/* * %CopyrightBegin% * * Copyright Ericsson AB 2002-2013. All Rights Reserved. * * The contents of this file are subject to the Erlang Public License, * Version 1.1, (the "License"); you may not use this file except in * compliance with the License. You should have received a copy of the * Erlang Public License along with this software. If not, it can be * retrieved online at http://www.erlang.org/. * * Software distributed under the License is distributed on an "AS IS" * basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See * the License for the specific language governing rights and limitations * under the License. * * %CopyrightEnd% */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include "sys.h" #include "erl_process.h" #include "erl_smp.h" #include "atom.h" #include "erl_mmap.h" #include #if defined(DEBUG) || 0 # undef ERTS_MMAP_DEBUG # define ERTS_MMAP_DEBUG #endif /* #define ERTS_MMAP_DEBUG_FILL_AREAS */ #ifdef ERTS_MMAP_DEBUG # define ERTS_MMAP_ASSERT ERTS_ASSERT #else # define ERTS_MMAP_ASSERT(A) ((void) 1) #endif /* * `mmap_state.sa.bot` and `mmap_state.sua.top` are read only after * initialization, but the other pointers are not; i.e., only * ERTS_MMAP_IN_SUPERCARRIER() is allowed without the mutex held. */ #define ERTS_MMAP_IN_SUPERCARRIER(PTR) \ (((UWord) (PTR)) - ((UWord) mmap_state.sa.bot) \ < ((UWord) mmap_state.sua.top) - ((UWord) mmap_state.sa.bot)) #define ERTS_MMAP_IN_SUPERALIGNED_AREA(PTR) \ (ERTS_SMP_LC_ASSERT(erts_lc_mtx_is_locked(&mmap_state.mtx)), \ (((UWord) (PTR)) - ((UWord) mmap_state.sa.bot) \ < ((UWord) mmap_state.sa.top) - ((UWord) mmap_state.sa.bot))) #define ERTS_MMAP_IN_SUPERUNALIGNED_AREA(PTR) \ (ERTS_SMP_LC_ASSERT(erts_lc_mtx_is_locked(&mmap_state.mtx)), \ (((UWord) (PTR)) - ((UWord) mmap_state.sua.bot) \ < ((UWord) mmap_state.sua.top) - ((UWord) mmap_state.sua.bot))) int erts_have_erts_mmap; UWord erts_page_inv_mask; #if defined(DEBUG) || defined(ERTS_MMAP_DEBUG) # undef RBT_DEBUG # define RBT_DEBUG #endif #ifdef RBT_DEBUG # define RBT_ASSERT ERTS_ASSERT # define IF_RBT_DEBUG(C) C #else # define RBT_ASSERT(x) # define IF_RBT_DEBUG(C) #endif typedef struct RBTNode_ RBTNode; struct RBTNode_ { UWord parent_and_color; /* color in bit 0 of parent ptr */ RBTNode *left; RBTNode *right; }; #define RED_FLG (1) #define IS_RED(N) ((N) && ((N)->parent_and_color & RED_FLG)) #define IS_BLACK(N) (!IS_RED(N)) #define SET_RED(N) ((N)->parent_and_color |= RED_FLG) #define SET_BLACK(N) ((N)->parent_and_color &= ~RED_FLG) static ERTS_INLINE RBTNode* parent(RBTNode* node) { return (RBTNode*) (node->parent_and_color & ~RED_FLG); } static ERTS_INLINE void set_parent(RBTNode* node, RBTNode* parent) { RBT_ASSERT(!((UWord)parent & RED_FLG)); node->parent_and_color = ((UWord)parent) | (node->parent_and_color & RED_FLG); } static ERTS_INLINE UWord parent_and_color(RBTNode* parent, int color) { RBT_ASSERT(!((UWord)parent & RED_FLG)); RBT_ASSERT(!(color & ~RED_FLG)); return ((UWord)parent) | color; } enum SortOrder { ADDR_ORDER, /* only address order */ SZ_ADDR_ORDER, /* first size then address order as tiebreaker */ SZ_REVERSE_ADDR_ORDER /* first size then reverse address order */ }; typedef struct { RBTNode* root; enum SortOrder order; }RBTree; #ifdef HARD_DEBUG # define HARD_CHECK_IS_MEMBER(ROOT,NODE) rbt_assert_is_member(ROOT,NODE) # define HARD_CHECK_TREE(TREE,SZ) check_tree(TREE, SZ) static int rbt_assert_is_member(RBTNode* root, RBTNode* node); static RBTNode* check_tree(RBTree* tree, Uint); #else # define HARD_CHECK_IS_MEMBER(ROOT,NODE) # define HARD_CHECK_TREE(TREE,SZ) #endif typedef struct { RBTNode snode; /* node in 'stree' */ RBTNode anode; /* node in 'atree' */ char* start; char* end; }ErtsFreeSegDesc; typedef struct { RBTree stree; /* size ordered tree */ RBTree atree; /* address ordered tree */ Uint nseg; }ErtsFreeSegMap; static struct { int (*reserve_physical)(char *, UWord); void (*unreserve_physical)(char *, UWord); int supercarrier; int no_os_mmap; /* * Super unaligend area is located above super aligned * area. That is, `sa.bot` is beginning of the super * carrier, `sua.top` is the end of the super carrier, * and sa.top and sua.bot moves towards eachother. */ struct { char *top; char *bot; ErtsFreeSegMap map; } sua; struct { char *top; char *bot; ErtsFreeSegMap map; } sa; #if HAVE_MMAP && (!defined(MAP_ANON) && !defined(MAP_ANONYMOUS)) int mmap_fd; #endif erts_smp_mtx_t mtx; char *desc_free_list; struct { struct { UWord total; struct { UWord total; UWord sa; UWord sua; } used; } supercarrier; struct { UWord used; } os; } size; } mmap_state; #define ERTS_MMAP_SIZE_SC_SA_INC(SZ) \ do { \ mmap_state.size.supercarrier.used.total += (SZ); \ mmap_state.size.supercarrier.used.sa += (SZ); \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.total \ <= mmap_state.size.supercarrier.total); \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.sa \ <= mmap_state.size.supercarrier.used.total); \ } while (0) #define ERTS_MMAP_SIZE_SC_SA_DEC(SZ) \ do { \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.total >= (SZ)); \ mmap_state.size.supercarrier.used.total -= (SZ); \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.sa >= (SZ)); \ mmap_state.size.supercarrier.used.sa -= (SZ); \ } while (0) #define ERTS_MMAP_SIZE_SC_SUA_INC(SZ) \ do { \ mmap_state.size.supercarrier.used.total += (SZ); \ mmap_state.size.supercarrier.used.sua += (SZ); \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.total \ <= mmap_state.size.supercarrier.total); \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.sua \ <= mmap_state.size.supercarrier.used.total); \ } while (0) #define ERTS_MMAP_SIZE_SC_SUA_DEC(SZ) \ do { \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.total >= (SZ)); \ mmap_state.size.supercarrier.used.total -= (SZ); \ ERTS_MMAP_ASSERT(mmap_state.size.supercarrier.used.sua >= (SZ)); \ mmap_state.size.supercarrier.used.sua -= (SZ); \ } while (0) #define ERTS_MMAP_SIZE_OS_INC(SZ) \ do { \ ERTS_MMAP_ASSERT(mmap_state.size.os.used + (SZ) >= (SZ)); \ mmap_state.size.os.used += (SZ); \ } while (0) #define ERTS_MMAP_SIZE_OS_DEC(SZ) \ do { \ ERTS_MMAP_ASSERT(mmap_state.size.os.used >= (SZ)); \ mmap_state.size.os.used -= (SZ); \ } while (0) static void add_free_desc_area(char *start, char *end) { if (end > start && sizeof(ErtsFreeSegDesc) <= end - start) { ErtsFreeSegDesc *prev_desc, *desc; char *desc_end; prev_desc = (ErtsFreeSegDesc *) start; prev_desc->start = mmap_state.desc_free_list; desc = (ErtsFreeSegDesc *) (start + sizeof(ErtsFreeSegDesc)); desc_end = start + 2*sizeof(ErtsFreeSegDesc); while (desc_end <= end) { desc->start = (char *) prev_desc; prev_desc = desc; desc = (ErtsFreeSegDesc *) desc_end; desc_end += sizeof(ErtsFreeSegDesc); } mmap_state.desc_free_list = (char *) prev_desc; } } static ERTS_INLINE ErtsFreeSegDesc * alloc_desc(void) { ErtsFreeSegDesc *res; res = (ErtsFreeSegDesc *) mmap_state.desc_free_list; if (res) mmap_state.desc_free_list = res->start; return res; } static ERTS_INLINE void free_desc(ErtsFreeSegDesc *desc) { desc->start = mmap_state.desc_free_list; mmap_state.desc_free_list = (char *) desc; } static ERTS_INLINE ErtsFreeSegDesc* anode_to_desc(RBTNode* anode) { return (ErtsFreeSegDesc*) ((char*)anode - offsetof(ErtsFreeSegDesc, anode)); } static ERTS_INLINE ErtsFreeSegDesc* snode_to_desc(RBTNode* snode) { return (ErtsFreeSegDesc*) ((char*)snode - offsetof(ErtsFreeSegDesc, snode)); } static ERTS_INLINE ErtsFreeSegDesc* node_to_desc(enum SortOrder order, RBTNode* node) { return order==ADDR_ORDER ? anode_to_desc(node) : snode_to_desc(node); } #ifdef HARD_DEBUG static ERTS_INLINE SWord cmp_nodes(enum SortOrder order, RBTNode* lhs, RBTNode* rhs) { ErtsFreeSegDesc* ldesc = node_to_desc(order, lhs); ErtsFreeSegDesc* rdesc = node_to_desc(order, rhs); RBT_ASSERT(lhs != rhs); if (order != ADDR_ORDER) { SWord lsz = ldesc->end - ldesc->start; SWord rsz = rdesc->end - rdesc->start; SWord diff = lsz - rsz; if (diff) return diff; } if (order != SZ_REVERSE_ADDR_ORDER) { return (char*)ldesc->start - (char*)rdesc->start; } else { return (char*)rdesc->start - (char*)ldesc->start; } } #endif /* HARD_DEBUG */ static ERTS_INLINE SWord cmp_with_node(enum SortOrder order, SWord sz, char* addr, RBTNode* rhs) { ErtsFreeSegDesc* rdesc; if (order != ADDR_ORDER) { rdesc = snode_to_desc(rhs); { SWord rhs_sz = rdesc->end - rdesc->start; SWord diff = sz - rhs_sz; if (diff) return diff; } } else rdesc = anode_to_desc(rhs); if (order != SZ_REVERSE_ADDR_ORDER) return addr - (char*)rdesc->start; else return (char*)rdesc->start - addr; } static ERTS_INLINE void left_rotate(RBTNode **root, RBTNode *x) { RBTNode *y = x->right; x->right = y->left; if (y->left) set_parent(y->left, x); set_parent(y, parent(x)); if (!parent(y)) { RBT_ASSERT(*root == x); *root = y; } else if (x == parent(x)->left) parent(x)->left = y; else { RBT_ASSERT(x == parent(x)->right); parent(x)->right = y; } y->left = x; set_parent(x, y); } static ERTS_INLINE void right_rotate(RBTNode **root, RBTNode *x) { RBTNode *y = x->left; x->left = y->right; if (y->right) set_parent(y->right, x); set_parent(y, parent(x)); if (!parent(y)) { RBT_ASSERT(*root == x); *root = y; } else if (x == parent(x)->right) parent(x)->right = y; else { RBT_ASSERT(x == parent(x)->left); parent(x)->left = y; } y->right = x; set_parent(x, y); } /* * Replace node x with node y * NOTE: segment descriptor of y is not changed */ static ERTS_INLINE void replace(RBTNode **root, RBTNode *x, RBTNode *y) { if (!parent(x)) { RBT_ASSERT(*root == x); *root = y; } else if (x == parent(x)->left) parent(x)->left = y; else { RBT_ASSERT(x == parent(x)->right); parent(x)->right = y; } if (x->left) { RBT_ASSERT(parent(x->left) == x); set_parent(x->left, y); } if (x->right) { RBT_ASSERT(parent(x->right) == x); set_parent(x->right, y); } y->parent_and_color = x->parent_and_color; y->right = x->right; y->left = x->left; } static void tree_insert_fixup(RBTNode** root, RBTNode *node) { RBTNode *x = node, *y, *papa_x, *granpa_x; /* * Rearrange the tree so that it satisfies the Red-Black Tree properties */ papa_x = parent(x); RBT_ASSERT(x != *root && IS_RED(papa_x)); do { /* * x and its parent are both red. Move the red pair up the tree * until we get to the root or until we can separate them. */ granpa_x = parent(papa_x); RBT_ASSERT(IS_RED(x)); RBT_ASSERT(IS_BLACK(granpa_x)); RBT_ASSERT(granpa_x); if (papa_x == granpa_x->left) { y = granpa_x->right; if (IS_RED(y)) { SET_BLACK(y); SET_BLACK(papa_x); SET_RED(granpa_x); x = granpa_x; } else { if (x == papa_x->right) { left_rotate(root, papa_x); papa_x = x; x = papa_x->left; } RBT_ASSERT(x == granpa_x->left->left); RBT_ASSERT(IS_RED(x)); RBT_ASSERT(IS_RED(papa_x)); RBT_ASSERT(IS_BLACK(granpa_x)); RBT_ASSERT(IS_BLACK(y)); SET_BLACK(papa_x); SET_RED(granpa_x); right_rotate(root, granpa_x); RBT_ASSERT(x == parent(x)->left); RBT_ASSERT(IS_RED(x)); RBT_ASSERT(IS_RED(parent(x)->right)); RBT_ASSERT(IS_BLACK(parent(x))); break; } } else { RBT_ASSERT(papa_x == granpa_x->right); y = granpa_x->left; if (IS_RED(y)) { SET_BLACK(y); SET_BLACK(papa_x); SET_RED(granpa_x); x = granpa_x; } else { if (x == papa_x->left) { right_rotate(root, papa_x); papa_x = x; x = papa_x->right; } RBT_ASSERT(x == granpa_x->right->right); RBT_ASSERT(IS_RED(x)); RBT_ASSERT(IS_RED(papa_x)); RBT_ASSERT(IS_BLACK(granpa_x)); RBT_ASSERT(IS_BLACK(y)); SET_BLACK(papa_x); SET_RED(granpa_x); left_rotate(root, granpa_x); RBT_ASSERT(x == parent(x)->right); RBT_ASSERT(IS_RED(x)); RBT_ASSERT(IS_RED(parent(x)->left)); RBT_ASSERT(IS_BLACK(parent(x))); break; } } } while (x != *root && (papa_x=parent(x), IS_RED(papa_x))); SET_BLACK(*root); } static void rbt_delete(RBTree* tree, RBTNode* del) { Uint spliced_is_black; RBTNode *x, *y, *z = del, *papa_y; RBTNode null_x; /* null_x is used to get the fixup started when we splice out a node without children. */ HARD_CHECK_IS_MEMBER(tree->root, del); HARD_CHECK_TREE(tree, 0); null_x.parent_and_color = parent_and_color(NULL, !RED_FLG); /* Remove node from tree... */ /* Find node to splice out */ if (!z->left || !z->right) y = z; else /* Set y to z:s successor */ for(y = z->right; y->left; y = y->left); /* splice out y */ x = y->left ? y->left : y->right; spliced_is_black = IS_BLACK(y); papa_y = parent(y); if (x) { set_parent(x, papa_y); } else if (spliced_is_black) { x = &null_x; x->right = x->left = NULL; x->parent_and_color = parent_and_color(papa_y, !RED_FLG); y->left = x; } if (!papa_y) { RBT_ASSERT(tree->root == y); tree->root = x; } else { if (y == papa_y->left) { papa_y->left = x; } else { RBT_ASSERT(y == papa_y->right); papa_y->right = x; } } if (y != z) { /* We spliced out the successor of z; replace z by the successor */ RBT_ASSERT(z != &null_x); replace(&tree->root, z, y); } if (spliced_is_black) { RBTNode* papa_x; /* We removed a black node which makes the resulting tree violate the Red-Black Tree properties. Fixup tree... */ papa_x = parent(x); while (IS_BLACK(x) && papa_x) { /* * x has an "extra black" which we move up the tree * until we reach the root or until we can get rid of it. * * y is the sibbling of x */ if (x == papa_x->left) { y = papa_x->right; RBT_ASSERT(y); if (IS_RED(y)) { RBT_ASSERT(y->right); RBT_ASSERT(y->left); SET_BLACK(y); RBT_ASSERT(IS_BLACK(papa_x)); SET_RED(papa_x); left_rotate(&tree->root, papa_x); RBT_ASSERT(papa_x == parent(x)); y = papa_x->right; } RBT_ASSERT(y); RBT_ASSERT(IS_BLACK(y)); if (IS_BLACK(y->left) && IS_BLACK(y->right)) { SET_RED(y); } else { if (IS_BLACK(y->right)) { SET_BLACK(y->left); SET_RED(y); right_rotate(&tree->root, y); RBT_ASSERT(papa_x == parent(x)); y = papa_x->right; } RBT_ASSERT(y); if (IS_RED(papa_x)) { SET_BLACK(papa_x); SET_RED(y); } RBT_ASSERT(y->right); SET_BLACK(y->right); left_rotate(&tree->root, papa_x); x = tree->root; break; } } else { RBT_ASSERT(x == papa_x->right); y = papa_x->left; RBT_ASSERT(y); if (IS_RED(y)) { RBT_ASSERT(y->right); RBT_ASSERT(y->left); SET_BLACK(y); RBT_ASSERT(IS_BLACK(papa_x)); SET_RED(papa_x); right_rotate(&tree->root, papa_x); RBT_ASSERT(papa_x == parent(x)); y = papa_x->left; } RBT_ASSERT(y); RBT_ASSERT(IS_BLACK(y)); if (IS_BLACK(y->right) && IS_BLACK(y->left)) { SET_RED(y); } else { if (IS_BLACK(y->left)) { SET_BLACK(y->right); SET_RED(y); left_rotate(&tree->root, y); RBT_ASSERT(papa_x == parent(x)); y = papa_x->left; } RBT_ASSERT(y); if (IS_RED(papa_x)) { SET_BLACK(papa_x); SET_RED(y); } RBT_ASSERT(y->left); SET_BLACK(y->left); right_rotate(&tree->root, papa_x); x = tree->root; break; } } x = papa_x; papa_x = parent(x); } SET_BLACK(x); papa_x = parent(&null_x); if (papa_x) { if (papa_x->left == &null_x) papa_x->left = NULL; else { RBT_ASSERT(papa_x->right == &null_x); papa_x->right = NULL; } RBT_ASSERT(!null_x.left); RBT_ASSERT(!null_x.right); } else if (tree->root == &null_x) { tree->root = NULL; RBT_ASSERT(!null_x.left); RBT_ASSERT(!null_x.right); } } HARD_CHECK_TREE(tree, 0); } static void rbt_insert(enum SortOrder order, RBTree* tree, RBTNode* node) { #ifdef RBT_DEBUG ErtsFreeSegDesc *dbg_under=NULL, *dbg_over=NULL; #endif ErtsFreeSegDesc* desc = node_to_desc(order, node); char* seg_addr = desc->start; SWord seg_sz = desc->end - desc->start; HARD_CHECK_TREE(tree, 0); node->left = NULL; node->right = NULL; if (!tree->root) { node->parent_and_color = parent_and_color(NULL, !RED_FLG); tree->root = node; } else { RBTNode *x = tree->root; while (1) { SWord diff = cmp_with_node(order, seg_sz, seg_addr, x); if (diff < 0) { IF_RBT_DEBUG(dbg_over = node_to_desc(order, x)); if (!x->left) { node->parent_and_color = parent_and_color(x, RED_FLG); x->left = node; break; } x = x->left; } else { RBT_ASSERT(diff > 0); IF_RBT_DEBUG(dbg_under = node_to_desc(order, x)); if (!x->right) { node->parent_and_color = parent_and_color(x, RED_FLG); x->right = node; break; } x = x->right; } } RBT_ASSERT(parent(node)); #ifdef RBT_DEBUG if (order == ADDR_ORDER) { RBT_ASSERT(!dbg_under || dbg_under->end < desc->start); RBT_ASSERT(!dbg_over || dbg_over->start > desc->end); } #endif RBT_ASSERT(IS_RED(node)); if (IS_RED(parent(node))) tree_insert_fixup(&tree->root, node); } HARD_CHECK_TREE(tree, 0); } /* * Traverse tree in (reverse) sorting order */ static void rbt_foreach_node(RBTree* tree, void (*fn)(RBTNode*,void*), void* arg, int reverse) { #ifdef HARD_DEBUG Sint blacks = -1; Sint curr_blacks = 1; Uint depth = 1; Uint max_depth = 0; Uint node_cnt = 0; #endif enum { RECURSE_LEFT, DO_NODE, RECURSE_RIGHT, RETURN_TO_PARENT }state; RBTNode *x = tree->root; RBT_ASSERT(!x || !parent(x)); state = reverse ? RECURSE_RIGHT : RECURSE_LEFT; while (x) { switch (state) { case RECURSE_LEFT: if (x->left) { RBT_ASSERT(parent(x->left) == x); #ifdef HARD_DEBUG ++depth; if (IS_BLACK(x->left)) curr_blacks++; #endif x = x->left; state = reverse ? RECURSE_RIGHT : RECURSE_LEFT; } else { #ifdef HARD_DEBUG if (blacks < 0) blacks = curr_blacks; RBT_ASSERT(blacks == curr_blacks); #endif state = reverse ? RETURN_TO_PARENT : DO_NODE; } break; case DO_NODE: #ifdef HARD_DEBUG ++node_cnt; if (depth > max_depth) max_depth = depth; #endif (*fn) (x, arg); /* Do it! */ state = reverse ? RECURSE_LEFT : RECURSE_RIGHT; break; case RECURSE_RIGHT: if (x->right) { RBT_ASSERT(parent(x->right) == x); #ifdef HARD_DEBUG ++depth; if (IS_BLACK(x->right)) curr_blacks++; #endif x = x->right; state = reverse ? RECURSE_RIGHT : RECURSE_LEFT; } else { #ifdef HARD_DEBUG if (blacks < 0) blacks = curr_blacks; RBT_ASSERT(blacks == curr_blacks); #endif state = reverse ? DO_NODE : RETURN_TO_PARENT; } break; case RETURN_TO_PARENT: #ifdef HARD_DEBUG if (IS_BLACK(x)) curr_blacks--; --depth; #endif if (parent(x)) { if (x == parent(x)->left) { state = reverse ? RETURN_TO_PARENT : DO_NODE; } else { RBT_ASSERT(x == parent(x)->right); state = reverse ? DO_NODE : RETURN_TO_PARENT; } } x = parent(x); break; } } #ifdef HARD_DEBUG RBT_ASSERT(depth == 0 || (!tree->root && depth==1)); RBT_ASSERT(curr_blacks == 0); RBT_ASSERT((1 << (max_depth/2)) <= node_cnt); #endif } #ifdef RBT_DEBUG static RBTNode* rbt_prev_node(RBTNode* node) { RBTNode* x; if (node->left) { for (x=node->left; x->right; x=x->right) ; return x; } for (x=node; parent(x); x=parent(x)) { if (parent(x)->right == x) return parent(x); } return NULL; } static RBTNode* rbt_next_node(RBTNode* node) { RBTNode* x; if (node->right) { for (x=node->right; x->left; x=x->left) ; return x; } for (x=node; parent(x); x=parent(x)) { if (parent(x)->left == x) return parent(x); } return NULL; } #endif /* RBT_DEBUG */ /* The API to keep track of a bunch of separated (free) segments (non-overlapping and non-adjacent). */ static void init_free_seg_map(ErtsFreeSegMap*, int reverse_ao); static void adjacent_free_seg(ErtsFreeSegMap*, char* start, char* end, ErtsFreeSegDesc** under, ErtsFreeSegDesc** over); static void insert_free_seg(ErtsFreeSegMap*, ErtsFreeSegDesc*, char* start, char* end); static void resize_free_seg(ErtsFreeSegMap*, ErtsFreeSegDesc*, char* start, char* end); static void delete_free_seg(ErtsFreeSegMap*, ErtsFreeSegDesc*); static ErtsFreeSegDesc* lookup_free_seg(ErtsFreeSegMap*, SWord sz); static void init_free_seg_map(ErtsFreeSegMap* map, int reverse_ao) { map->atree.root = NULL; map->atree.order = ADDR_ORDER; map->stree.root = NULL; map->stree.order = reverse_ao ? SZ_REVERSE_ADDR_ORDER : SZ_ADDR_ORDER; map->nseg = 0; } /* Lookup directly adjacent free segments to the given area [start->end]. * The given area must not contain any free segments. */ static void adjacent_free_seg(ErtsFreeSegMap* map, char* start, char* end, ErtsFreeSegDesc** under, ErtsFreeSegDesc** over) { RBTNode* x = map->atree.root; *under = NULL; *over = NULL; while (x) { if (start < anode_to_desc(x)->start) { RBT_ASSERT(end <= anode_to_desc(x)->start); if (end == anode_to_desc(x)->start) { RBT_ASSERT(!*over); *over = anode_to_desc(x); } x = x->left; } else { RBT_ASSERT(start >= anode_to_desc(x)->end); if (start == anode_to_desc(x)->end) { RBT_ASSERT(!*under); *under = anode_to_desc(x); } x = x->right; } } } /* Initialize 'desc' and insert as new free segment [start->end]. * The new segment must not contain or be adjacent to any free segment in 'map'. */ static void insert_free_seg(ErtsFreeSegMap* map, ErtsFreeSegDesc* desc, char* start, char* end) { desc->start = start; desc->end = end; rbt_insert(map->atree.order, &map->atree, &desc->anode); rbt_insert(map->stree.order, &map->stree, &desc->snode); map->nseg++; } /* Resize existing free segment 'desc' to [start->end]. * The new segment location must overlap the old location and * it must not contain or be adjacent to any other free segment in 'map'. */ static void resize_free_seg(ErtsFreeSegMap* map, ErtsFreeSegDesc* desc, char* start, char* end) { #ifdef RBT_DEBUG RBTNode* prev = rbt_prev_node(&desc->anode); RBTNode* next = rbt_next_node(&desc->anode); RBT_ASSERT(!prev || anode_to_desc(prev)->end < start); RBT_ASSERT(!next || anode_to_desc(next)->start > end); #endif rbt_delete(&map->stree, &desc->snode); desc->start = start; desc->end = end; rbt_insert(map->stree.order, &map->stree, &desc->snode); } /* Delete existing free segment 'desc' from 'map'. */ static void delete_free_seg(ErtsFreeSegMap* map, ErtsFreeSegDesc* desc) { rbt_delete(&map->atree, &desc->anode); rbt_delete(&map->stree, &desc->snode); map->nseg--; } /* Lookup a free segment in 'map' with a size of at least 'need_sz' bytes. */ static ErtsFreeSegDesc* lookup_free_seg(ErtsFreeSegMap* map, SWord need_sz) { RBTNode* x = map->stree.root; ErtsFreeSegDesc* best_desc = NULL; while (x) { ErtsFreeSegDesc* desc = snode_to_desc(x); SWord seg_sz = desc->end - desc->start; if (seg_sz < need_sz) { x = x->right; } else { best_desc = desc; x = x->left; } } return best_desc; } struct build_arg_t { Process* p; Eterm* hp; Eterm acc; }; static void build_free_seg_tuple(RBTNode* node, void* arg) { struct build_arg_t* a = (struct build_arg_t*)arg; ErtsFreeSegDesc* desc = anode_to_desc(node); Eterm start= erts_bld_uword(&a->hp, NULL, (UWord)desc->start); Eterm end = erts_bld_uword(&a->hp, NULL, (UWord)desc->end); Eterm tpl = TUPLE2(a->hp, start, end); a->hp += 3; a->acc = CONS(a->hp, tpl, a->acc); a->hp += 2; } static Eterm build_free_seg_list(Process* p, ErtsFreeSegMap* map) { struct build_arg_t barg; Eterm* hp_end; const Uint may_need = map->nseg * (2 + 3 + 2*2); /* cons + tuple + bigs */ barg.p = p; barg.hp = HAlloc(p, may_need); hp_end = barg.hp + may_need; barg.acc = NIL; rbt_foreach_node(&map->atree, build_free_seg_tuple, &barg, 1); RBT_ASSERT(barg.hp <= hp_end); HRelease(p, hp_end, barg.hp); return barg.acc; } #if ERTS_HAVE_OS_MMAP /* Implementation of os_mmap()/os_munmap()/os_mremap()... */ #if HAVE_MMAP # define ERTS_MMAP_PROT (PROT_READ|PROT_WRITE) # if defined(MAP_ANONYMOUS) # define ERTS_MMAP_FLAGS (MAP_ANON|MAP_PRIVATE) # define ERTS_MMAP_FD (-1) # elif defined(MAP_ANON) # define ERTS_MMAP_FLAGS (MAP_ANON|MAP_PRIVATE) # define ERTS_MMAP_FD (-1) # else # define ERTS_MMAP_FLAGS (MAP_PRIVATE) # define ERTS_MMAP_FD mmap_state.mmap_fd # endif #endif static ERTS_INLINE void * os_mmap(UWord size, int try_superalign) { #if HAVE_MMAP void *res; #ifdef MAP_ALIGN if (try_superalign) res = mmap((void *) ERTS_SUPERALIGNED_SIZE, size, ERTS_MMAP_PROT, ERTS_MMAP_FLAGS|MAP_ALIGN, ERTS_MMAP_FD, 0); else #endif res = mmap((void *) 0, size, ERTS_MMAP_PROT, ERTS_MMAP_FLAGS, ERTS_MMAP_FD, 0); if (res == MAP_FAILED) return NULL; return res; #elif HAVE_VIRTUALALLOC return (void *) VirtualAlloc(NULL, (SIZE_T) size, MEM_COMMIT|MEM_RESERVE, PAGE_READWRITE); #else # error "missing mmap() or similar" #endif } static ERTS_INLINE void os_munmap(void *ptr, UWord size) { #if HAVE_MMAP #ifdef ERTS_MMAP_DEBUG int res = #endif munmap(ptr, size); ERTS_MMAP_ASSERT(res == 0); #elif HAVE_VIRTUALALLOC #ifdef DEBUG BOOL res = #endif VirtualFree((LPVOID) ptr, (SIZE_T) 0, MEM_RELEASE); ERTS_MMAP_ASSERT(res != 0); #else # error "missing munmap() or similar" #endif } #ifdef ERTS_HAVE_OS_MREMAP # if HAVE_MREMAP # if defined(__NetBSD__) # define ERTS_MREMAP_FLAGS (0) # else # define ERTS_MREMAP_FLAGS (MREMAP_MAYMOVE) # endif # endif static ERTS_INLINE void * os_mremap(void *ptr, UWord old_size, UWord new_size, int try_superalign) { void *new_seg; #if HAVE_MREMAP new_seg = mremap(ptr, (size_t) old_size, # if defined(__NetBSD__) NULL, # endif (size_t) new_size, ERTS_MREMAP_FLAGS); if (new_seg == (void *) MAP_FAILED) return NULL; return new_seg; #else # error "missing mremap() or similar" #endif } #endif #ifdef ERTS_HAVE_OS_PHYSICAL_MEMORY_RESERVATION #if HAVE_MMAP #define ERTS_MMAP_RESERVE_PROT (ERTS_MMAP_PROT) #define ERTS_MMAP_RESERVE_FLAGS (ERTS_MMAP_FLAGS|MAP_FIXED) #define ERTS_MMAP_UNRESERVE_PROT (PROT_NONE) #define ERTS_MMAP_UNRESERVE_FLAGS (ERTS_MMAP_FLAGS|MAP_NORESERVE|MAP_FIXED) #define ERTS_MMAP_VIRTUAL_PROT (PROT_NONE) #define ERTS_MMAP_VIRTUAL_FLAGS (ERTS_MMAP_FLAGS|MAP_NORESERVE) static int os_reserve_physical(char *ptr, UWord size) { void *res = mmap((void *) ptr, (size_t) size, ERTS_MMAP_RESERVE_PROT, ERTS_MMAP_RESERVE_FLAGS, ERTS_MMAP_FD, 0); if (res == (void *) MAP_FAILED) return 0; return 1; } static void os_unreserve_physical(char *ptr, UWord size) { void *res = mmap((void *) ptr, (size_t) size, ERTS_MMAP_UNRESERVE_PROT, ERTS_MMAP_UNRESERVE_FLAGS, ERTS_MMAP_FD, 0); if (res == (void *) MAP_FAILED) erl_exit(ERTS_ABORT_EXIT, "Failed to unreserve memory"); } static void * os_mmap_virtual(char *ptr, UWord size) { void *res = mmap((void *) ptr, (size_t) size, ERTS_MMAP_VIRTUAL_PROT, ERTS_MMAP_VIRTUAL_FLAGS, ERTS_MMAP_FD, 0); if (res == (void *) MAP_FAILED) return NULL; return res; } #else #error "Missing reserve/unreserve physical memory implementation" #endif #endif /* ERTS_HAVE_OS_RESERVE_PHYSICAL_MEMORY */ #endif /* ERTS_HAVE_OS_MMAP */ static int reserve_noop(char *ptr, UWord size) { #ifdef ERTS_MMAP_DEBUG_FILL_AREAS Uint32 *uip, *end = (Uint32 *) (ptr + size); for (uip = (Uint32 *) ptr; uip < end; uip++) ERTS_MMAP_ASSERT(*uip == (Uint32) 0xdeadbeef); for (uip = (Uint32 *) ptr; uip < end; uip++) *uip = (Uint32) 0xfeedfeed; #endif return 1; } static void unreserve_noop(char *ptr, UWord size) { #ifdef ERTS_MMAP_DEBUG_FILL_AREAS Uint32 *uip, *end = (Uint32 *) (ptr + size); for (uip = (Uint32 *) ptr; uip < end; uip++) *uip = (Uint32) 0xdeadbeef; #endif } static ERTS_INLINE UWord alloc_desc_insert_free_seg(ErtsFreeSegMap *map, char* start, char* end) { UWord ad_sz; char *new_end; ErtsFreeSegDesc *desc = alloc_desc(); if (desc) { insert_free_seg(map, desc, start, end); return 0; } /* Use part of the free segment for descriptors */ if (map == &mmap_state.sa.map) { ERTS_MMAP_SIZE_SC_SA_INC(ERTS_SUPERALIGNED_SIZE); ad_sz = ERTS_SUPERALIGNED_SIZE; } else { ERTS_MMAP_SIZE_SC_SUA_INC(ERTS_PAGEALIGNED_SIZE); ad_sz = ERTS_PAGEALIGNED_SIZE; } new_end = end - ad_sz; ERTS_MMAP_ASSERT(start <= new_end); if (start != new_end) { desc = alloc_desc(); ERTS_MMAP_ASSERT(desc); insert_free_seg(map, desc, start, new_end); } return ad_sz; } void * erts_mmap(Uint32 flags, UWord *sizep) { char *seg; UWord asize = ERTS_PAGEALIGNED_CEILING(*sizep); /* Map in premapped supercarrier */ if (mmap_state.supercarrier && !(ERTS_MMAPFLG_OS_ONLY & flags)) { char *end; ErtsFreeSegDesc *desc; Uint32 superaligned = (ERTS_MMAPFLG_SUPERALIGNED & flags); erts_smp_mtx_lock(&mmap_state.mtx); if (!superaligned) { desc = lookup_free_seg(&mmap_state.sua.map, asize); if (desc) { seg = desc->start; end = seg+asize; if (!mmap_state.reserve_physical(seg, asize)) goto supercarrier_reserve_failure; if (desc->end == end) { delete_free_seg(&mmap_state.sua.map, desc); free_desc(desc); } else { ERTS_MMAP_ASSERT(end < desc->end); resize_free_seg(&mmap_state.sua.map, desc, end, desc->end); } ERTS_MMAP_SIZE_SC_SUA_INC(asize); goto supercarrier_success; } if (asize <= mmap_state.sua.bot - mmap_state.sa.top) { if (!mmap_state.reserve_physical(mmap_state.sua.bot - asize, asize)) goto supercarrier_reserve_failure; mmap_state.sua.bot -= asize; seg = mmap_state.sua.bot; ERTS_MMAP_SIZE_SC_SUA_INC(asize); goto supercarrier_success; } } asize = ERTS_SUPERALIGNED_CEILING(asize); desc = lookup_free_seg(&mmap_state.sa.map, asize); if (desc) { seg = desc->start; end = seg+asize; if (!mmap_state.reserve_physical(seg, asize)) goto supercarrier_reserve_failure; if (desc->end == end) { delete_free_seg(&mmap_state.sa.map, desc); free_desc(desc); } else { ERTS_MMAP_ASSERT(end < desc->end); resize_free_seg(&mmap_state.sa.map, desc, end, desc->end); } ERTS_MMAP_SIZE_SC_SA_INC(asize); goto supercarrier_success; } if (superaligned) { if (asize <= mmap_state.sua.bot - mmap_state.sa.top) { seg = (void *) mmap_state.sa.top; if (!mmap_state.reserve_physical(seg, asize)) goto supercarrier_reserve_failure; mmap_state.sa.top += asize; ERTS_MMAP_SIZE_SC_SA_INC(asize); goto supercarrier_success; } desc = lookup_free_seg(&mmap_state.sua.map, asize + ERTS_SUPERALIGNED_SIZE); if (desc) { char *org_start = desc->start; char *org_end = desc->end; seg = (char *) ERTS_SUPERALIGNED_CEILING(org_start); end = seg + asize; if (!mmap_state.reserve_physical(seg, asize)) goto supercarrier_reserve_failure; ERTS_MMAP_SIZE_SC_SUA_INC(asize); if (org_start != seg) { ERTS_MMAP_ASSERT(org_start < seg); resize_free_seg(&mmap_state.sua.map, desc, org_start, seg); desc = NULL; } if (end != org_end) { ERTS_MMAP_ASSERT(end < org_end); if (desc) resize_free_seg(&mmap_state.sua.map, desc, end, org_end); else alloc_desc_insert_free_seg(&mmap_state.sua.map, end, org_end); } goto supercarrier_success; } } erts_smp_mtx_unlock(&mmap_state.mtx); } #if ERTS_HAVE_OS_MMAP /* Map using OS primitives */ if (!(ERTS_MMAPFLG_SUPERCARRIER_ONLY & flags) && !mmap_state.no_os_mmap) { if (!(ERTS_MMAPFLG_SUPERALIGNED & flags)) { seg = os_mmap(asize, 0); if (!seg) return NULL; } else { asize = ERTS_SUPERALIGNED_CEILING(*sizep); seg = os_mmap(asize, 1); if (!seg) return NULL; if (!ERTS_IS_SUPERALIGNED(seg)) { char *ptr; UWord sz; os_munmap(seg, asize); ptr = os_mmap(asize + ERTS_SUPERALIGNED_SIZE, 1); if (!ptr) return NULL; seg = (char *) ERTS_SUPERALIGNED_CEILING(ptr); sz = (UWord) (seg - ptr); ERTS_MMAP_ASSERT(sz <= ERTS_SUPERALIGNED_SIZE); if (sz) os_munmap(ptr, sz); sz = ERTS_SUPERALIGNED_SIZE - sz; if (sz) os_munmap(seg+asize, sz); } } ERTS_MMAP_SIZE_OS_INC(asize); *sizep = asize; return (void *) seg; } #endif *sizep = 0; return NULL; supercarrier_success: #ifdef ERTS_MMAP_DEBUG if ((ERTS_MMAPFLG_SUPERALIGNED & flags) || ERTS_MMAP_IN_SUPERALIGNED_AREA(seg)) { ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(seg)); ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(asize)); } else { ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(seg)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(asize)); } #endif erts_smp_mtx_unlock(&mmap_state.mtx); *sizep = asize; return (void *) seg; supercarrier_reserve_failure: erts_smp_mtx_unlock(&mmap_state.mtx); *sizep = 0; return NULL; } void erts_munmap(Uint32 flags, void **ptrp, UWord *sizep) { void *ptr = *ptrp; UWord size = *sizep; ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(ptr)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(size)); if (!ERTS_MMAP_IN_SUPERCARRIER(ptr)) { ERTS_MMAP_ASSERT(!mmap_state.no_os_mmap); #if ERTS_HAVE_OS_MMAP ERTS_MMAP_SIZE_OS_DEC(size); os_munmap(ptr, size); #endif } else { char *start, *end; ErtsFreeSegMap *map; ErtsFreeSegDesc *prev, *next, *desc; UWord ad_sz = 0; ERTS_MMAP_ASSERT(mmap_state.supercarrier); start = (char *) ptr; end = start + size; erts_smp_mtx_lock(&mmap_state.mtx); if (ERTS_MMAP_IN_SUPERALIGNED_AREA(ptr)) { start = (char *) ERTS_SUPERALIGNED_CEILING(start); end = (char *) ERTS_SUPERALIGNED_FLOOR(end); size = (UWord) (end - start); *ptrp = start; *sizep = size; map = &mmap_state.sa.map; adjacent_free_seg(map, start, end, &prev, &next); ERTS_MMAP_SIZE_SC_SA_DEC(size); if (end == mmap_state.sa.top) { ERTS_MMAP_ASSERT(!next); if (prev) { start = prev->start; delete_free_seg(map, prev); free_desc(prev); } mmap_state.sa.top = start; goto supercarrier_success; } } else { ERTS_MMAP_ASSERT(ERTS_MMAP_IN_SUPERUNALIGNED_AREA(ptr)); map = &mmap_state.sua.map; adjacent_free_seg(map, start, end, &prev, &next); ERTS_MMAP_SIZE_SC_SUA_DEC(size); if (start == mmap_state.sua.bot) { ERTS_MMAP_ASSERT(!prev); if (next) { end = next->end; delete_free_seg(map, next); free_desc(next); } mmap_state.sua.bot = end; goto supercarrier_success; } } desc = NULL; if (next) { ERTS_MMAP_ASSERT(end < next->end); end = next->end; if (prev) { delete_free_seg(map, next); free_desc(next); goto save_prev; } desc = next; } else if (prev) { save_prev: ERTS_MMAP_ASSERT(prev->start < start); start = prev->start; desc = prev; } if (desc) resize_free_seg(map, desc, start, end); else ad_sz = alloc_desc_insert_free_seg(map, start, end); supercarrier_success: { UWord unres_sz; erts_smp_mtx_unlock(&mmap_state.mtx); ERTS_MMAP_ASSERT(size >= ad_sz); unres_sz = size - ad_sz; if (unres_sz) mmap_state.unreserve_physical((char *) ptr, unres_sz); } } } static void * remap_move(Uint32 flags, void *ptr, UWord old_size, UWord *sizep) { UWord size = *sizep; UWord um_size = old_size; void *um_ptr = ptr; void *new_ptr = erts_mmap(flags, &size); if (!new_ptr) return NULL; *sizep = size; if (old_size < size) size = old_size; sys_memcpy(new_ptr, ptr, (size_t) size); erts_munmap(flags, &um_ptr, &um_size); ERTS_MMAP_ASSERT(um_ptr == ptr); ERTS_MMAP_ASSERT(um_size == old_size); return new_ptr; } void * erts_mremap(Uint32 flags, void *ptr, UWord old_size, UWord *sizep) { void *new_ptr; Uint32 superaligned; UWord asize; ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(ptr)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(old_size)); ERTS_MMAP_ASSERT(sizep && ERTS_IS_PAGEALIGNED(*sizep)); if (!ERTS_MMAP_IN_SUPERCARRIER(ptr)) { ERTS_MMAP_ASSERT(!mmap_state.no_os_mmap); if (!(ERTS_MMAPFLG_OS_ONLY & flags) && mmap_state.supercarrier) { new_ptr = remap_move(ERTS_MMAPFLG_SUPERCARRIER_ONLY|flags, ptr, old_size, sizep); if (new_ptr) return new_ptr; } if (ERTS_MMAPFLG_SUPERCARRIER_ONLY & flags) return NULL; #if ERTS_HAVE_OS_MREMAP || ERTS_HAVE_GENUINE_OS_MMAP superaligned = (ERTS_MMAPFLG_SUPERALIGNED & flags); if (superaligned) { asize = ERTS_SUPERALIGNED_CEILING(*sizep); if (asize == old_size && ERTS_IS_SUPERALIGNED(ptr)) { *sizep = asize; return ptr; } } else { asize = ERTS_PAGEALIGNED_CEILING(*sizep); if (asize == old_size) { *sizep = asize; return ptr; } } #if ERTS_HAVE_GENUINE_OS_MMAP if (asize < old_size && (!superaligned || ERTS_IS_SUPERALIGNED(ptr))) { UWord um_sz; new_ptr = ((char *) ptr) + asize; ERTS_MMAP_ASSERT((((char *)ptr) + old_size) > (char *) new_ptr); um_sz = (UWord) ((((char *) ptr) + old_size) - (char *) new_ptr); ERTS_MMAP_SIZE_OS_DEC(um_sz); os_munmap(new_ptr, um_sz); *sizep = asize; return ptr; } #endif #if ERTS_HAVE_OS_MREMAP if (superaligned) return remap_move(flags, new_ptr, old_size, sizep); else { new_ptr = os_mremap(ptr, old_size, asize, 0); if (!new_ptr) return NULL; if (asize > old_size) ERTS_MMAP_SIZE_OS_INC(asize - old_size); else ERTS_MMAP_SIZE_OS_DEC(old_size - asize); *sizep = asize; return new_ptr; } #endif #endif } else { /* In super carrier */ char *start, *end, *new_end; ErtsFreeSegMap *map; ErtsFreeSegDesc *prev, *next; UWord ad_sz = 0; ERTS_MMAP_ASSERT(mmap_state.supercarrier); if (ERTS_MMAPFLG_OS_ONLY & flags) return remap_move(flags, ptr, old_size, sizep); superaligned = (ERTS_MMAPFLG_SUPERALIGNED & flags); asize = (superaligned ? ERTS_SUPERALIGNED_CEILING(*sizep) : ERTS_PAGEALIGNED_CEILING(*sizep)); erts_smp_mtx_lock(&mmap_state.mtx); if (ERTS_MMAP_IN_SUPERALIGNED_AREA(ptr) ? (!superaligned && lookup_free_seg(&mmap_state.sua.map, asize)) : (superaligned && lookup_free_seg(&mmap_state.sa.map, asize))) { erts_smp_mtx_unlock(&mmap_state.mtx); /* * Segment currently in wrong area (due to a previous memory * shortage), move it to the right area. * (remap_move() will succeed) */ return remap_move(ERTS_MMAPFLG_SUPERCARRIER_ONLY|flags, ptr, old_size, sizep); } if (asize == old_size) { new_ptr = ptr; goto supercarrier_resize_success; } start = (char *) ptr; end = start + old_size; new_end = start+asize; if (asize < old_size) { UWord unres_sz; new_ptr = ptr; if (!ERTS_MMAP_IN_SUPERALIGNED_AREA(ptr)) { ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(ptr)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(old_size)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(asize)); map = &mmap_state.sua.map; ERTS_MMAP_SIZE_SC_SUA_DEC(old_size - asize); } else { ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(ptr)); ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(old_size)); if (!superaligned) { /* must be a superaligned size in this area */ asize = ERTS_SUPERALIGNED_CEILING(asize); ERTS_MMAP_ASSERT(asize <= old_size); if (asize == old_size) goto supercarrier_resize_success; new_end = start+asize; } ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(asize)); if (end == mmap_state.sa.top) { mmap_state.sa.top = new_end; mmap_state.unreserve_physical(((char *) ptr) + asize, old_size - asize); goto supercarrier_resize_success; } ERTS_MMAP_SIZE_SC_SA_DEC(old_size - asize); map = &mmap_state.sa.map; } adjacent_free_seg(map, start, end, &prev, &next); if (next) resize_free_seg(map, next, new_end, next->end); else ad_sz = alloc_desc_insert_free_seg(map, new_end, end); ERTS_MMAP_ASSERT(old_size - asize >= ad_sz); unres_sz = old_size - asize - ad_sz; if (unres_sz) mmap_state.unreserve_physical(((char *) ptr) + asize, unres_sz); goto supercarrier_resize_success; } if (!ERTS_MMAP_IN_SUPERALIGNED_AREA(ptr)) { ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(ptr)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(old_size)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(asize)); adjacent_free_seg(&mmap_state.sua.map, start, end, &prev, &next); if (next && new_end <= next->end) { if (!mmap_state.reserve_physical(((char *) ptr) + old_size, asize - old_size)) goto supercarrier_reserve_failure; if (new_end < next->end) resize_free_seg(&mmap_state.sua.map, next, new_end, next->end); else { delete_free_seg(&mmap_state.sua.map, next); free_desc(next); } new_ptr = ptr; ERTS_MMAP_SIZE_SC_SUA_INC(asize - old_size); goto supercarrier_resize_success; } } else { /* Superaligned area */ ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(ptr)); ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(old_size)); if (!superaligned) { /* must be a superaligned size in this area */ asize = ERTS_PAGEALIGNED_CEILING(asize); new_end = start+asize; } ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(asize)); if (end == mmap_state.sa.top) { if (new_end <= mmap_state.sua.bot) { if (!mmap_state.reserve_physical(((char *) ptr) + old_size, asize - old_size)) goto supercarrier_reserve_failure; mmap_state.sa.top = new_end; new_ptr = ptr; ERTS_MMAP_SIZE_SC_SA_INC(asize - old_size); goto supercarrier_resize_success; } } else { adjacent_free_seg(&mmap_state.sa.map, start, end, &prev, &next); if (next && new_end <= next->end) { if (!mmap_state.reserve_physical(((char *) ptr) + old_size, asize - old_size)) goto supercarrier_reserve_failure; if (new_end < next->end) resize_free_seg(&mmap_state.sa.map, next, new_end, next->end); else { delete_free_seg(&mmap_state.sa.map, next); free_desc(next); } new_ptr = ptr; ERTS_MMAP_SIZE_SC_SA_INC(asize - old_size); goto supercarrier_resize_success; } } } erts_smp_mtx_unlock(&mmap_state.mtx); /* Failed to resize... */ } return remap_move(flags, ptr, old_size, sizep); supercarrier_resize_success: #ifdef ERTS_MMAP_DEBUG if ((ERTS_MMAPFLG_SUPERALIGNED & flags) || ERTS_MMAP_IN_SUPERALIGNED_AREA(new_ptr)) { ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(new_ptr)); ERTS_MMAP_ASSERT(ERTS_IS_SUPERALIGNED(asize)); } else { ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(new_ptr)); ERTS_MMAP_ASSERT(ERTS_IS_PAGEALIGNED(asize)); } #endif erts_smp_mtx_unlock(&mmap_state.mtx); *sizep = asize; return new_ptr; supercarrier_reserve_failure: erts_smp_mtx_unlock(&mmap_state.mtx); *sizep = 0; return NULL; } int erts_mmap_in_supercarrier(void *ptr) { return ERTS_MMAP_IN_SUPERCARRIER(ptr); } void erts_mmap_init(ErtsMMapInit *init) { int virtual_map = 0; char *start = NULL, *end = NULL; UWord pagesize; #if defined(__WIN32__) SYSTEM_INFO sysinfo; GetSystemInfo(&sysinfo); pagesize = (UWord) sysinfo.dwPageSize; #elif defined(_SC_PAGESIZE) pagesize = (UWord) sysconf(_SC_PAGESIZE); #elif defined(HAVE_GETPAGESIZE) pagesize = (UWord) getpagesize(); #else # error "Do not know how to get page size" #endif #if defined(HARD_DEBUG) || 0 erts_fprintf(stderr, "erts_mmap: scs = %bpu\n", init->scs); erts_fprintf(stderr, "erts_mmap: sco = %i\n", init->sco); erts_fprintf(stderr, "erts_mmap: scmgc = %i\n", init->scmgc); #endif erts_page_inv_mask = pagesize - 1; if (pagesize & erts_page_inv_mask) erl_exit(-1, "erts_mmap: Invalid pagesize: %bpu\n", pagesize); erts_have_erts_mmap = 0; mmap_state.reserve_physical = reserve_noop; mmap_state.unreserve_physical = unreserve_noop; #if HAVE_MMAP && !defined(MAP_ANON) mmap_state.mmap_fd = open("/dev/zero", O_RDWR); if (mmap_state.mmap_fd < 0) erl_exit(-1, "erts_mmap: Failed to open /dev/zero\n"); #endif erts_smp_mtx_init(&mmap_state.mtx, "erts_mmap"); #ifdef ERTS_HAVE_OS_PHYSICAL_MEMORY_RESERVATION if (init->virtual_range.start) { char *ptr; UWord sz; ptr = (char *) ERTS_PAGEALIGNED_CEILING(init->virtual_range.start); end = (char *) ERTS_PAGEALIGNED_FLOOR(init->virtual_range.end); sz = end - ptr; start = os_mmap_virtual(ptr, sz); if (!start || start > ptr || start >= end) erl_exit(-1, "erts_mmap: Failed to create virtual range for super carrier\n"); sz = start - ptr; if (sz) os_munmap(end, sz); mmap_state.reserve_physical = os_reserve_physical; mmap_state.unreserve_physical = os_unreserve_physical; virtual_map = 1; } else #endif if (init->predefined_area.start) { start = init->predefined_area.start; end = init->predefined_area.end; if (end != (void *) 0 && end < start) end = start; } #if ERTS_HAVE_OS_MMAP else if (init->scs) { UWord sz; sz = ERTS_PAGEALIGNED_CEILING(init->scs); #ifdef ERTS_HAVE_OS_PHYSICAL_MEMORY_RESERVATION if (!init->scrpm) { start = os_mmap_virtual(NULL, sz); mmap_state.reserve_physical = os_reserve_physical; mmap_state.unreserve_physical = os_unreserve_physical; virtual_map = 1; } else #endif { /* * The whole supercarrier will by physically * reserved all the time. */ start = os_mmap(sz, 1); } if (!start) erl_exit(-1, "erts_mmap: Failed to create super carrier of size %bpu MB\n", init->scs/1024/1024); end = start + sz; #ifdef ERTS_MMAP_DEBUG_FILL_AREAS if (!virtual_map) { Uint32 *uip; for (uip = (Uint32 *) start; uip < (Uint32 *) end; uip++) *uip = (Uint32) 0xdeadbeef; } #endif } if (!mmap_state.no_os_mmap) erts_have_erts_mmap |= ERTS_HAVE_ERTS_OS_MMAP; #endif mmap_state.size.supercarrier.total = 0; mmap_state.size.supercarrier.used.total = 0; mmap_state.size.supercarrier.used.sa = 0; mmap_state.size.supercarrier.used.sua = 0; mmap_state.size.os.used = 0; if (!start) { mmap_state.sa.bot = NULL; mmap_state.sua.top = NULL; mmap_state.sa.bot = NULL; mmap_state.sua.top = NULL; mmap_state.no_os_mmap = 0; } else { size_t desc_size; mmap_state.no_os_mmap = init->sco; desc_size = init->scmgc; if (desc_size < 100) desc_size = 100; desc_size *= sizeof(ErtsFreeSegDesc); if ((desc_size + ERTS_SUPERALIGNED_SIZE + ERTS_PAGEALIGNED_SIZE) > end - start) erl_exit(-1, "erts_mmap: No space for segments in super carrier\n"); mmap_state.sa.bot = start; mmap_state.sa.bot += desc_size; mmap_state.sa.bot = (char *) ERTS_SUPERALIGNED_CEILING(mmap_state.sa.bot); mmap_state.sa.top = mmap_state.sa.bot; mmap_state.sua.top = (char *) ERTS_SUPERALIGNED_FLOOR(end); mmap_state.sua.bot = mmap_state.sua.top; mmap_state.size.os.used += (UWord) (mmap_state.sa.bot - start); if (end == (void *) 0) { /* * Very unlikely, but we need a guarantee * that `mmap_state.sua.top` always will * compare as larger than all segment pointers * into the super carrier... */ mmap_state.sua.top -= ERTS_PAGEALIGNED_SIZE; mmap_state.size.os.used += ERTS_PAGEALIGNED_SIZE; } mmap_state.size.supercarrier.total = (UWord) (mmap_state.sua.top - mmap_state.sa.bot); /* * Area before (and after) super carrier * will be used for free segment descritors. */ mmap_state.desc_free_list = NULL; #ifdef ERTS_HAVE_OS_PHYSICAL_MEMORY_RESERVATION if (virtual_map && mmap_state.sa.bot - start > 0) os_reserve_physical(start, mmap_state.sa.bot - start); #endif add_free_desc_area(start, mmap_state.sa.bot); #ifdef ERTS_HAVE_OS_PHYSICAL_MEMORY_RESERVATION if (virtual_map && end - mmap_state.sua.top > 0) os_reserve_physical(mmap_state.sua.top, end - mmap_state.sua.top); #endif add_free_desc_area(mmap_state.sua.top, end); init_free_seg_map(&mmap_state.sa.map, 0); init_free_seg_map(&mmap_state.sua.map, 1); mmap_state.supercarrier = 1; erts_have_erts_mmap |= ERTS_HAVE_ERTS_SUPERCARRIER_MMAP; } #if !ERTS_HAVE_OS_MMAP mmap_state.no_os_mmap = 1; #endif } Eterm erts_mmap_info(Process* p) { if (mmap_state.supercarrier) { ERTS_DECL_AM(sabot); ERTS_DECL_AM(satop); ERTS_DECL_AM(suabot); ERTS_DECL_AM(suatop); Eterm sa_list, sua_list, list; Eterm tags[] = { AM_sabot, AM_satop, AM_suabot, AM_suatop }; UWord values[4]; Eterm *hp, *hp_end; Uint may_need; const Uint PTR_BIG_SZ = HALFWORD_HEAP ? 3 : 2; erts_smp_mtx_lock(&mmap_state.mtx); values[0] = (UWord)mmap_state.sa.bot; values[1] = (UWord)mmap_state.sa.top; values[2] = (UWord)mmap_state.sua.bot; values[3] = (UWord)mmap_state.sua.top; sa_list = build_free_seg_list(p, &mmap_state.sa.map); sua_list = build_free_seg_list(p, &mmap_state.sua.map); erts_smp_mtx_unlock(&mmap_state.mtx); may_need = 4*(2+3+PTR_BIG_SZ) + 2*(2+3); hp = HAlloc(p, may_need); hp_end = hp + may_need; list = erts_bld_atom_uint_2tup_list(&hp, NULL, sizeof(values)/sizeof(*values), tags, values); sa_list = TUPLE2(hp, am_atom_put("sa_free_segs",12), sa_list); hp+=3; sua_list = TUPLE2(hp, am_atom_put("sua_free_segs",13), sua_list); hp+=3; list = CONS(hp, sua_list, list); hp+=2; list = CONS(hp, sa_list, list); hp+=2; ASSERT(hp <= hp_end); HRelease(p, hp_end, hp); return list; } else { return am_undefined; } } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * Debug functions * \* */ #ifdef HARD_DEBUG static int rbt_assert_is_member(RBTNode* root, RBTNode* node) { while (node != root) { RBT_ASSERT(parent(node)); RBT_ASSERT(parent(node)->left == node || parent(node)->right == node); node = parent(node); } return 1; } #if 0 # define PRINT_TREE #else # undef PRINT_TREE #endif #ifdef PRINT_TREE static void print_tree(enum SortOrder order, RBTNode*); #endif /* * Checks that the order between parent and children are correct, * and that the Red-Black Tree properies are satisfied. if size > 0, * check_tree() returns the node that satisfies "address order first fit" * * The Red-Black Tree properies are: * 1. Every node is either red or black. * 2. Every leaf (NIL) is black. * 3. If a node is red, then both its children are black. * 4. Every simple path from a node to a descendant leaf * contains the same number of black nodes. * */ struct check_arg_t { RBTree* tree; ErtsFreeSegDesc* prev_seg; Uint size; RBTNode *res; }; static void check_node_callback(RBTNode* x, void* arg); static RBTNode * check_tree(RBTree* tree, Uint size) { struct check_arg_t carg; carg.tree = tree; carg.prev_seg = NULL; carg.size = size; carg.res = NULL; #ifdef PRINT_TREE print_tree(tree->order, tree->root); #endif if (!tree->root) return NULL; RBT_ASSERT(IS_BLACK(tree->root)); RBT_ASSERT(!parent(tree->root)); rbt_foreach_node(tree, check_node_callback, &carg, 0); return carg.res; } static void check_node_callback(RBTNode* x, void* arg) { struct check_arg_t* a = (struct check_arg_t*) arg; ErtsFreeSegDesc* seg; if (IS_RED(x)) { RBT_ASSERT(IS_BLACK(x->right)); RBT_ASSERT(IS_BLACK(x->left)); } RBT_ASSERT(parent(x) || x == a->tree->root); if (x->left) { RBT_ASSERT(cmp_nodes(a->tree->order, x->left, x) < 0); } if (x->right) { RBT_ASSERT(cmp_nodes(a->tree->order, x->right, x) > 0); } seg = node_to_desc(a->tree->order, x); RBT_ASSERT(seg->start < seg->end); if (a->size && (seg->end - seg->start) >= a->size) { if (!a->res || cmp_nodes(a->tree->order, x, a->res) < 0) { a->res = x; } } if (a->tree->order == ADDR_ORDER) { RBT_ASSERT(!a->prev_seg || a->prev_seg->end < seg->start); a->prev_seg = seg; } } #endif /* HARD_DEBUG */ #ifdef PRINT_TREE #define INDENT_STEP 2 #include static void print_tree_aux(enum SortOrder order, RBTNode *x, int indent) { int i; if (x) { ErtsFreeSegDesc* desc = node_to_desc(order, x); print_tree_aux(order, x->right, indent + INDENT_STEP); for (i = 0; i < indent; i++) { putc(' ', stderr); } fprintf(stderr, "%s: sz=%lx [%p - %p] desc=%p\r\n", IS_BLACK(x) ? "BLACK" : "RED", desc->end - desc->start, desc->start, desc->end, desc); print_tree_aux(order, x->left, indent + INDENT_STEP); } } static void print_tree(enum SortOrder order, RBTNode* root) { static const char* type[] = {"Address","Size-Address","Size-RevAddress"}; fprintf(stderr, " --- %s ordered tree begin ---\r\n", type[order]); print_tree_aux(order, root, 0); fprintf(stderr, " --- %s ordered tree end ---\r\n", type[order]); } #endif /* PRINT_TREE */ #ifdef FREE_SEG_API_SMOKE_TEST void test_it(void) { ErtsFreeSegMap map; ErtsFreeSegDesc *desc, *under, *over, *d1, *d2; int i; for (i=0; i<2; i++) { init_free_seg_map(&map, i); insert_free_seg(&map, alloc_desc(), (char*)0x11000, (char*)0x12000); HARD_CHECK_TREE(&map.atree, 0); HARD_CHECK_TREE(&map.stree, 0); insert_free_seg(&map, alloc_desc(), (char*)0x13000, (char*)0x14000); HARD_CHECK_TREE(&map.atree, 0); HARD_CHECK_TREE(&map.stree, 0); insert_free_seg(&map, alloc_desc(), (char*)0x15000, (char*)0x17000); HARD_CHECK_TREE(&map.atree, 0); HARD_CHECK_TREE(&map.stree, 0); insert_free_seg(&map, alloc_desc(), (char*)0x8000, (char*)0x10000); HARD_CHECK_TREE(&map.atree, 0); HARD_CHECK_TREE(&map.stree, 0); desc = lookup_free_seg(&map, 0x500); ERTS_ASSERT(desc->start == (char*)(i?0x13000L:0x11000L)); desc = lookup_free_seg(&map, 0x1500); ERTS_ASSERT(desc->start == (char*)0x15000); adjacent_free_seg(&map, (char*)0x6666, (char*)0x7777, &under, &over); ERTS_ASSERT(!under && !over); adjacent_free_seg(&map, (char*)0x6666, (char*)0x8000, &under, &over); ERTS_ASSERT(!under && over->start == (char*)0x8000); adjacent_free_seg(&map, (char*)0x10000, (char*)0x10500, &under, &over); ERTS_ASSERT(under->end == (char*)0x10000 && !over); adjacent_free_seg(&map, (char*)0x10100, (char*)0x10500, &under, &over); ERTS_ASSERT(!under && !over); adjacent_free_seg(&map, (char*)0x10100, (char*)0x11000, &under, &over); ERTS_ASSERT(!under && over && over->start == (char*)0x11000); adjacent_free_seg(&map, (char*)0x12000, (char*)0x12500, &under, &over); ERTS_ASSERT(under && under->end == (char*)0x12000 && !over); adjacent_free_seg(&map, (char*)0x12000, (char*)0x13000, &under, &over); ERTS_ASSERT(under && under->end == (char*)0x12000 && over && over->start == (char*)0x13000); adjacent_free_seg(&map, (char*)0x12500, (char*)0x13000, &under, &over); ERTS_ASSERT(!under && over && over->start == (char*)0x13000); d1 = lookup_free_seg(&map, 0x500); ERTS_ASSERT(d1->start == (char*)(i?0x13000L:0x11000L)); resize_free_seg(&map, d1, d1->start - 0x800, (char*)d1->end); HARD_CHECK_TREE(&map.atree, 0); HARD_CHECK_TREE(&map.stree, 0); d2 = lookup_free_seg(&map, 0x1200); ERTS_ASSERT(d2 == d1); delete_free_seg(&map, d1); HARD_CHECK_TREE(&map.atree, 0); HARD_CHECK_TREE(&map.stree, 0); d1 = lookup_free_seg(&map, 0x1200); ERTS_ASSERT(d1->start == (char*)0x15000); } } #endif /* FREE_SEG_API_SMOKE_TEST */