author | dcubed |
Thu, 18 Jul 2013 12:35:55 -0700 | |
changeset 18945 | 1225c36dacd3 |
parent 7397 | 5b173b4ca846 |
child 22551 | 9bf46d16dcc6 |
permissions | -rw-r--r-- |
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/* |
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* Copyright (c) 2003, 2010, Oracle and/or its affiliates. All rights reserved. |
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. |
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* |
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* This code is free software; you can redistribute it and/or modify it |
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* under the terms of the GNU General Public License version 2 only, as |
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* published by the Free Software Foundation. |
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* |
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* This code is distributed in the hope that it will be useful, but WITHOUT |
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or |
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License |
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* version 2 for more details (a copy is included in the LICENSE file that |
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* accompanied this code). |
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* |
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* You should have received a copy of the GNU General Public License version |
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* 2 along with this work; if not, write to the Free Software Foundation, |
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* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. |
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* |
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* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
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* or visit www.oracle.com if you need additional information or have any |
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* questions. |
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* |
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*/ |
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#ifndef SHARE_VM_RUNTIME_ORDERACCESS_HPP |
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#define SHARE_VM_RUNTIME_ORDERACCESS_HPP |
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#include "memory/allocation.hpp" |
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// Memory Access Ordering Model |
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// |
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// This interface is based on the JSR-133 Cookbook for Compiler Writers |
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// and on the IA64 memory model. It is the dynamic equivalent of the |
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// C/C++ volatile specifier. I.e., volatility restricts compile-time |
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// memory access reordering in a way similar to what we want to occur |
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// at runtime. |
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// |
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// In the following, the terms 'previous', 'subsequent', 'before', |
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// 'after', 'preceding' and 'succeeding' refer to program order. The |
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// terms 'down' and 'below' refer to forward load or store motion |
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// relative to program order, while 'up' and 'above' refer to backward |
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// motion. |
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// |
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// |
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// We define four primitive memory barrier operations. |
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// |
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// LoadLoad: Load1(s); LoadLoad; Load2 |
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// |
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// Ensures that Load1 completes (obtains the value it loads from memory) |
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// before Load2 and any subsequent load operations. Loads before Load1 |
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// may *not* float below Load2 and any subsequent load operations. |
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// |
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// StoreStore: Store1(s); StoreStore; Store2 |
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// |
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// Ensures that Store1 completes (the effect on memory of Store1 is made |
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// visible to other processors) before Store2 and any subsequent store |
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// operations. Stores before Store1 may *not* float below Store2 and any |
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// subsequent store operations. |
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// |
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// LoadStore: Load1(s); LoadStore; Store2 |
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// |
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// Ensures that Load1 completes before Store2 and any subsequent store |
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// operations. Loads before Load1 may *not* float below Store2 and any |
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// subseqeuent store operations. |
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// |
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// StoreLoad: Store1(s); StoreLoad; Load2 |
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// |
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// Ensures that Store1 completes before Load2 and any subsequent load |
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// operations. Stores before Store1 may *not* float below Load2 and any |
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// subseqeuent load operations. |
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// |
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// |
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// We define two further operations, 'release' and 'acquire'. They are |
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// mirror images of each other. |
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// |
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// Execution by a processor of release makes the effect of all memory |
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// accesses issued by it previous to the release visible to all |
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// processors *before* the release completes. The effect of subsequent |
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// memory accesses issued by it *may* be made visible *before* the |
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// release. I.e., subsequent memory accesses may float above the |
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// release, but prior ones may not float below it. |
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// |
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// Execution by a processor of acquire makes the effect of all memory |
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// accesses issued by it subsequent to the acquire visible to all |
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// processors *after* the acquire completes. The effect of prior memory |
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// accesses issued by it *may* be made visible *after* the acquire. |
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// I.e., prior memory accesses may float below the acquire, but |
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// subsequent ones may not float above it. |
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// |
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// Finally, we define a 'fence' operation, which conceptually is a |
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// release combined with an acquire. In the real world these operations |
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// require one or more machine instructions which can float above and |
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// below the release or acquire, so we usually can't just issue the |
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// release-acquire back-to-back. All machines we know of implement some |
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// sort of memory fence instruction. |
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// |
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// |
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// The standalone implementations of release and acquire need an associated |
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// dummy volatile store or load respectively. To avoid redundant operations, |
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// we can define the composite operators: 'release_store', 'store_fence' and |
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// 'load_acquire'. Here's a summary of the machine instructions corresponding |
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// to each operation. |
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// |
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// sparc RMO ia64 x86 |
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// --------------------------------------------------------------------- |
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// fence membar #LoadStore | mf lock addl 0,(sp) |
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// #StoreStore | |
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// #LoadLoad | |
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// #StoreLoad |
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// |
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// release membar #LoadStore | st.rel [sp]=r0 movl $0,<dummy> |
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// #StoreStore |
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// st %g0,[] |
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// |
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// acquire ld [%sp],%g0 ld.acq <r>=[sp] movl (sp),<r> |
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// membar #LoadLoad | |
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// #LoadStore |
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// |
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// release_store membar #LoadStore | st.rel <store> |
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// #StoreStore |
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// st |
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// |
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// store_fence st st lock xchg |
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// fence mf |
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// |
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// load_acquire ld ld.acq <load> |
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// membar #LoadLoad | |
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// #LoadStore |
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// |
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// Using only release_store and load_acquire, we can implement the |
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// following ordered sequences. |
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// |
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// 1. load, load == load_acquire, load |
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// or load_acquire, load_acquire |
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// 2. load, store == load, release_store |
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// or load_acquire, store |
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// or load_acquire, release_store |
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// 3. store, store == store, release_store |
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// or release_store, release_store |
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// |
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// These require no membar instructions for sparc-TSO and no extra |
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// instructions for ia64. |
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// |
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// Ordering a load relative to preceding stores requires a store_fence, |
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// which implies a membar #StoreLoad between the store and load under |
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// sparc-TSO. A fence is required by ia64. On x86, we use locked xchg. |
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// |
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// 4. store, load == store_fence, load |
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// |
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// Use store_fence to make sure all stores done in an 'interesting' |
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// region are made visible prior to both subsequent loads and stores. |
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// |
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// Conventional usage is to issue a load_acquire for ordered loads. Use |
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// release_store for ordered stores when you care only that prior stores |
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// are visible before the release_store, but don't care exactly when the |
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// store associated with the release_store becomes visible. Use |
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// release_store_fence to update values like the thread state, where we |
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// don't want the current thread to continue until all our prior memory |
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// accesses (including the new thread state) are visible to other threads. |
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// |
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// |
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// C++ Volatility |
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// |
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// C++ guarantees ordering at operations termed 'sequence points' (defined |
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// to be volatile accesses and calls to library I/O functions). 'Side |
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// effects' (defined as volatile accesses, calls to library I/O functions |
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// and object modification) previous to a sequence point must be visible |
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// at that sequence point. See the C++ standard, section 1.9, titled |
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// "Program Execution". This means that all barrier implementations, |
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// including standalone loadload, storestore, loadstore, storeload, acquire |
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// and release must include a sequence point, usually via a volatile memory |
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// access. Other ways to guarantee a sequence point are, e.g., use of |
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// indirect calls and linux's __asm__ volatile. |
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// Note: as of 6973570, we have replaced the originally static "dummy" field |
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// (see above) by a volatile store to the stack. All of the versions of the |
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// compilers that we currently use (SunStudio, gcc and VC++) respect the |
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// semantics of volatile here. If you build HotSpot using other |
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// compilers, you may need to verify that no compiler reordering occurs |
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// across the sequence point respresented by the volatile access. |
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// |
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// |
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// os::is_MP Considered Redundant |
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// |
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// Callers of this interface do not need to test os::is_MP() before |
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// issuing an operation. The test is taken care of by the implementation |
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// of the interface (depending on the vm version and platform, the test |
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// may or may not be actually done by the implementation). |
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// |
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// |
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// A Note on Memory Ordering and Cache Coherency |
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// |
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// Cache coherency and memory ordering are orthogonal concepts, though they |
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// interact. E.g., all existing itanium machines are cache-coherent, but |
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// the hardware can freely reorder loads wrt other loads unless it sees a |
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// load-acquire instruction. All existing sparc machines are cache-coherent |
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// and, unlike itanium, TSO guarantees that the hardware orders loads wrt |
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// loads and stores, and stores wrt to each other. |
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// |
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// Consider the implementation of loadload. *If* your platform *isn't* |
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// cache-coherent, then loadload must not only prevent hardware load |
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// instruction reordering, but it must *also* ensure that subsequent |
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// loads from addresses that could be written by other processors (i.e., |
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// that are broadcast by other processors) go all the way to the first |
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// level of memory shared by those processors and the one issuing |
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// the loadload. |
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// |
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// So if we have a MP that has, say, a per-processor D$ that doesn't see |
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// writes by other processors, and has a shared E$ that does, the loadload |
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// barrier would have to make sure that either |
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// |
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// 1. cache lines in the issuing processor's D$ that contained data from |
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// addresses that could be written by other processors are invalidated, so |
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// subsequent loads from those addresses go to the E$, (it could do this |
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// by tagging such cache lines as 'shared', though how to tell the hardware |
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// to do the tagging is an interesting problem), or |
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// |
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// 2. there never are such cache lines in the issuing processor's D$, which |
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// means all references to shared data (however identified: see above) |
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// bypass the D$ (i.e., are satisfied from the E$). |
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// |
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// If your machine doesn't have an E$, substitute 'main memory' for 'E$'. |
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// |
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// Either of these alternatives is a pain, so no current machine we know of |
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// has incoherent caches. |
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// |
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// If loadload didn't have these properties, the store-release sequence for |
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// publishing a shared data structure wouldn't work, because a processor |
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// trying to read data newly published by another processor might go to |
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// its own incoherent caches to satisfy the read instead of to the newly |
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// written shared memory. |
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// |
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// |
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// NOTE WELL!! |
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// |
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// A Note on MutexLocker and Friends |
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// |
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// See mutexLocker.hpp. We assume throughout the VM that MutexLocker's |
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// and friends' constructors do a fence, a lock and an acquire *in that |
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// order*. And that their destructors do a release and unlock, in *that* |
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// order. If their implementations change such that these assumptions |
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// are violated, a whole lot of code will break. |
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class OrderAccess : AllStatic { |
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public: |
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static void loadload(); |
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static void storestore(); |
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static void loadstore(); |
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static void storeload(); |
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static void acquire(); |
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static void release(); |
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static void fence(); |
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static jbyte load_acquire(volatile jbyte* p); |
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static jshort load_acquire(volatile jshort* p); |
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static jint load_acquire(volatile jint* p); |
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static jlong load_acquire(volatile jlong* p); |
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static jubyte load_acquire(volatile jubyte* p); |
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static jushort load_acquire(volatile jushort* p); |
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static juint load_acquire(volatile juint* p); |
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static julong load_acquire(volatile julong* p); |
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static jfloat load_acquire(volatile jfloat* p); |
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static jdouble load_acquire(volatile jdouble* p); |
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static intptr_t load_ptr_acquire(volatile intptr_t* p); |
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static void* load_ptr_acquire(volatile void* p); |
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static void* load_ptr_acquire(const volatile void* p); |
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static void release_store(volatile jbyte* p, jbyte v); |
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static void release_store(volatile jshort* p, jshort v); |
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static void release_store(volatile jint* p, jint v); |
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static void release_store(volatile jlong* p, jlong v); |
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static void release_store(volatile jubyte* p, jubyte v); |
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static void release_store(volatile jushort* p, jushort v); |
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static void release_store(volatile juint* p, juint v); |
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static void release_store(volatile julong* p, julong v); |
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static void release_store(volatile jfloat* p, jfloat v); |
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static void release_store(volatile jdouble* p, jdouble v); |
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static void release_store_ptr(volatile intptr_t* p, intptr_t v); |
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static void release_store_ptr(volatile void* p, void* v); |
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static void store_fence(jbyte* p, jbyte v); |
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static void store_fence(jshort* p, jshort v); |
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static void store_fence(jint* p, jint v); |
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static void store_fence(jlong* p, jlong v); |
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static void store_fence(jubyte* p, jubyte v); |
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static void store_fence(jushort* p, jushort v); |
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static void store_fence(juint* p, juint v); |
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static void store_fence(julong* p, julong v); |
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static void store_fence(jfloat* p, jfloat v); |
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static void store_fence(jdouble* p, jdouble v); |
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static void store_ptr_fence(intptr_t* p, intptr_t v); |
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static void store_ptr_fence(void** p, void* v); |
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static void release_store_fence(volatile jbyte* p, jbyte v); |
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static void release_store_fence(volatile jshort* p, jshort v); |
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static void release_store_fence(volatile jint* p, jint v); |
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static void release_store_fence(volatile jlong* p, jlong v); |
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static void release_store_fence(volatile jubyte* p, jubyte v); |
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static void release_store_fence(volatile jushort* p, jushort v); |
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static void release_store_fence(volatile juint* p, juint v); |
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static void release_store_fence(volatile julong* p, julong v); |
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static void release_store_fence(volatile jfloat* p, jfloat v); |
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static void release_store_fence(volatile jdouble* p, jdouble v); |
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static void release_store_ptr_fence(volatile intptr_t* p, intptr_t v); |
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static void release_store_ptr_fence(volatile void* p, void* v); |
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private: |
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// This is a helper that invokes the StubRoutines::fence_entry() |
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// routine if it exists, It should only be used by platforms that |
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// don't another way to do the inline eassembly. |
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static void StubRoutines_fence(); |
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}; |
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#endif // SHARE_VM_RUNTIME_ORDERACCESS_HPP |