/***********************************************************************/ /* */ /* Objective Caml */ /* */ /* Xavier Leroy, projet Cristal, INRIA Rocquencourt */ /* */ /* Copyright 2001 Institut National de Recherche en Informatique et */ /* en Automatique. All rights reserved. This file is distributed */ /* under the terms of the GNU Library General Public License, with */ /* the special exception on linking described in file ../LICENSE. */ /* */ /***********************************************************************/ /* $Id$ */ /* Registration of global memory roots */ #include "memory.h" #include "misc.h" #include "mlvalues.h" #include "globroots.h" /* The set of global memory roots is represented as a skip list (see William Pugh, "Skip lists: a probabilistic alternative to balanced binary trees", Comm. ACM 33(6), 1990). */ /* Generate a random level for a new node: 0 with probability 3/4, 1 with probability 3/16, 2 with probability 3/64, etc. We use a simple linear congruential PRNG (see Knuth vol 2) instead of random(), because we need exactly 32 bits of pseudo-random data (i.e. 2 * (MAX_LEVEL + 1)). Moreover, the congruential PRNG is faster and guaranteed to be deterministic (to reproduce bugs). */ static uint32 random_seed = 0; static int random_level(void) { uint32 r; int level = 0; /* Linear congruence with modulus = 2^32, multiplier = 69069 (Knuth vol 2 p. 106, line 15 of table 1), additive = 25173. */ r = random_seed = random_seed * 69069 + 25173; /* Knuth (vol 2 p. 13) shows that the least significant bits are "less random" than the most significant bits with a modulus of 2^m, so consume most significant bits first */ while ((r & 0xC0000000U) == 0xC0000000U) { level++; r = r << 2; } Assert(level <= MAX_LEVEL); return level; } /* The initial global root list */ struct global_root_list caml_global_roots = { NULL, { NULL, }, 0 }; /* Register a global C root */ void register_global_root(value *r) { struct global_root * update[MAX_LEVEL]; struct global_root * e, * f; int i, new_level; Assert (((long) r & 3) == 0); /* compact.c demands this (for now) */ /* Init "cursor" to list head */ e = (struct global_root *) &caml_global_roots; /* Find place to insert new node */ for (i = caml_global_roots.level; i >= 0; i--) { while (1) { f = e->forward[i]; if (f == NULL || f->root >= r) break; e = f; } update[i] = e; } e = e->forward[0]; /* If already present, don't do anything */ if (e != NULL && e->root == r) return; /* Insert additional element, updating list level if necessary */ new_level = random_level(); if (new_level > caml_global_roots.level) { for (i = caml_global_roots.level + 1; i <= new_level; i++) update[i] = (struct global_root *) &caml_global_roots; caml_global_roots.level = new_level; } e = stat_alloc(sizeof(struct global_root) + new_level * sizeof(struct global_root *)); e->root = r; for (i = 0; i <= new_level; i++) { e->forward[i] = update[i]->forward[i]; update[i]->forward[i] = e; } } /* Un-register a global C root */ void remove_global_root(value *r) { struct global_root * update[MAX_LEVEL]; struct global_root * e, * f; int i; /* Init "cursor" to list head */ e = (struct global_root *) &caml_global_roots; /* Find element in list */ for (i = caml_global_roots.level; i >= 0; i--) { while (1) { f = e->forward[i]; if (f == NULL || f->root >= r) break; e = f; } update[i] = e; } e = e->forward[0]; /* If not found, nothing to do */ if (e == NULL || e->root != r) return; /* Rebuild list without node */ for (i = 0; i <= caml_global_roots.level; i++) { if (update[i]->forward[i] == e) update[i]->forward[i] = e->forward[i]; } /* Reclaim list element */ stat_free(e); /* Down-correct list level */ while (caml_global_roots.level > 0 && caml_global_roots.forward[caml_global_roots.level] == NULL) caml_global_roots.level--; }