_WRITE(x)
# define NO_PREFETCH_FOR_WRITE
# endif
# ifndef CACHE_LINE_SIZE
# define CACHE_LINE_SIZE 32 /* Wild guess */
# endif
# ifdef LINUX
# define REGISTER_LIBRARIES_EARLY
/* We sometimes use dl_iterate_phdr, which may acquire an internal */
/* lock. This isn't safe after the world has stopped. So we must */
/* call GC_register_dynamic_libraries before stopping the world. */
/* For performance reasons, this may be beneficial on other */
/* platforms as well, though it should be avoided in win32. */
# endif /* LINUX */
# if defined(SEARCH_FOR_DATA_START) && defined(GC_PRIVATE_H)
extern ptr_t GC_data_start;
# endif
# ifndef CLEAR_DOUBLE
# define CLEAR_DOUBLE(x) \
((word*)x)[0] = 0; \
((word*)x)[1] = 0;
# endif /* CLEAR_DOUBLE */
/* Internally we use GC_SOLARIS_THREADS to test for either old or pthreads. */
# if defined(GC_SOLARIS_PTHREADS) && !defined(GC_SOLARIS_THREADS)
# define GC_SOLARIS_THREADS
# endif
# if defined(GC_IRIX_THREADS) && !defined(IRIX5)
--> inconsistent configuration
# endif
# if defined(GC_LINUX_THREADS) && !defined(LINUX)
--> inconsistent configuration
# endif
# if defined(GC_SOLARIS_THREADS) && !defined(SUNOS5)
--> inconsistent configuration
# endif
# if defined(GC_HPUX_THREADS) && !defined(HPUX)
--> inconsistent configuration
# endif
# if defined(GC_WIN32_THREADS) && !defined(MSWIN32)
/* Ideally CYGWIN32 should work, in addition to MSWIN32. I suspect */
/* the necessary code is mostly there, but nobody has actually made */
/* sure the right combination of pieces is compiled in, etc. */
--> inconsistent configuration
# endif
# if defined(PCR) || defined(SRC_M3) || \
defined(GC_SOLARIS_THREADS) || defined(GC_WIN32_THREADS) || \
defined(GC_PTHREADS)
# define THREADS
# endif
# if defined(HP_PA) || defined(M88K) || defined(POWERPC) && !defined(MACOSX) \
|| defined(LINT) || defined(MSWINCE) \
|| (defined(I386) && defined(__LCC__))
/* Use setjmp based hack to mark from callee-save registers. */
/* The define should move to the individual platform */
/* descriptions. */
# define USE_GENERIC_PUSH_REGS
# endif
# if defined(SPARC)
# define ASM_CLEAR_CODE /* Stack clearing is crucial, and we */
/* include assembly code to do it well. */
# endif
/* Can we save call chain in objects for debugging? */
/* SET NFRAMES (# of saved frames) and NARGS (#of args for each frame) */
/* to reasonable values for the platform. */
/* Set SAVE_CALL_CHAIN if we can. SAVE_CALL_COUNT can be specified at */
/* build time, though we feel free to adjust it slightly. */
/* Define NEED_CALLINFO if we either save the call stack or */
/* GC_ADD_CALLER is defined. */
#ifdef LINUX
# include <features.h>
# if __GLIBC__ == 2 && __GLIBC_MINOR__ >= 1 || __GLIBC__ > 2
# define HAVE_BUILTIN_BACKTRACE
# endif
#endif
#if defined(SPARC)
# define CAN_SAVE_CALL_STACKS
# define CAN_SAVE_CALL_ARGS
#endif
#if (defined(I386) || defined(X86_64)) && defined(LINUX)
/* SAVE_CALL_CHAIN is supported if the code is compiled to save */
/* frame pointers by default, i.e. no -fomit-frame-pointer flag. */
# define CAN_SAVE_CALL_STACKS
# define CAN_SAVE_CALL_ARGS
#endif
#if defined(HAVE_BUILTIN_BACKTRACE) && !defined(CAN_SAVE_CALL_STACKS)
# define CAN_SAVE_CALL_STACKS
#endif
# if defined(SAVE_CALL_COUNT) && !defined(GC_ADD_CALLER) \
&& defined(CAN_SAVE_CALL_STACKS)
# define SAVE_CALL_CHAIN
# endif
# ifdef SAVE_CALL_CHAIN
# if defined(SAVE_CALL_NARGS) && defined(CAN_SAVE_CALL_ARGS)
# define NARGS SAVE_CALL_NARGS
# else
# define NARGS 0 /* Number of arguments to save for each call. */
# endif
# endif
# ifdef SAVE_CALL_CHAIN
# ifndef SAVE_CALL_COUNT
# define NFRAMES 6 /* Number of frames to save. Even for */
/* alignment reasons. */
# else
# define NFRAMES ((SAVE_CALL_COUNT + 1) & ~1)
# endif
# define NEED_CALLINFO
# endif /* SAVE_CALL_CHAIN */
# ifdef GC_ADD_CALLER
# define NFRAMES 1
# define NARGS 0
# define NEED_CALLINFO
# endif
# if defined(MAKE_BACK_GRAPH) && !defined(DBG_HDRS_ALL)
# define DBG_HDRS_ALL
# endif
# endif /* GCCONFIG_H */