Mercurial > hg > graal-compiler
view src/share/vm/utilities/array.hpp @ 6972:bd7a7ce2e264
6830717: replay of compilations would help with debugging
Summary: When java process crashed in compiler thread, repeat the compilation process will help finding root cause. This is done with using SA dump application class data and replay data from core dump, then use debug version of jvm to recompile the problematic java method.
Reviewed-by: kvn, twisti, sspitsyn
Contributed-by: yumin.qi@oracle.com
author | minqi |
---|---|
date | Mon, 12 Nov 2012 14:03:53 -0800 |
parents | da91efe96a93 |
children | a1ebd310d5c1 |
line wrap: on
line source
/* * Copyright (c) 2000, 2012, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code 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 General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #ifndef SHARE_VM_UTILITIES_ARRAY_HPP #define SHARE_VM_UTILITIES_ARRAY_HPP #include "memory/allocation.hpp" #include "memory/allocation.inline.hpp" #include "memory/metaspace.hpp" // correct linkage required to compile w/o warnings // (must be on file level - cannot be local) extern "C" { typedef int (*ftype)(const void*, const void*); } class ResourceArray: public ResourceObj { protected: int _length; // the number of array elements void* _data; // the array memory #ifdef ASSERT int _nesting; // the resource area nesting level #endif // creation ResourceArray() { _length = 0; _data = NULL; DEBUG_ONLY(init_nesting();) // client may call initialize, at most once } ResourceArray(size_t esize, int length) { DEBUG_ONLY(_data = NULL); initialize(esize, length); } void initialize(size_t esize, int length) { assert(length >= 0, "illegal length"); assert(_data == NULL, "must be new object"); _length = length; _data = resource_allocate_bytes(esize * length); DEBUG_ONLY(init_nesting();) } #ifdef ASSERT void init_nesting(); #endif // helper functions void sort (size_t esize, ftype f); // sort the array void expand (size_t esize, int i, int& size);// expand the array to include slot i void remove_at(size_t esize, int i); // remove the element in slot i public: // standard operations int length() const { return _length; } bool is_empty() const { return length() == 0; } }; template <MEMFLAGS F>class CHeapArray: public CHeapObj<F> { protected: int _length; // the number of array elements void* _data; // the array memory // creation CHeapArray() { _length = 0; _data = NULL; } CHeapArray(size_t esize, int length) { assert(length >= 0, "illegal length"); _length = length; _data = (void*) NEW_C_HEAP_ARRAY(char *, esize * length, F); } void initialize(size_t esize, int length) { // In debug set array to 0? } #ifdef ASSERT void init_nesting(); #endif // helper functions void sort (size_t esize, ftype f); // sort the array void expand (size_t esize, int i, int& size);// expand the array to include slot i void remove_at(size_t esize, int i); // remove the element in slot i public: // standard operations int length() const { return _length; } bool is_empty() const { return length() == 0; } }; #define define_generic_array(array_name,element_type, base_class) \ class array_name: public base_class { \ protected: \ typedef element_type etype; \ enum { esize = sizeof(etype) }; \ \ void base_remove_at(size_t size, int i) { base_class::remove_at(size, i); } \ \ public: \ /* creation */ \ array_name() : base_class() {} \ explicit array_name(const int length) : base_class(esize, length) {} \ array_name(const int length, const etype fx) { initialize(length, fx); } \ void initialize(const int length) { base_class::initialize(esize, length); } \ void initialize(const int length, const etype fx) { \ initialize(length); \ for (int i = 0; i < length; i++) ((etype*)_data)[i] = fx; \ } \ \ /* standard operations */ \ etype& operator [] (const int i) const { \ assert(0 <= i && i < length(), "index out of bounds"); \ return ((etype*)_data)[i]; \ } \ \ int index_of(const etype x) const { \ int i = length(); \ while (i-- > 0 && ((etype*)_data)[i] != x) ; \ /* i < 0 || ((etype*)_data)_data[i] == x */ \ return i; \ } \ \ void sort(int f(etype*, etype*)) { base_class::sort(esize, (ftype)f); } \ bool contains(const etype x) const { return index_of(x) >= 0; } \ \ /* deprecated operations - for compatibility with GrowableArray only */ \ etype at(const int i) const { return (*this)[i]; } \ void at_put(const int i, const etype x) { (*this)[i] = x; } \ etype* adr_at(const int i) { return &(*this)[i]; } \ int find(const etype x) { return index_of(x); } \ }; \ #define define_array(array_name,element_type) \ define_generic_array(array_name, element_type, ResourceArray) #define define_stack(stack_name,array_name) \ class stack_name: public array_name { \ protected: \ int _size; \ \ void grow(const int i, const etype fx) { \ assert(i >= length(), "index too small"); \ if (i >= size()) expand(esize, i, _size); \ for (int j = length(); j <= i; j++) ((etype*)_data)[j] = fx; \ _length = i+1; \ } \ \ public: \ /* creation */ \ stack_name() : array_name() { _size = 0; } \ stack_name(const int size) { initialize(size); } \ stack_name(const int size, const etype fx) { initialize(size, fx); } \ void initialize(const int size, const etype fx) { \ _size = size; \ array_name::initialize(size, fx); \ /* _length == size, allocation and size are the same */ \ } \ void initialize(const int size) { \ _size = size; \ array_name::initialize(size); \ _length = 0; /* reset length to zero; _size records the allocation */ \ } \ \ /* standard operations */ \ int size() const { return _size; } \ \ int push(const etype x) { \ int len = length(); \ if (len >= size()) expand(esize, len, _size); \ ((etype*)_data)[len] = x; \ _length = len+1; \ return len; \ } \ \ etype pop() { \ assert(!is_empty(), "stack is empty"); \ return ((etype*)_data)[--_length]; \ } \ \ etype top() const { \ assert(!is_empty(), "stack is empty"); \ return ((etype*)_data)[length() - 1]; \ } \ \ void push_all(const stack_name* stack) { \ const int l = stack->length(); \ for (int i = 0; i < l; i++) push(((etype*)(stack->_data))[i]); \ } \ \ etype at_grow(const int i, const etype fx) { \ if (i >= length()) grow(i, fx); \ return ((etype*)_data)[i]; \ } \ \ void at_put_grow(const int i, const etype x, const etype fx) { \ if (i >= length()) grow(i, fx); \ ((etype*)_data)[i] = x; \ } \ \ void truncate(const int length) { \ assert(0 <= length && length <= this->length(), "illegal length"); \ _length = length; \ } \ \ void remove_at(int i) { base_remove_at(esize, i); } \ void remove(etype x) { remove_at(index_of(x)); } \ \ /* inserts the given element before the element at index i */ \ void insert_before(const int i, const etype el) { \ int len = length(); \ int new_length = len + 1; \ if (new_length >= size()) expand(esize, new_length, _size); \ for (int j = len - 1; j >= i; j--) { \ ((etype*)_data)[j + 1] = ((etype*)_data)[j]; \ } \ _length = new_length; \ at_put(i, el); \ } \ \ /* inserts contents of the given stack before the element at index i */ \ void insert_before(const int i, const stack_name *st) { \ if (st->length() == 0) return; \ int len = length(); \ int st_len = st->length(); \ int new_length = len + st_len; \ if (new_length >= size()) expand(esize, new_length, _size); \ int j; \ for (j = len - 1; j >= i; j--) { \ ((etype*)_data)[j + st_len] = ((etype*)_data)[j]; \ } \ for (j = 0; j < st_len; j++) { \ ((etype*)_data)[i + j] = ((etype*)st->_data)[j]; \ } \ _length = new_length; \ } \ \ /* deprecated operations - for compatibility with GrowableArray only */ \ int capacity() const { return size(); } \ void clear() { truncate(0); } \ void trunc_to(const int length) { truncate(length); } \ int append(const etype x) { return push(x); } \ void appendAll(const stack_name* stack) { push_all(stack); } \ etype last() const { return top(); } \ }; \ #define define_resource_list(element_type) \ define_generic_array(element_type##Array, element_type, ResourceArray) \ define_stack(element_type##List, element_type##Array) #define define_resource_pointer_list(element_type) \ define_generic_array(element_type##Array, element_type *, ResourceArray) \ define_stack(element_type##List, element_type##Array) #define define_c_heap_list(element_type) \ define_generic_array(element_type##Array, element_type, CHeapArray) \ define_stack(element_type##List, element_type##Array) #define define_c_heap_pointer_list(element_type) \ define_generic_array(element_type##Array, element_type *, CHeapArray) \ define_stack(element_type##List, element_type##Array) // Arrays for basic types define_array(boolArray, bool) define_stack(boolStack, boolArray) define_array(intArray , int ) define_stack(intStack , intArray ) // Array for metadata allocation template <typename T> class Array: public MetaspaceObj { friend class MetadataFactory; friend class VMStructs; friend class MethodHandleCompiler; // special case protected: int _length; // the number of array elements T _data[1]; // the array memory void initialize(int length) { _length = length; } private: // Turn off copy constructor and assignment operator. Array(const Array<T>&); void operator=(const Array<T>&); void* operator new(size_t size, ClassLoaderData* loader_data, int length, bool read_only, TRAPS) { size_t word_size = Array::size(length); return (void*) Metaspace::allocate(loader_data, word_size, read_only, Metaspace::NonClassType, CHECK_NULL); } static size_t byte_sizeof(int length) { return sizeof(Array<T>) + MAX2(length - 1, 0) * sizeof(T); } explicit Array(int length) : _length(length) { assert(length >= 0, "illegal length"); } Array(int length, T init) : _length(length) { assert(length >= 0, "illegal length"); for (int i = 0; i < length; i++) { _data[i] = init; } } public: // standard operations int length() const { return _length; } T* data() { return _data; } bool is_empty() const { return length() == 0; } int index_of(const T& x) const { int i = length(); while (i-- > 0 && _data[i] != x) ; return i; } // sort the array. bool contains(const T& x) const { return index_of(x) >= 0; } T at(int i) const { assert(i >= 0 && i< _length, err_msg_res("oob: 0 <= %d < %d", i, _length)); return _data[i]; } void at_put(const int i, const T& x) { assert(i >= 0 && i< _length, err_msg_res("oob: 0 <= %d < %d", i, _length)); _data[i] = x; } T* adr_at(const int i) { assert(i >= 0 && i< _length, err_msg_res("oob: 0 <= %d < %d", i, _length)); return &_data[i]; } int find(const T& x) { return index_of(x); } T at_acquire(const int which) { return OrderAccess::load_acquire(adr_at(which)); } void release_at_put(int which, T contents) { OrderAccess::release_store(adr_at(which), contents); } static int size(int length) { return align_size_up(byte_sizeof(length), BytesPerWord) / BytesPerWord; } int size() { return size(_length); } static int length_offset_in_bytes() { return (int) (offset_of(Array<T>, _length)); } // Note, this offset don't have to be wordSize aligned. static int base_offset_in_bytes() { return (int) (offset_of(Array<T>, _data)); }; // FIXME: How to handle this? void print_value_on(outputStream* st) const { st->print("Array<T>(" INTPTR_FORMAT ")", this); } #ifndef PRODUCT void print(outputStream* st) { for (int i = 0; i< _length; i++) { st->print_cr("%d: " INTPTR_FORMAT, i, (intptr_t)at(i)); } } void print() { print(tty); } #endif // PRODUCT }; #endif // SHARE_VM_UTILITIES_ARRAY_HPP