Mercurial > sdl-ios-xcode
view src/atomic/qnx/SDL_atomic.c @ 3509:8fde6aeb58df
Changed so that it's obvious that the two code blocks are related.
author | Sam Lantinga <slouken@libsdl.org> |
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date | Wed, 02 Dec 2009 07:25:06 +0000 |
parents | 70bfe3337f8a |
children | f7b03b6838cb |
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/* SDL - Simple DirectMedia Layer Copyright (C) 1997-2009 Sam Lantinga This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA Sam Lantinga slouken@libsdl.org QNX native atomic operations Copyright (C) 2009 Mike Gorchak (mike@malva.ua, lestat@i.com.ua) */ #include "SDL_stdinc.h" #include "SDL_atomic.h" #include "SDL_error.h" #include <atomic.h> /* SMP Exchange for PPC platform */ #ifdef __PPC__ #include <ppc/smpxchg.h> #endif /* __PPC__ */ /* SMP Exchange for ARM platform */ #ifdef __ARM__ #include <arm/smpxchg.h> #endif /* __ARM__ */ /* SMP Exchange for MIPS platform */ #if defined (__MIPSEB__) || defined(__MIPSEL__) #include <mips/smpxchg.h> #endif /* __MIPSEB__ || __MIPSEL__ */ /* SMP Exchange for SH platform */ #ifdef __SH__ #include <sh/smpxchg.h> #endif /* __SH__ */ /* SMP Exchange for x86 platform */ #ifdef __X86__ #include <x86/smpxchg.h> #endif /* __X86__ */ /* This file provides 32, and 64 bit atomic operations. If the operations are provided by the native hardware and operating system they are used. If they are not then the operations are emulated using the SDL spin lock operations. If spin lock can not be implemented then these functions must fail. */ void SDL_AtomicLock(SDL_SpinLock *lock) { unsigned volatile* l = (unsigned volatile*)lock; Uint32 oldval = 0; Uint32 newval = 1; oldval = _smp_xchg(l, newval); while(1 == oldval) { oldval = _smp_xchg(l, newval); } } void SDL_AtomicUnlock(SDL_SpinLock *lock) { unsigned volatile* l = (unsigned volatile*)lock; Uint32 newval = 0; _smp_xchg(l, newval); } /* QNX 6.4.1 supports only 32 bit atomic access */ #undef nativeTestThenSet32 #define nativeClear32 #define nativeFetchThenIncrement32 #define nativeFetchThenDecrement32 #define nativeFetchThenAdd32 #define nativeFetchThenSubtract32 #define nativeIncrementThenFetch32 #define nativeDecrementThenFetch32 #define nativeAddThenFetch32 #define nativeSubtractThenFetch32 #undef nativeTestThenSet64 #undef nativeClear64 #undef nativeFetchThenIncrement64 #undef nativeFetchThenDecrement64 #undef nativeFetchThenAdd64 #undef nativeFetchThenSubtract64 #undef nativeIncrementThenFetch64 #undef nativeDecrementThenFetch64 #undef nativeAddThenFetch64 #undef nativeSubtractThenFetch64 /* If any of the operations are not provided then we must emulate some of them. That means we need a nice implementation of spin locks that avoids the "one big lock" problem. We use a vector of spin locks and pick which one to use based on the address of the operand of the function. To generate the index of the lock we first shift by 3 bits to get rid on the zero bits that result from 32 and 64 bit allignment of data. We then mask off all but 5 bits and use those 5 bits as an index into the table. Picking the lock this way insures that accesses to the same data at the same time will go to the same lock. OTOH, accesses to different data have only a 1/32 chance of hitting the same lock. That should pretty much eliminate the chances of several atomic operations on different data from waiting on the same "big lock". If it isn't then the table of locks can be expanded to a new size so long as the new size is a power of two. */ static SDL_SpinLock locks[32] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, }; static __inline__ void privateWaitLock(volatile void *ptr) { #if SIZEOF_VOIDP == 4 Uint32 index = ((((Uint32)ptr) >> 3) & 0x1f); #elif SIZEOF_VOIDP == 8 Uint64 index = ((((Uint64)ptr) >> 3) & 0x1f); #endif /* SIZEOF_VOIDP */ SDL_AtomicLock(&locks[index]); } static __inline__ void privateUnlock(volatile void *ptr) { #if SIZEOF_VOIDP == 4 Uint32 index = ((((Uint32)ptr) >> 3) & 0x1f); #elif SIZEOF_VOIDP == 8 Uint64 index = ((((Uint64)ptr) >> 3) & 0x1f); #endif /* SIZEOF_VOIDP */ SDL_AtomicUnlock(&locks[index]); } /* 32 bit atomic operations */ SDL_bool SDL_AtomicTestThenSet32(volatile Uint32 * ptr) { #ifdef nativeTestThenSet32 #else SDL_bool result = SDL_FALSE; privateWaitLock(ptr); result = (*ptr == 0); if (result) { *ptr = 1; } privateUnlock(ptr); return result; #endif /* nativeTestThenSet32 */ } void SDL_AtomicClear32(volatile Uint32 * ptr) { #ifdef nativeClear32 atomic_clr(ptr, 0xFFFFFFFF); #else privateWaitLock(ptr); *ptr = 0; privateUnlock(ptr); return; #endif /* nativeClear32 */ } Uint32 SDL_AtomicFetchThenIncrement32(volatile Uint32 * ptr) { #ifdef nativeFetchThenIncrement32 return atomic_add_value(ptr, 0x00000001); #else Uint32 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr)+= 1; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenIncrement32 */ } Uint32 SDL_AtomicFetchThenDecrement32(volatile Uint32 * ptr) { #ifdef nativeFetchThenDecrement32 return atomic_sub_value(ptr, 0x00000001); #else Uint32 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr) -= 1; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenDecrement32 */ } Uint32 SDL_AtomicFetchThenAdd32(volatile Uint32 * ptr, Uint32 value) { #ifdef nativeFetchThenAdd32 return atomic_add_value(ptr, value); #else Uint32 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr)+= value; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenAdd32 */ } Uint32 SDL_AtomicFetchThenSubtract32(volatile Uint32 * ptr, Uint32 value) { #ifdef nativeFetchThenSubtract32 return atomic_sub_value(ptr, value); #else Uint32 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr)-= value; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenSubtract32 */ } Uint32 SDL_AtomicIncrementThenFetch32(volatile Uint32 * ptr) { #ifdef nativeIncrementThenFetch32 atomic_add(ptr, 0x00000001); return atomic_add_value(ptr, 0x00000000); #else Uint32 tmp = 0; privateWaitLock(ptr); (*ptr)+= 1; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeIncrementThenFetch32 */ } Uint32 SDL_AtomicDecrementThenFetch32(volatile Uint32 * ptr) { #ifdef nativeDecrementThenFetch32 atomic_sub(ptr, 0x00000001); return atomic_sub_value(ptr, 0x00000000); #else Uint32 tmp = 0; privateWaitLock(ptr); (*ptr)-= 1; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeDecrementThenFetch32 */ } Uint32 SDL_AtomicAddThenFetch32(volatile Uint32 * ptr, Uint32 value) { #ifdef nativeAddThenFetch32 atomic_add(ptr, value); return atomic_add_value(ptr, 0x00000000); #else Uint32 tmp = 0; privateWaitLock(ptr); (*ptr)+= value; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeAddThenFetch32 */ } Uint32 SDL_AtomicSubtractThenFetch32(volatile Uint32 * ptr, Uint32 value) { #ifdef nativeSubtractThenFetch32 atomic_sub(ptr, value); return atomic_sub_value(ptr, 0x00000000); #else Uint32 tmp = 0; privateWaitLock(ptr); (*ptr)-= value; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeSubtractThenFetch32 */ } /* 64 bit atomic operations */ #ifdef SDL_HAS_64BIT_TYPE SDL_bool SDL_AtomicTestThenSet64(volatile Uint64 * ptr) { #ifdef nativeTestThenSet64 #else SDL_bool result = SDL_FALSE; privateWaitLock(ptr); result = (*ptr == 0); if (result) { *ptr = 1; } privateUnlock(ptr); return result; #endif /* nativeTestThenSet64 */ } void SDL_AtomicClear64(volatile Uint64 * ptr) { #ifdef nativeClear64 #else privateWaitLock(ptr); *ptr = 0; privateUnlock(ptr); return; #endif /* nativeClear64 */ } Uint64 SDL_AtomicFetchThenIncrement64(volatile Uint64 * ptr) { #ifdef nativeFetchThenIncrement64 #else Uint64 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr)+= 1; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenIncrement64 */ } Uint64 SDL_AtomicFetchThenDecrement64(volatile Uint64 * ptr) { #ifdef nativeFetchThenDecrement64 #else Uint64 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr) -= 1; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenDecrement64 */ } Uint64 SDL_AtomicFetchThenAdd64(volatile Uint64 * ptr, Uint64 value) { #ifdef nativeFetchThenAdd64 #else Uint64 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr)+= value; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenAdd64 */ } Uint64 SDL_AtomicFetchThenSubtract64(volatile Uint64 * ptr, Uint64 value) { #ifdef nativeFetchThenSubtract64 #else Uint64 tmp = 0; privateWaitLock(ptr); tmp = *ptr; (*ptr)-= value; privateUnlock(ptr); return tmp; #endif /* nativeFetchThenSubtract64 */ } Uint64 SDL_AtomicIncrementThenFetch64(volatile Uint64 * ptr) { #ifdef nativeIncrementThenFetch64 #else Uint64 tmp = 0; privateWaitLock(ptr); (*ptr)+= 1; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeIncrementThenFetch64 */ } Uint64 SDL_AtomicDecrementThenFetch64(volatile Uint64 * ptr) { #ifdef nativeDecrementThenFetch64 #else Uint64 tmp = 0; privateWaitLock(ptr); (*ptr)-= 1; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeDecrementThenFetch64 */ } Uint64 SDL_AtomicAddThenFetch64(volatile Uint64 * ptr, Uint64 value) { #ifdef nativeAddThenFetch64 #else Uint64 tmp = 0; privateWaitLock(ptr); (*ptr)+= value; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeAddThenFetch64 */ } Uint64 SDL_AtomicSubtractThenFetch64(volatile Uint64 * ptr, Uint64 value) { #ifdef nativeSubtractThenFetch64 #else Uint64 tmp = 0; privateWaitLock(ptr); (*ptr)-= value; tmp = *ptr; privateUnlock(ptr); return tmp; #endif /* nativeSubtractThenFetch64 */ } #endif /* SDL_HAS_64BIT_TYPE */