// SPDX-License-Identifier: AGPL-1.0-only // Copyright (C) 2018 Ludvig Strigeus . All Rights Reserved. #include "stdafx.h" #include "ip_to_peer_map.h" #include "bit_ops.h" #include #include IpToPeerMap::IpToPeerMap() { } IpToPeerMap::~IpToPeerMap() { } bool IpToPeerMap::InsertV4(uint32 ip, int cidr, void *peer) { ipv4_.Insert(ip, cidr, peer); return true; } bool IpToPeerMap::InsertV6(const void *addr, int cidr, void *peer) { Entry6 e; e.cidr_len = cidr; e.peer = peer; memcpy(e.ip, addr, 16); ipv6_.push_back(e); return true; } void *IpToPeerMap::LookupV4(uint32 ip) { return ipv4_.Lookup(ip); } void *IpToPeerMap::LookupV4DefaultPeer() { return ipv4_.LookupExact(0, 0); } void *IpToPeerMap::LookupV6DefaultPeer() { for (auto it = ipv6_.begin(); it != ipv6_.end(); ++it) { if (it->cidr_len == 0) return it->peer; } return NULL; } static int CalculateIPv6CommonPrefix(const uint8 *a, const uint8 *b) { uint64 x = ToBE64(*(uint64*)&a[0] ^ *(uint64*)&b[0]); uint64 y = ToBE64(*(uint64*)&a[8] ^ *(uint64*)&b[8]); return x ? 64 - FindHighestSetBit64(x) : 128 - FindHighestSetBit64(y); } void *IpToPeerMap::LookupV6(const void *addr) { int best_len = 0; void *best_peer = NULL; for (auto it = ipv6_.begin(); it != ipv6_.end(); ++it) { int len = CalculateIPv6CommonPrefix((const uint8*)addr, it->ip); if (len >= it->cidr_len && len >= best_len) { best_len = len; best_peer = it->peer; } } return best_peer; } void IpToPeerMap::RemovePeer(void *peer) { assert(0); // todo: remove peer also from ipv4_ { size_t n = ipv6_.size(); Entry6 *r = &ipv6_[0], *w = r; for (size_t i = 0; i != n; i++, r++) { if (r->peer != peer) *w++ = *r; } ipv6_.resize(w - &ipv6_[0]); } } #pragma warning (disable: 4200) // warning C4200: nonstandard extension used: zero-sized array in struct/union struct RoutingTrie32::Node { uint32 key; // bits == 0 if this is a leaf uint8 pos, bits; union { struct { Node *parent; uint32 full_children, empty_children; Node *child[0]; }; struct { Node *leaf_next; Value leaf_value; }; }; }; static inline uint32 prefix_mismatch(uint32 key, RoutingTrie32::Node *n) { uint32 prefix = n->key; return (key ^ prefix) & (prefix | (uint32)-(int32)prefix); } static uint32 make_cidr_mask(uint8 cidr) { return cidr == 0 ? 0 : 0xffffffff << (32 - cidr); } #define IS_LEAF(n) (n->bits == 0) #define GET_INDEX(k, n) ((n->key ^ k) >> n->pos) #define NODE_IS_OLEAF(n) ((intptr_t)(n) & 1) #define NODE_IS_NULL_OR_OLEAF(n) ((n) == 0 || NODE_IS_OLEAF(n)) #define VALUE_TO_OLEAF(n) ((Node*)((intptr_t)(n) + 1)) #define VALUE_FROM_OLEAF(n) ((void*)((intptr_t)(n) - 1)) static RoutingTrie32::Node *NewNode(uint32 key, int pos, int bits) { RoutingTrie32::Node *n = (RoutingTrie32::Node *)malloc(offsetof(RoutingTrie32::Node, child[(uint32)(1U << bits)])); if (n) { n->parent = NULL; n->pos = pos; n->bits = bits; n->full_children = 0; n->empty_children = 1U << bits; uint32 s = pos + bits; n->key = (s < 32) ? key >> s << s : 0; memset(n->child, 0, n->empty_children * sizeof(RoutingTrie32::Node*)); } return n; } static RoutingTrie32::Node *NewLeaf(uint32 key, uint8 leaf_pos, RoutingTrie32::Value value) { RoutingTrie32::Node *n = (RoutingTrie32::Node *)malloc(sizeof(RoutingTrie32::Node)); if (n) { n->key = key; n->bits = 0; n->pos = leaf_pos; n->leaf_value = value; n->leaf_next = NULL; } return n; } static void FreeNode(RoutingTrie32::Node *n) { free(n); } static void RecursiveFreeNode(RoutingTrie32::Node *n) { RoutingTrie32::Node *cn; if (n->bits == 0) { while ((cn = n->leaf_next) != NULL) { n->leaf_next = cn->leaf_next; FreeNode(cn); } } else { uint32 items = 1 << n->bits; for (uint32 i = 0; i != items; i++) { RoutingTrie32::Node *cn = n->child[i]; if (!NODE_IS_NULL_OR_OLEAF(cn)) RecursiveFreeNode(cn); } } FreeNode(n); } RoutingTrie32::RoutingTrie32() : root_(NULL) { } RoutingTrie32::~RoutingTrie32() { if (root_) RecursiveFreeNode(root_); } RoutingTrie32::Value RoutingTrie32::Lookup(uint32 ip) { uint32 key = ip; Node *n = root_, *pn = n, *ppn; int cindex = 0; if (!n) return NULL; // Find the longest prefix match for (;;) { uint32 index = GET_INDEX(key, n); if (index >> n->bits) break; // mismatch in skipped bits if (IS_LEAF(n)) return n->leaf_value; pn = n; cindex = index; n = n->child[index]; if (NODE_IS_NULL_OR_OLEAF(n)) { if (!n) goto backtrace; // node is an optimized leaf return VALUE_FROM_OLEAF(n); } } // backtrace for longest prefix for (;;) { if (prefix_mismatch(key, n)) goto backtrace; if (IS_LEAF(n)) { for (;;) { if (((n->key ^ key) >> n->pos) == 0) return n->leaf_value; if (n->leaf_next == NULL) { if (n->pos == 32) return n->leaf_value; break; } n = n->leaf_next; } goto backtrace; } ppn = n; n = n->child[0]; if (NODE_IS_NULL_OR_OLEAF(n)) { if (n) { if (((ppn->key ^ key) >> ppn->pos) == 0) return VALUE_FROM_OLEAF(n); } for (;;) { backtrace: // step up to previous parent when we used all bits in current while (cindex == 0) { uint32 pkey = pn->key; pn = pn->parent; if (!pn) return 0; cindex = (pn->key ^ pkey) >> pn->pos; } // strip lsb of cindex and find child cindex &= cindex - 1; assert(cindex < (1 << pn->bits)); n = pn->child[cindex]; if (!NODE_IS_NULL_OR_OLEAF(n)) break; if (n) { uint32 nkey = pn->key + (cindex << pn->pos); if (((nkey ^ key) >> pn->pos) == 0) return VALUE_FROM_OLEAF(n); } } } } } bool RoutingTrie32::InsertLeafInto(Node **nn, uint8 leaf_pos, Value value) { // put higher cidr higher up Node *n = *nn; assert(IS_LEAF(n)); uint32 key = n->key; do { if (leaf_pos < n->pos) break; if (leaf_pos == n->pos) { n->leaf_value = value; return true; } nn = &n->leaf_next; } while ((n = *nn) != NULL); Node *leaf = NewLeaf(key, leaf_pos, value); if (leaf == NULL) return false; leaf->leaf_next = *nn; *nn = leaf; return true; } static inline bool IsFull(RoutingTrie32::Node *pn, RoutingTrie32::Node *n) { return !NODE_IS_NULL_OR_OLEAF(n) && (n->pos + n->bits) == pn->pos && !IS_LEAF(n); } void RoutingTrie32::PutChild(Node *pn, uint32 i, Node *n) { Node *on = pn->child[i]; pn->child[i] = n; pn->empty_children += (n == NULL) - (on == NULL); pn->full_children += IsFull(pn, n) - IsFull(pn, on); assert(pn->empty_children < 0x80000000); assert(pn->full_children < 0x80000000); } bool RoutingTrie32::Insert(uint32 ip, int cidr, Value value) { uint32 key = ip; Node **nn = &root_, *n = root_, *pn = NULL, *leaf, *tn = NULL, *leaf_to_free = NULL; uint8 leaf_pos = 32 - cidr; if (n == NULL) { root_ = NewLeaf(key, leaf_pos, value); return (root_ != NULL); } assert(!NODE_IS_OLEAF(n)); for (;;) { uint32 index = GET_INDEX(key, n); if (index >> n->bits) { force_add: // n is a node and the key doesn't match, allocate a new node // with two elements and insert it. if (!(tn = NewNode(key, FindLastSetBit32(key ^ n->key), 1))) return false; tn->parent = pn; // can convert leaf node to oleaf? if (IS_LEAF(n)) { if (tn->pos == n->pos && n->leaf_next == NULL) { leaf_to_free = n; n = VALUE_TO_OLEAF(n->leaf_value); } } PutChild(tn, GET_INDEX(key, tn) ^ 1, n); break; } if (IS_LEAF(n)) { if (key != n->key) goto force_add; return InsertLeafInto(nn, leaf_pos, value); } pn = n; nn = &n->child[index]; if ((n = *nn) == NULL) { tn = pn; break; } if (NODE_IS_OLEAF(n)) { if (!(n = NewLeaf(pn->key + (index << pn->pos), pn->pos, VALUE_FROM_OLEAF(n)))) return false; *nn = n; } } // Create either leaf or oleaf if (tn->pos == leaf_pos) { leaf = VALUE_TO_OLEAF(value); } else if (!(leaf = NewLeaf(key, leaf_pos, value))) { if (tn != pn) FreeNode(tn); return false; } // -- Start making irreversible changes here if (leaf_to_free) FreeNode(leaf_to_free); if (tn != pn) { if (!NODE_IS_OLEAF(n) && !IS_LEAF(n)) n->parent = tn; if (pn) { PutChild(pn, GET_INDEX(key, pn), tn); } else { root_ = tn; } pn = tn; } PutChild(pn, GET_INDEX(key, pn), leaf); Rebalance(pn); return true; } bool RoutingTrie32::Delete(uint32 ip, int cidr) { uint32 key = ip; Node *n = root_, *pn = NULL; uint32 pn_index = 0; if (n == NULL) return false; uint8 leaf_pos = 32 - cidr; for (;;) { uint32 index = GET_INDEX(key, n); if (index >> n->bits) return false; if (IS_LEAF(n)) { if (n->key != key) return false; if (n->pos == leaf_pos) { if (pn == NULL) { root_ = n->leaf_next; } else { PutChild(pn, pn_index, n->leaf_next); if (n->leaf_next == NULL) Rebalance(pn); } FreeNode(n); return true; } Node **nn = &n->leaf_next; while (*nn) { if ((*nn)->pos == leaf_pos) { *nn = (*nn)->leaf_next; FreeNode(*nn); return true; } nn = &(*nn)->leaf_next; } return false; } pn = n; pn_index = index; n = n->child[index]; if (NODE_IS_NULL_OR_OLEAF(n)) { if (n && key == pn->key + (index << pn->pos) && pn->pos == leaf_pos) { PutChild(pn, index, NULL); Rebalance(pn); return true; } return false; } } } RoutingTrie32::Value RoutingTrie32::LookupExact(uint32 ip, int cidr) { uint32 key = ip; Node *n = root_, *pn; if (n == NULL) return NULL; uint8 leaf_pos = 32 - cidr; for (;;) { uint32 index = GET_INDEX(key, n); if (index >> n->bits) return NULL; if (IS_LEAF(n)) { if (n->key != key) return NULL; do { if (n->pos == leaf_pos) return n->leaf_value; n = n->leaf_next; } while (n); return NULL; } pn = n; n = n->child[index]; if (NODE_IS_NULL_OR_OLEAF(n)) return (n && key == pn->key + (index << pn->pos) && pn->pos == leaf_pos) ? n->leaf_value : NULL; } } void RoutingTrie32::Rebalance(Node *n) { // Always resize |n| and its parent. For each parent where // Resize returns true resize also its parent. Node *np = n->parent; Resize(n); while (np) { n = np; np = n->parent; if (!Resize(n)) break; } } void RoutingTrie32::ResizeChildren(Node *pn) { for (uint32 i = 0, i_end = 1U << pn->bits; i != i_end; i++) { Node *n = pn->child[i]; if (IsFull(pn, n)) Resize(n); } } enum { kHalveThreshold = 25, kInflateThreshold = 50, kHalveThresholdRoot = 15, kInflateThresholdRoot = 30, }; bool RoutingTrie32::Resize(Node *n) { assert(!IS_LEAF(n)); Node **pn = n->parent ? &n->parent->child[GET_INDEX(n->key, n->parent)] : &root_; bool did_work = false; if (n->empty_children >= (1U << n->bits) - 1) { Collapse(pn); n = *pn; if (n == NULL || IS_LEAF(n)) return true; did_work = true; } bool did_inflate = false; // Double as long as the resulting node has a number of // nonempty nodes that are above the threshold. while ((n->full_children > 0 && 50 * (n->full_children + (1U << n->bits) - n->empty_children) >= (n->parent && !(n->pos == 9) ? kInflateThreshold : kInflateThresholdRoot) * (1U << n->bits)) && n->bits < 16) { if (!Inflate(pn)) break; n = *pn; did_work = true; did_inflate = true; } // Halve as long as the number of empty children in this // node is above threshold. while (n->bits > 1 && 100 * ((1U << n->bits) - n->empty_children) < (n->parent && !(n->pos == 8) ? kHalveThreshold : kHalveThresholdRoot) * (1U << n->bits)) { assert(!did_inflate); if (!Halve(pn)) break; n = *pn; did_work = true; } if (n->empty_children >= (1U << n->bits) - 1) { Collapse(pn); n = *pn; if (n == NULL || IS_LEAF(n)) return true; did_work = true; } if (did_work) ResizeChildren(n); return did_work; } void RoutingTrie32::UpdateParent(Node *pn) { uint32 i_end = 1U << pn->bits; uint32 mask_of_halves = 0; for (uint32 i = 0; i != i_end; i++) { Node *n = pn->child[i]; if (n == NULL) continue; mask_of_halves |= (i & 1) + 1; if (NODE_IS_NULL_OR_OLEAF(n) || IS_LEAF(n)) continue; Node *op = n->parent; n->parent = pn; if (op == NULL) UpdateParent(n); } // Collapse right away if there's too many children if (pn->empty_children + 1 >= i_end) { Collapse(pn->parent ? &pn->parent->child[GET_INDEX(pn->key, pn->parent)] : &root_); return; } if (mask_of_halves != 3) { // Only one half of the entries are actually used. Perform a halving operation. Halve(pn->parent ? &pn->parent->child[GET_INDEX(pn->key, pn->parent)] : &root_); } } RoutingTrie32::Node *RoutingTrie32::ConvertOleafToLeaf(Node *pn, uint32 i, Node *n) { return NewLeaf(pn->key + (i << pn->pos), pn->pos, VALUE_FROM_OLEAF(n)); } // The |parent| and |leaf_next| pointers are repurposed to hold // the next pointer in the free list. class FreeableNodeCollector { public: FreeableNodeCollector() : ptr_(NULL) {} void Add(RoutingTrie32::Node *n) { n->leaf_next = ptr_; ptr_ = n; } void Revert(RoutingTrie32::Node *reset_parent_to); void Free(); private: RoutingTrie32::Node *ptr_; }; void FreeableNodeCollector::Revert(RoutingTrie32::Node *reset_parent_to) { for (RoutingTrie32::Node *p = ptr_, *pn; p != NULL; p = pn) { pn = p->parent; p->parent = reset_parent_to; } } void FreeableNodeCollector::Free() { for (RoutingTrie32::Node *p = ptr_, *pn; p != NULL; p = pn) { pn = p->parent; FreeNode(p); } } void RoutingTrie32::ReplaceChild(RoutingTrie32::Node **pnp, RoutingTrie32::Node *n) { RoutingTrie32::Node *pn = *pnp; if (pn->parent) RoutingTrie32::PutChild(pn->parent, (uint32)(pnp - pn->parent->child), n); else *pnp = n; } bool RoutingTrie32::Inflate(Node **pnp) { Node *pn = *pnp, *n0, *n1; FreeableNodeCollector free_on_failure, free_on_success, free_on_success_null; Node *tn = NewNode(pn->key, pn->pos - 1, pn->bits + 1); if (!tn) return false; tn->parent = pn->parent; uint8 oleaf_compare_value = tn->pos; for (uint32 i = 0, i_end = 1U << pn->bits; i != i_end; i++) { Node *n = pn->child[i]; // An empty child if (n == NULL) continue; if (NODE_IS_OLEAF(n)) { // Convert oleaf to leaf as parent's |pos| changed if (!(n = ConvertOleafToLeaf(pn, i, n))) goto nomem; free_on_failure.Add(n); goto insert_child; } if (IS_LEAF(n)) { // Check whether the leaf can be converted to an oleaf. if (n->pos == oleaf_compare_value && n->leaf_next == NULL) { free_on_success_null.Add(n); PutChild(tn, GET_INDEX(n->key, tn), VALUE_TO_OLEAF(n->leaf_value)); continue; } goto insert_child; } // A leaf or an internal node with skipped bits if ((n->pos + n->bits) != pn->pos) { insert_child: PutChild(tn, GET_INDEX(n->key, tn), n); continue; } free_on_success.Add(n); // Copying oleaf from here is ok as pos is unchanged. if (n->bits == 1) { // An internal node with exactly two children n0 = n->child[0]; n1 = n->child[1]; } else { // An internal node with more than two children if (!(n1 = NewNode(n->key | (1 << tn->pos), n->pos, n->bits - 1))) goto nomem; free_on_failure.Add(n1); if (!(n0 = NewNode(n->key, n->pos, n->bits - 1))) goto nomem; free_on_failure.Add(n0); uint32 j_end = 1U << (n->bits - 1); for (uint32 j = 0; j != j_end; j++) { PutChild(n0, j, n->child[j]); PutChild(n1, j, n->child[j + j_end]); } } PutChild(tn, 2 * i + 0, n0); PutChild(tn, 2 * i + 1, n1); } free_on_success.Free(); free_on_success_null.Free(); free_on_failure.Revert(NULL); ReplaceChild(pnp, tn); UpdateParent(tn); FreeNode(pn); return true; nomem: free_on_success.Revert(pn); free_on_success_null.Revert(NULL); free_on_failure.Free(); FreeNode(tn); return false; } bool RoutingTrie32::Halve(Node **pnp) { Node *pn = *pnp, *n; Node *tn = NewNode(pn->key, pn->pos + 1, pn->bits - 1); FreeableNodeCollector free_on_failure, free_on_success_null; if (!tn) return false; tn->parent = pn->parent; uint8 oleaf_compare_value = tn->pos; for (uint32 i = 0, i_end = 1U << pn->bits; i != i_end; i += 2) { Node *n0 = pn->child[i + 0]; Node *n1 = pn->child[i + 1]; if (n0 == NULL || n1 == NULL) { // At least one of the children is empty. n = n0 ? n0 : n1; if (NODE_IS_OLEAF(n)) { // Convert oleaf to leaf as parent's |pos| changed if (!(n = ConvertOleafToLeaf(pn, i + (n0 == NULL), n))) goto nomem; free_on_failure.Add(n); } else if (n && IS_LEAF(n) && n->pos == oleaf_compare_value && n->leaf_next == NULL) { // The leaf can be converted to an oleaf. free_on_success_null.Add(n); n = VALUE_TO_OLEAF(n->leaf_value); } } else { // Two nonempty children if (!(n = NewNode(pn->key + (i << pn->pos), pn->pos, 1))) goto nomem; free_on_failure.Add(n); PutChild(n, 0, n0); PutChild(n, 1, n1); } PutChild(tn, i / 2, n); } free_on_failure.Revert(NULL); free_on_success_null.Free(); ReplaceChild(pnp, tn); UpdateParent(tn); FreeNode(pn); return true; nomem: free_on_failure.Free(); free_on_success_null.Revert(NULL); FreeNode(tn); return false; } void RoutingTrie32::Collapse(Node **pnp) { Node *pn = *pnp, *n = NULL; if (pn->empty_children != (1U << pn->bits)) { for (uint32 i = 0; ; i++) { n = pn->child[i]; if (n) { if (NODE_IS_OLEAF(n)) { if (!(n = ConvertOleafToLeaf(pn, i, n))) return; } else if (!IS_LEAF(n)) { n->parent = pn->parent; } break; } } } ReplaceChild(pnp, n); FreeNode(pn); }