// Copyright (c) 2005, Google Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // --- // Author: Sanjay Ghemawat // // A data structure used by the caching malloc. It maps from page# to // a pointer that contains info about that page. We use two // representations: one for 32-bit addresses, and another for 64 bit // addresses. Both representations provide the same interface. The // first representation is implemented as a flat array, the seconds as // a three-level radix tree that strips away approximately 1/3rd of // the bits every time. // // The BITS parameter should be the number of bits required to hold // a page number. E.g., with 32 bit pointers and 4K pages (i.e., // page offset fits in lower 12 bits), BITS == 20. #ifndef TCMALLOC_PAGEMAP_H__ #define TCMALLOC_PAGEMAP_H__ #include "config.h" #if HAVE(STDINT_H) #include #elif HAVE(INTTYPES_H) #include #else #include #endif #include #include "Assertions.h" // Single-level array template class TCMalloc_PageMap1 { private: void** array_; public: typedef uintptr_t Number; void init(void* (*allocator)(size_t)) { array_ = reinterpret_cast((*allocator)(sizeof(void*) << BITS)); memset(array_, 0, sizeof(void*) << BITS); } // Ensure that the map contains initialized entries "x .. x+n-1". // Returns true if successful, false if we could not allocate memory. bool Ensure(Number x, size_t n) { // Nothing to do since flat array was allocate at start return true; } // REQUIRES "k" is in range "[0,2^BITS-1]". // REQUIRES "k" has been ensured before. // // Return the current value for KEY. Returns "Value()" if not // yet set. void* get(Number k) const { return array_[k]; } // REQUIRES "k" is in range "[0,2^BITS-1]". // REQUIRES "k" has been ensured before. // // Sets the value for KEY. void set(Number k, void* v) { array_[k] = v; } }; // Two-level radix tree template class TCMalloc_PageMap2 { private: // Put 32 entries in the root and (2^BITS)/32 entries in each leaf. static const int ROOT_BITS = 5; static const int ROOT_LENGTH = 1 << ROOT_BITS; static const int LEAF_BITS = BITS - ROOT_BITS; static const int LEAF_LENGTH = 1 << LEAF_BITS; // Leaf node struct Leaf { void* values[LEAF_LENGTH]; }; Leaf* root_[ROOT_LENGTH]; // Pointers to 32 child nodes void* (*allocator_)(size_t); // Memory allocator public: typedef uintptr_t Number; void init(void* (*allocator)(size_t)) { allocator_ = allocator; memset(root_, 0, sizeof(root_)); } void* get(Number k) const { ASSERT(k >> BITS == 0); const Number i1 = k >> LEAF_BITS; const Number i2 = k & (LEAF_LENGTH-1); return root_[i1]->values[i2]; } void set(Number k, void* v) { ASSERT(k >> BITS == 0); const Number i1 = k >> LEAF_BITS; const Number i2 = k & (LEAF_LENGTH-1); root_[i1]->values[i2] = v; } bool Ensure(Number start, size_t n) { for (Number key = start; key <= start + n - 1; ) { const Number i1 = key >> LEAF_BITS; // Make 2nd level node if necessary if (root_[i1] == NULL) { Leaf* leaf = reinterpret_cast((*allocator_)(sizeof(Leaf))); if (leaf == NULL) return false; memset(leaf, 0, sizeof(*leaf)); root_[i1] = leaf; } // Advance key past whatever is covered by this leaf node key = ((key >> LEAF_BITS) + 1) << LEAF_BITS; } return true; } #ifdef WTF_CHANGES template void visit(const Visitor& visitor, const MemoryReader& reader) { for (int i = 0; i < ROOT_LENGTH; i++) { if (!root_[i]) continue; Leaf* l = reader(reinterpret_cast(root_[i])); for (int j = 0; j < LEAF_LENGTH; j += visitor.visit(l->values[j])) ; } } #endif }; // Three-level radix tree template class TCMalloc_PageMap3 { private: // How many bits should we consume at each interior level static const int INTERIOR_BITS = (BITS + 2) / 3; // Round-up static const int INTERIOR_LENGTH = 1 << INTERIOR_BITS; // How many bits should we consume at leaf level static const int LEAF_BITS = BITS - 2*INTERIOR_BITS; static const int LEAF_LENGTH = 1 << LEAF_BITS; // Interior node struct Node { Node* ptrs[INTERIOR_LENGTH]; }; // Leaf node struct Leaf { void* values[LEAF_LENGTH]; }; Node* root_; // Root of radix tree void* (*allocator_)(size_t); // Memory allocator Node* NewNode() { Node* result = reinterpret_cast((*allocator_)(sizeof(Node))); if (result != NULL) { memset(result, 0, sizeof(*result)); } return result; } public: typedef uintptr_t Number; void init(void* (*allocator)(size_t)) { allocator_ = allocator; root_ = NewNode(); } void* get(Number k) const { ASSERT(k >> BITS == 0); const Number i1 = k >> (LEAF_BITS + INTERIOR_BITS); const Number i2 = (k >> LEAF_BITS) & (INTERIOR_LENGTH-1); const Number i3 = k & (LEAF_LENGTH-1); return reinterpret_cast(root_->ptrs[i1]->ptrs[i2])->values[i3]; } void set(Number k, void* v) { ASSERT(k >> BITS == 0); const Number i1 = k >> (LEAF_BITS + INTERIOR_BITS); const Number i2 = (k >> LEAF_BITS) & (INTERIOR_LENGTH-1); const Number i3 = k & (LEAF_LENGTH-1); reinterpret_cast(root_->ptrs[i1]->ptrs[i2])->values[i3] = v; } bool Ensure(Number start, size_t n) { for (Number key = start; key <= start + n - 1; ) { const Number i1 = key >> (LEAF_BITS + INTERIOR_BITS); const Number i2 = (key >> LEAF_BITS) & (INTERIOR_LENGTH-1); // Make 2nd level node if necessary if (root_->ptrs[i1] == NULL) { Node* n = NewNode(); if (n == NULL) return false; root_->ptrs[i1] = n; } // Make leaf node if necessary if (root_->ptrs[i1]->ptrs[i2] == NULL) { Leaf* leaf = reinterpret_cast((*allocator_)(sizeof(Leaf))); if (leaf == NULL) return false; memset(leaf, 0, sizeof(*leaf)); root_->ptrs[i1]->ptrs[i2] = reinterpret_cast(leaf); } // Advance key past whatever is covered by this leaf node key = ((key >> LEAF_BITS) + 1) << LEAF_BITS; } return true; } #ifdef WTF_CHANGES template void visit(const Visitor& visitor, const MemoryReader& reader) { Node* root = reader(root_); for (int i = 0; i < INTERIOR_LENGTH; i++) { if (!root->ptrs[i]) continue; Node* n = reader(root->ptrs[i]); for (int j = 0; j < INTERIOR_LENGTH; j++) { if (!n->ptrs[j]) continue; Leaf* l = reader(reinterpret_cast(n->ptrs[j])); for (int k = 0; k < LEAF_LENGTH; k += visitor.visit(l->values[k])) ; } } } #endif }; #endif // TCMALLOC_PAGEMAP_H__