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author | Mark Wielaard <mark@klomp.org> | 2016-08-25 23:47:19 +0200 |
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committer | Mark Wielaard <mjw@redhat.com> | 2016-08-25 23:48:05 +0200 |
commit | 9d6861b8c3edcb74faedcebb0a6960c01bb6f34d (patch) | |
tree | faf9e620c2b6e28269b087aff73eebfdcca3ffdc /misc/tsearch.c | |
parent | 7ed2b544511e8ad69ac95634388037ec264d52a7 (diff) | |
download | glibc-9d6861b8c3edcb74faedcebb0a6960c01bb6f34d.zip glibc-9d6861b8c3edcb74faedcebb0a6960c01bb6f34d.tar.gz glibc-9d6861b8c3edcb74faedcebb0a6960c01bb6f34d.tar.bz2 |
Reduce memory size of tsearch red-black tree.
A tsearch red-black tree node contains 3 pointers (key, left, right)
and 1 bit to hold the red-black flag. When allocating new nodes
this 1 bit is expanded to a full word. Causing the overhead per node
to be 3 times the key size.
We can reduce this overhead to just 2 times the key size.
malloc returns naturally aligned memory. All nodes are internally
allocated with malloc and the left/right node pointers are used
as implementation details. So we can use the low bits of the
left/right node pointers to store extra information.
Replace all direct accesses of the struct node_t node pointers and
red-black value with defines that take care of the red-black flag in
the low bit of the (left) node pointer. This reduces the size of the
nodes on 32-bit systems from 16 to 12 bytes and on 64-bit systems
from 32 to 24 bytes.
Also fix a call to CHECK_TREE so the code can be build (and tested)
with DEBUGGING defined again.
V2 changes:
- Add assert after malloc to catch any odd pointers from bad
interposed mallocs.
- Rename implementation flag to USE_MALLOC_LOW_BIT.
ChangeLog:
* misc/tsearch.c (struct node_t): Reduce to 3 pointers if
USE_MALLOC_LOW_BIT. Define pointer/value accessors.
(check_tree_recurse): Use newly defined accessors.
(check_tree): Likewise.
(maybe_split_for_insert): Likewise.
(__tfind): Likewise.
(__tdelete): Likewise.
(trecurse): Likewise.
(tdestroy_recurse): Likewise.
(__tsearch): Likewise. And add asserts for malloc alignment.
(__twalk): Cast root to node in case CHECK_TREE is defined.
Diffstat (limited to 'misc/tsearch.c')
-rw-r--r-- | misc/tsearch.c | 398 |
1 files changed, 245 insertions, 153 deletions
diff --git a/misc/tsearch.c b/misc/tsearch.c index ffb89ec..c07e606 100644 --- a/misc/tsearch.c +++ b/misc/tsearch.c @@ -83,19 +83,70 @@ In this case, A has been rotated left. This preserves the ordering of the binary tree. */ +#include <assert.h> +#include <stdalign.h> +#include <stddef.h> #include <stdlib.h> #include <string.h> #include <search.h> +/* Assume malloc returns naturally aligned (alignof (max_align_t)) + pointers so we can use the low bits to store some extra info. This + works for the left/right node pointers since they are not user + visible and always allocated by malloc. The user provides the key + pointer and so that can point anywhere and doesn't have to be + aligned. */ +#define USE_MALLOC_LOW_BIT 1 + +#ifndef USE_MALLOC_LOW_BIT +typedef struct node_t +{ + /* Callers expect this to be the first element in the structure - do not + move! */ + const void *key; + struct node_t *left_node; + struct node_t *right_node; + unsigned int is_red:1; +} *node; + +#define RED(N) (N)->is_red +#define SETRED(N) (N)->is_red = 1 +#define SETBLACK(N) (N)->is_red = 0 +#define SETNODEPTR(NP,P) (*NP) = (P) +#define LEFT(N) (N)->left_node +#define LEFTPTR(N) (&(N)->left_node) +#define SETLEFT(N,L) (N)->left_node = (L) +#define RIGHT(N) (N)->right_node +#define RIGHTPTR(N) (&(N)->right_node) +#define SETRIGHT(N,R) (N)->right_node = (R) +#define DEREFNODEPTR(NP) (*(NP)) + +#else /* USE_MALLOC_LOW_BIT */ + typedef struct node_t { /* Callers expect this to be the first element in the structure - do not move! */ const void *key; - struct node_t *left; - struct node_t *right; - unsigned int red:1; + uintptr_t left_node; /* Includes whether the node is red in low-bit. */ + uintptr_t right_node; } *node; + +#define RED(N) (node)((N)->left_node & ((uintptr_t) 0x1)) +#define SETRED(N) (N)->left_node |= ((uintptr_t) 0x1) +#define SETBLACK(N) (N)->left_node &= ~((uintptr_t) 0x1) +#define SETNODEPTR(NP,P) (*NP) = (node)((((uintptr_t)(*NP)) \ + & (uintptr_t) 0x1) | (uintptr_t)(P)) +#define LEFT(N) (node)((N)->left_node & ~((uintptr_t) 0x1)) +#define LEFTPTR(N) (node *)(&(N)->left_node) +#define SETLEFT(N,L) (N)->left_node = (((N)->left_node & (uintptr_t) 0x1) \ + | (uintptr_t)(L)) +#define RIGHT(N) (node)((N)->right_node) +#define RIGHTPTR(N) (node *)(&(N)->right_node) +#define SETRIGHT(N,R) (N)->right_node = (uintptr_t)(R) +#define DEREFNODEPTR(NP) (node)((uintptr_t)(*(NP)) & ~((uintptr_t) 0x1)) + +#endif /* USE_MALLOC_LOW_BIT */ typedef const struct node_t *const_node; #undef DEBUGGING @@ -104,8 +155,6 @@ typedef const struct node_t *const_node; /* Routines to check tree invariants. */ -#include <assert.h> - #define CHECK_TREE(a) check_tree(a) static void @@ -117,12 +166,14 @@ check_tree_recurse (node p, int d_sofar, int d_total) return; } - check_tree_recurse (p->left, d_sofar + (p->left && !p->left->red), d_total); - check_tree_recurse (p->right, d_sofar + (p->right && !p->right->red), d_total); - if (p->left) - assert (!(p->left->red && p->red)); - if (p->right) - assert (!(p->right->red && p->red)); + check_tree_recurse (LEFT(p), d_sofar + (LEFT(p) && !RED(LEFT(p))), + d_total); + check_tree_recurse (RIGHT(p), d_sofar + (RIGHT(p) && !RED(RIGHT(p))), + d_total); + if (LEFT(p)) + assert (!(RED(LEFT(p)) && RED(p))); + if (RIGHT(p)) + assert (!(RED(RIGHT(p)) && RED(p))); } static void @@ -132,13 +183,12 @@ check_tree (node root) node p; if (root == NULL) return; - root->red = 0; - for(p = root->left; p; p = p->left) - cnt += !p->red; + SETBLACK(root); + for(p = LEFT(root); p; p = LEFT(p)) + cnt += !RED(p); check_tree_recurse (root, 0, cnt); } - #else #define CHECK_TREE(a) @@ -155,28 +205,31 @@ static void maybe_split_for_insert (node *rootp, node *parentp, node *gparentp, int p_r, int gp_r, int mode) { - node root = *rootp; + node root = DEREFNODEPTR(rootp); node *rp, *lp; - rp = &(*rootp)->right; - lp = &(*rootp)->left; + node rpn, lpn; + rp = RIGHTPTR(root); + rpn = RIGHT(root); + lp = LEFTPTR(root); + lpn = LEFT(root); /* See if we have to split this node (both successors red). */ if (mode == 1 - || ((*rp) != NULL && (*lp) != NULL && (*rp)->red && (*lp)->red)) + || ((rpn) != NULL && (lpn) != NULL && RED(rpn) && RED(lpn))) { /* This node becomes red, its successors black. */ - root->red = 1; - if (*rp) - (*rp)->red = 0; - if (*lp) - (*lp)->red = 0; + SETRED(root); + if (rpn) + SETBLACK(rpn); + if (lpn) + SETBLACK(lpn); /* If the parent of this node is also red, we have to do rotations. */ - if (parentp != NULL && (*parentp)->red) + if (parentp != NULL && RED(DEREFNODEPTR(parentp))) { - node gp = *gparentp; - node p = *parentp; + node gp = DEREFNODEPTR(gparentp); + node p = DEREFNODEPTR(parentp); /* There are two main cases: 1. The edge types (left or right) of the two red edges differ. 2. Both red edges are of the same type. @@ -186,45 +239,45 @@ maybe_split_for_insert (node *rootp, node *parentp, node *gparentp, { /* Put the child at the top of the tree, with its parent and grandparent as successors. */ - p->red = 1; - gp->red = 1; - root->red = 0; + SETRED(p); + SETRED(gp); + SETBLACK(root); if (p_r < 0) { /* Child is left of parent. */ - p->left = *rp; - *rp = p; - gp->right = *lp; - *lp = gp; + SETLEFT(p,rpn); + SETNODEPTR(rp,p); + SETRIGHT(gp,lpn); + SETNODEPTR(lp,gp); } else { /* Child is right of parent. */ - p->right = *lp; - *lp = p; - gp->left = *rp; - *rp = gp; + SETRIGHT(p,lpn); + SETNODEPTR(lp,p); + SETLEFT(gp,rpn); + SETNODEPTR(rp,gp); } - *gparentp = root; + SETNODEPTR(gparentp,root); } else { - *gparentp = *parentp; + SETNODEPTR(gparentp,p); /* Parent becomes the top of the tree, grandparent and child are its successors. */ - p->red = 0; - gp->red = 1; + SETBLACK(p); + SETRED(gp); if (p_r < 0) { /* Left edges. */ - gp->left = p->right; - p->right = gp; + SETLEFT(gp,RIGHT(p)); + SETRIGHT(p,gp); } else { /* Right edges. */ - gp->right = p->left; - p->left = gp; + SETRIGHT(gp,LEFT(p)); + SETLEFT(p,gp); } } } @@ -237,25 +290,30 @@ maybe_split_for_insert (node *rootp, node *parentp, node *gparentp, void * __tsearch (const void *key, void **vrootp, __compar_fn_t compar) { - node q; + node q, root; node *parentp = NULL, *gparentp = NULL; node *rootp = (node *) vrootp; node *nextp; int r = 0, p_r = 0, gp_r = 0; /* No they might not, Mr Compiler. */ +#ifdef USE_MALLOC_LOW_BIT + static_assert (alignof (max_align_t) > 1, "malloc must return aligned ptrs"); +#endif + if (rootp == NULL) return NULL; /* This saves some additional tests below. */ - if (*rootp != NULL) - (*rootp)->red = 0; + root = DEREFNODEPTR(rootp); + if (root != NULL) + SETBLACK(root); - CHECK_TREE (*rootp); + CHECK_TREE (root); nextp = rootp; - while (*nextp != NULL) + while (DEREFNODEPTR(nextp) != NULL) { - node root = *rootp; + root = DEREFNODEPTR(rootp); r = (*compar) (key, root->key); if (r == 0) return root; @@ -265,8 +323,8 @@ __tsearch (const void *key, void **vrootp, __compar_fn_t compar) That doesn't matter, because the values they contain are never used again in that case. */ - nextp = r < 0 ? &root->left : &root->right; - if (*nextp == NULL) + nextp = r < 0 ? LEFTPTR(root) : RIGHTPTR(root); + if (DEREFNODEPTR(nextp) == NULL) break; gparentp = parentp; @@ -280,10 +338,20 @@ __tsearch (const void *key, void **vrootp, __compar_fn_t compar) q = (struct node_t *) malloc (sizeof (struct node_t)); if (q != NULL) { - *nextp = q; /* link new node to old */ + /* Make sure the malloc implementation returns naturally aligned + memory blocks when expected. Or at least even pointers, so we + can use the low bit as red/black flag. Even though we have a + static_assert to make sure alignof (max_align_t) > 1 there could + be an interposed malloc implementation that might cause havoc by + not obeying the malloc contract. */ +#ifdef USE_MALLOC_LOW_BIT + assert (((uintptr_t) q & (uintptr_t) 0x1) == 0); +#endif + SETNODEPTR(nextp,q); /* link new node to old */ q->key = key; /* initialize new node */ - q->red = 1; - q->left = q->right = NULL; + SETRED(q); + SETLEFT(q,NULL); + SETRIGHT(q,NULL); if (nextp != rootp) /* There may be two red edges in a row now, which we must avoid by @@ -303,23 +371,25 @@ weak_alias (__tsearch, tsearch) void * __tfind (const void *key, void *const *vrootp, __compar_fn_t compar) { + node root; node *rootp = (node *) vrootp; if (rootp == NULL) return NULL; - CHECK_TREE (*rootp); + root = DEREFNODEPTR(rootp); + CHECK_TREE (root); - while (*rootp != NULL) + while (DEREFNODEPTR(rootp) != NULL) { - node root = *rootp; + root = DEREFNODEPTR(rootp); int r; r = (*compar) (key, root->key); if (r == 0) return root; - rootp = r < 0 ? &root->left : &root->right; + rootp = r < 0 ? LEFTPTR(root) : RIGHTPTR(root); } return NULL; } @@ -346,13 +416,14 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) if (rootp == NULL) return NULL; - p = *rootp; + p = DEREFNODEPTR(rootp); if (p == NULL) return NULL; CHECK_TREE (p); - while ((cmp = (*compar) (key, (*rootp)->key)) != 0) + root = DEREFNODEPTR(rootp); + while ((cmp = (*compar) (key, root->key)) != 0) { if (sp == stacksize) { @@ -363,11 +434,18 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) } nodestack[sp++] = rootp; - p = *rootp; - rootp = ((cmp < 0) - ? &(*rootp)->left - : &(*rootp)->right); - if (*rootp == NULL) + p = DEREFNODEPTR(rootp); + if (cmp < 0) + { + rootp = LEFTPTR(p); + root = LEFT(p); + } + else + { + rootp = RIGHTPTR(p); + root = RIGHT(p); + } + if (root == NULL) return NULL; } @@ -380,16 +458,17 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) it with its successor and unchain the successor. If there is no successor, we really unchain the node to be deleted. */ - root = *rootp; + root = DEREFNODEPTR(rootp); - r = root->right; - q = root->left; + r = RIGHT(root); + q = LEFT(root); if (q == NULL || r == NULL) unchained = root; else { - node *parent = rootp, *up = &root->right; + node *parentp = rootp, *up = RIGHTPTR(root); + node upn; for (;;) { if (sp == stacksize) @@ -399,34 +478,35 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) newstack = alloca (sizeof (node *) * stacksize); nodestack = memcpy (newstack, nodestack, sp * sizeof (node *)); } - nodestack[sp++] = parent; - parent = up; - if ((*up)->left == NULL) + nodestack[sp++] = parentp; + parentp = up; + upn = DEREFNODEPTR(up); + if (LEFT(upn) == NULL) break; - up = &(*up)->left; + up = LEFTPTR(upn); } - unchained = *up; + unchained = DEREFNODEPTR(up); } /* We know that either the left or right successor of UNCHAINED is NULL. R becomes the other one, it is chained into the parent of UNCHAINED. */ - r = unchained->left; + r = LEFT(unchained); if (r == NULL) - r = unchained->right; + r = RIGHT(unchained); if (sp == 0) - *rootp = r; + SETNODEPTR(rootp,r); else { - q = *nodestack[sp-1]; - if (unchained == q->right) - q->right = r; + q = DEREFNODEPTR(nodestack[sp-1]); + if (unchained == RIGHT(q)) + SETRIGHT(q,r); else - q->left = r; + SETLEFT(q,r); } if (unchained != root) root->key = unchained->key; - if (!unchained->red) + if (!RED(unchained)) { /* Now we lost a black edge, which means that the number of black edges on every path is no longer constant. We must balance the @@ -435,17 +515,17 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) in the first iteration. */ /* NULL nodes are considered black throughout - this is necessary for correctness. */ - while (sp > 0 && (r == NULL || !r->red)) + while (sp > 0 && (r == NULL || !RED(r))) { node *pp = nodestack[sp - 1]; - p = *pp; + p = DEREFNODEPTR(pp); /* Two symmetric cases. */ - if (r == p->left) + if (r == LEFT(p)) { /* Q is R's brother, P is R's parent. The subtree with root R has one black edge less than the subtree with root Q. */ - q = p->right; - if (q->red) + q = RIGHT(p); + if (RED(q)) { /* If Q is red, we know that P is black. We rotate P left so that Q becomes the top node in the tree, with P below @@ -454,21 +534,21 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) leaf in the tree, but we will be able to recognize one of the following situations, which all require that Q is black. */ - q->red = 0; - p->red = 1; + SETBLACK(q); + SETRED(p); /* Left rotate p. */ - p->right = q->left; - q->left = p; - *pp = q; + SETRIGHT(p,LEFT(q)); + SETLEFT(q,p); + SETNODEPTR(pp,q); /* Make sure pp is right if the case below tries to use it. */ - nodestack[sp++] = pp = &q->left; - q = p->right; + nodestack[sp++] = pp = LEFTPTR(q); + q = RIGHT(p); } /* We know that Q can't be NULL here. We also know that Q is black. */ - if ((q->left == NULL || !q->left->red) - && (q->right == NULL || !q->right->red)) + if ((LEFT(q) == NULL || !RED(LEFT(q))) + && (RIGHT(q) == NULL || !RED(RIGHT(q)))) { /* Q has two black successors. We can simply color Q red. The whole subtree with root P is now missing one black @@ -478,7 +558,7 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) valid and also makes the black edge count come out right. If P is black, we are at least one step closer to the root and we'll try again the next iteration. */ - q->red = 1; + SETRED(q); r = p; } else @@ -486,7 +566,7 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) /* Q is black, one of Q's successors is red. We can repair the tree with one operation and will exit the loop afterwards. */ - if (q->right == NULL || !q->right->red) + if (RIGHT(q) == NULL || !RED(RIGHT(q))) { /* The left one is red. We perform the same action as in maybe_split_for_insert where two red edges are @@ -498,14 +578,17 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) P becomes black, and Q2 gets the color that P had. This changes the black edge count only for node R and its successors. */ - node q2 = q->left; - q2->red = p->red; - p->right = q2->left; - q->left = q2->right; - q2->right = q; - q2->left = p; - *pp = q2; - p->red = 0; + node q2 = LEFT(q); + if (RED(p)) + SETRED(q2); + else + SETBLACK(q2); + SETRIGHT(p,LEFT(q2)); + SETLEFT(q,RIGHT(q2)); + SETRIGHT(q2,q); + SETLEFT(q2,p); + SETNODEPTR(pp,q2); + SETBLACK(p); } else { @@ -513,15 +596,18 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) and Q gets the color that P had. Q's right successor also becomes black. This changes the black edge count only for node R and its successors. */ - q->red = p->red; - p->red = 0; + if (RED(p)) + SETRED(q); + else + SETBLACK(q); + SETBLACK(p); - q->right->red = 0; + SETBLACK(RIGHT(q)); /* left rotate p */ - p->right = q->left; - q->left = p; - *pp = q; + SETRIGHT(p,LEFT(q)); + SETLEFT(q,p); + SETNODEPTR(pp,q); } /* We're done. */ @@ -532,44 +618,50 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) else { /* Comments: see above. */ - q = p->left; - if (q->red) + q = LEFT(p); + if (RED(q)) { - q->red = 0; - p->red = 1; - p->left = q->right; - q->right = p; - *pp = q; - nodestack[sp++] = pp = &q->right; - q = p->left; + SETBLACK(q); + SETRED(p); + SETLEFT(p,RIGHT(q)); + SETRIGHT(q,p); + SETNODEPTR(pp,q); + nodestack[sp++] = pp = RIGHTPTR(q); + q = LEFT(p); } - if ((q->right == NULL || !q->right->red) - && (q->left == NULL || !q->left->red)) + if ((RIGHT(q) == NULL || !RED(RIGHT(q))) + && (LEFT(q) == NULL || !RED(LEFT(q)))) { - q->red = 1; + SETRED(q); r = p; } else { - if (q->left == NULL || !q->left->red) + if (LEFT(q) == NULL || !RED(LEFT(q))) { - node q2 = q->right; - q2->red = p->red; - p->left = q2->right; - q->right = q2->left; - q2->left = q; - q2->right = p; - *pp = q2; - p->red = 0; + node q2 = RIGHT(q); + if (RED(p)) + SETRED(q2); + else + SETBLACK(q2); + SETLEFT(p,RIGHT(q2)); + SETRIGHT(q,LEFT(q2)); + SETLEFT(q2,q); + SETRIGHT(q2,p); + SETNODEPTR(pp,q2); + SETBLACK(p); } else { - q->red = p->red; - p->red = 0; - q->left->red = 0; - p->left = q->right; - q->right = p; - *pp = q; + if (RED(p)) + SETRED(q); + else + SETBLACK(q); + SETBLACK(p); + SETBLACK(LEFT(q)); + SETLEFT(p,RIGHT(q)); + SETRIGHT(q,p); + SETNODEPTR(pp,q); } sp = 1; r = NULL; @@ -578,7 +670,7 @@ __tdelete (const void *key, void **vrootp, __compar_fn_t compar) --sp; } if (r != NULL) - r->red = 0; + SETBLACK(r); } free (unchained); @@ -597,16 +689,16 @@ trecurse (const void *vroot, __action_fn_t action, int level) { const_node root = (const_node) vroot; - if (root->left == NULL && root->right == NULL) + if (LEFT(root) == NULL && RIGHT(root) == NULL) (*action) (root, leaf, level); else { (*action) (root, preorder, level); - if (root->left != NULL) - trecurse (root->left, action, level + 1); + if (LEFT(root) != NULL) + trecurse (LEFT(root), action, level + 1); (*action) (root, postorder, level); - if (root->right != NULL) - trecurse (root->right, action, level + 1); + if (RIGHT(root) != NULL) + trecurse (RIGHT(root), action, level + 1); (*action) (root, endorder, level); } } @@ -620,7 +712,7 @@ __twalk (const void *vroot, __action_fn_t action) { const_node root = (const_node) vroot; - CHECK_TREE (root); + CHECK_TREE ((node) root); if (root != NULL && action != NULL) trecurse (root, action, 0); @@ -636,10 +728,10 @@ static void internal_function tdestroy_recurse (node root, __free_fn_t freefct) { - if (root->left != NULL) - tdestroy_recurse (root->left, freefct); - if (root->right != NULL) - tdestroy_recurse (root->right, freefct); + if (LEFT(root) != NULL) + tdestroy_recurse (LEFT(root), freefct); + if (RIGHT(root) != NULL) + tdestroy_recurse (RIGHT(root), freefct); (*freefct) ((void *) root->key); /* Free the node itself. */ free (root); |