/*------------------------------------------------------------------------- * * integerset.c * Data structure to hold a large set of 64-bit integers efficiently * * IntegerSet provides an in-memory data structure to hold a set of * arbitrary 64-bit integers. Internally, the values are stored in a * B-tree, with a special packed representation at the leaf level using * the Simple-8b algorithm, which can pack clusters of nearby values * very tightly. * * Memory consumption depends on the number of values stored, but also * on how far the values are from each other. In the best case, with * long runs of consecutive integers, memory consumption can be as low as * 0.1 bytes per integer. In the worst case, if integers are more than * 2^32 apart, it uses about 8 bytes per integer. In typical use, the * consumption per integer is somewhere between those extremes, depending * on the range of integers stored, and how "clustered" they are. * * * Interface * --------- * * intset_create - Create a new, empty set * intset_add_member - Add an integer to the set * intset_is_member - Test if an integer is in the set * intset_begin_iterate - Begin iterating through all integers in set * intset_iterate_next - Return next set member, if any * * intset_create() creates the set in the current memory context. Subsequent * operations that add to the data structure will continue to allocate from * that same context, even if it's not current anymore. * * Note that there is no function to free an integer set. If you need to do * that, create a dedicated memory context to hold it, and destroy the memory * context instead. * * * Limitations * ----------- * * - Values must be added in order. (Random insertions would require * splitting nodes, which hasn't been implemented.) * * - Values cannot be added while iteration is in progress. * * - No support for removing values. * * None of these limitations are fundamental to the data structure, so they * could be lifted if needed, by writing some new code. But the current * users of this facility don't need them. * * * References * ---------- * * Simple-8b encoding is based on: * * Vo Ngoc Anh, Alistair Moffat, Index compression using 64-bit words, * Software - Practice & Experience, v.40 n.2, p.131-147, February 2010 * (https://doi.org/10.1002/spe.948) * * * Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * IDENTIFICATION * src/backend/lib/integerset.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include "access/htup_details.h" #include "lib/integerset.h" #include "port/pg_bitutils.h" #include "utils/memutils.h" /* * Maximum number of integers that can be encoded in a single Simple-8b * codeword. (Defined here before anything else, so that we can size arrays * using this.) */ #define SIMPLE8B_MAX_VALUES_PER_CODEWORD 240 /* * Parameters for shape of the in-memory B-tree. * * These set the size of each internal and leaf node. They don't necessarily * need to be the same, because the tree is just an in-memory structure. * With the default 64, each node is about 1 kb. * * If you change these, you must recalculate MAX_TREE_LEVELS, too! */ #define MAX_INTERNAL_ITEMS 64 #define MAX_LEAF_ITEMS 64 /* * Maximum height of the tree. * * MAX_TREE_ITEMS is calculated from the "fan-out" of the B-tree. The * theoretical maximum number of items that we can store in a set is 2^64, * so MAX_TREE_LEVELS should be set so that: * * MAX_LEAF_ITEMS * MAX_INTERNAL_ITEMS ^ (MAX_TREE_LEVELS - 1) >= 2^64. * * In practice, we'll need far fewer levels, because you will run out of * memory long before reaching that number, but let's be conservative. */ #define MAX_TREE_LEVELS 11 /* * Node structures, for the in-memory B-tree. * * An internal node holds a number of downlink pointers to leaf nodes, or * to internal nodes on a lower level. For each downlink, the key value * corresponding to the lower level node is stored in a sorted array. The * stored key values are low keys. In other words, if the downlink has value * X, then all items stored on that child are >= X. * * Each leaf node holds a number of "items", with a varying number of * integers packed into each item. Each item consists of two 64-bit words: * The first word holds the first integer stored in the item, in plain format. * The second word contains between 0 and 240 more integers, packed using * Simple-8b encoding. By storing the first integer in plain, unpacked, * format, we can use binary search to quickly find an item that holds (or * would hold) a particular integer. And by storing the rest in packed form, * we still get pretty good memory density, if there are clusters of integers * with similar values. * * Each leaf node also has a pointer to the next leaf node, so that the leaf * nodes can be easily walked from beginning to end when iterating. */ typedef struct intset_node intset_node; typedef struct intset_leaf_node intset_leaf_node; typedef struct intset_internal_node intset_internal_node; /* Common structure of both leaf and internal nodes. */ struct intset_node { uint16 level; /* tree level of this node */ uint16 num_items; /* number of items in this node */ }; /* Internal node */ struct intset_internal_node { /* common header, must match intset_node */ uint16 level; /* >= 1 on internal nodes */ uint16 num_items; /* * 'values' is an array of key values, and 'downlinks' are pointers to * lower-level nodes, corresponding to the key values. */ uint64 values[MAX_INTERNAL_ITEMS]; intset_node *downlinks[MAX_INTERNAL_ITEMS]; }; /* Leaf node */ typedef struct { uint64 first; /* first integer in this item */ uint64 codeword; /* simple8b encoded differences from 'first' */ } leaf_item; #define MAX_VALUES_PER_LEAF_ITEM (1 + SIMPLE8B_MAX_VALUES_PER_CODEWORD) struct intset_leaf_node { /* common header, must match intset_node */ uint16 level; /* 0 on leafs */ uint16 num_items; intset_leaf_node *next; /* right sibling, if any */ leaf_item items[MAX_LEAF_ITEMS]; }; /* * We buffer insertions in a simple array, before packing and inserting them * into the B-tree. MAX_BUFFERED_VALUES sets the size of the buffer. The * encoder assumes that it is large enough that we can always fill a leaf * item with buffered new items. In other words, MAX_BUFFERED_VALUES must be * larger than MAX_VALUES_PER_LEAF_ITEM. For efficiency, make it much larger. */ #define MAX_BUFFERED_VALUES (MAX_VALUES_PER_LEAF_ITEM * 2) /* * IntegerSet is the top-level object representing the set. * * The integers are stored in an in-memory B-tree structure, plus an array * for newly-added integers. IntegerSet also tracks information about memory * usage, as well as the current position when iterating the set with * intset_begin_iterate / intset_iterate_next. */ struct IntegerSet { /* * 'context' is the memory context holding this integer set and all its * tree nodes. * * 'mem_used' tracks the amount of memory used. We don't do anything with * it in integerset.c itself, but the callers can ask for it with * intset_memory_usage(). */ MemoryContext context; uint64 mem_used; uint64 num_entries; /* total # of values in the set */ uint64 highest_value; /* highest value stored in this set */ /* * B-tree to hold the packed values. * * 'rightmost_nodes' hold pointers to the rightmost node on each level. * rightmost_parent[0] is rightmost leaf, rightmost_parent[1] is its * parent, and so forth, all the way up to the root. These are needed when * adding new values. (Currently, we require that new values are added at * the end.) */ int num_levels; /* height of the tree */ intset_node *root; /* root node */ intset_node *rightmost_nodes[MAX_TREE_LEVELS]; intset_leaf_node *leftmost_leaf; /* leftmost leaf node */ /* * Holding area for new items that haven't been inserted to the tree yet. */ uint64 buffered_values[MAX_BUFFERED_VALUES]; int num_buffered_values; /* * Iterator support. * * 'iter_values' is an array of integers ready to be returned to the * caller; 'iter_num_values' is the length of that array, and * 'iter_valueno' is the next index. 'iter_node' and 'iter_itemno' point * to the leaf node, and item within the leaf node, to get the next batch * of values from. * * Normally, 'iter_values' points to 'iter_values_buf', which holds items * decoded from a leaf item. But after we have scanned the whole B-tree, * we iterate through all the unbuffered values, too, by pointing * iter_values to 'buffered_values'. */ bool iter_active; /* is iteration in progress? */ const uint64 *iter_values; int iter_num_values; /* number of elements in 'iter_values' */ int iter_valueno; /* next index into 'iter_values' */ intset_leaf_node *iter_node; /* current leaf node */ int iter_itemno; /* next item in 'iter_node' to decode */ uint64 iter_values_buf[MAX_VALUES_PER_LEAF_ITEM]; }; /* * Prototypes for internal functions. */ static void intset_update_upper(IntegerSet *intset, int level, intset_node *child, uint64 child_key); static void intset_flush_buffered_values(IntegerSet *intset); static int intset_binsrch_uint64(uint64 item, uint64 *arr, int arr_elems, bool nextkey); static int intset_binsrch_leaf(uint64 item, leaf_item *arr, int arr_elems, bool nextkey); static uint64 simple8b_encode(const uint64 *ints, int *num_encoded, uint64 base); static int simple8b_decode(uint64 codeword, uint64 *decoded, uint64 base); static bool simple8b_contains(uint64 codeword, uint64 key, uint64 base); /* * Create a new, initially empty, integer set. * * The integer set is created in the current memory context. * We will do all subsequent allocations in the same context, too, regardless * of which memory context is current when new integers are added to the set. */ IntegerSet * intset_create(void) { IntegerSet *intset; intset = (IntegerSet *) palloc(sizeof(IntegerSet)); intset->context = CurrentMemoryContext; intset->mem_used = GetMemoryChunkSpace(intset); intset->num_entries = 0; intset->highest_value = 0; intset->num_levels = 0; intset->root = NULL; memset(intset->rightmost_nodes, 0, sizeof(intset->rightmost_nodes)); intset->leftmost_leaf = NULL; intset->num_buffered_values = 0; intset->iter_active = false; intset->iter_node = NULL; intset->iter_itemno = 0; intset->iter_valueno = 0; intset->iter_num_values = 0; intset->iter_values = NULL; return intset; } /* * Allocate a new node. */ static intset_internal_node * intset_new_internal_node(IntegerSet *intset) { intset_internal_node *n; n = (intset_internal_node *) MemoryContextAlloc(intset->context, sizeof(intset_internal_node)); intset->mem_used += GetMemoryChunkSpace(n); n->level = 0; /* caller must set */ n->num_items = 0; return n; } static intset_leaf_node * intset_new_leaf_node(IntegerSet *intset) { intset_leaf_node *n; n = (intset_leaf_node *) MemoryContextAlloc(intset->context, sizeof(intset_leaf_node)); intset->mem_used += GetMemoryChunkSpace(n); n->level = 0; n->num_items = 0; n->next = NULL; return n; } /* * Return the number of entries in the integer set. */ uint64 intset_num_entries(IntegerSet *intset) { return intset->num_entries; } /* * Return the amount of memory used by the integer set. */ uint64 intset_memory_usage(IntegerSet *intset) { return intset->mem_used; } /* * Add a value to the set. * * Values must be added in order. */ void intset_add_member(IntegerSet *intset, uint64 x) { if (intset->iter_active) elog(ERROR, "cannot add new values to integer set while iteration is in progress"); if (x <= intset->highest_value && intset->num_entries > 0) elog(ERROR, "cannot add value to integer set out of order"); if (intset->num_buffered_values >= MAX_BUFFERED_VALUES) { /* Time to flush our buffer */ intset_flush_buffered_values(intset); Assert(intset->num_buffered_values < MAX_BUFFERED_VALUES); } /* Add it to the buffer of newly-added values */ intset->buffered_values[intset->num_buffered_values] = x; intset->num_buffered_values++; intset->num_entries++; intset->highest_value = x; } /* * Take a batch of buffered values, and pack them into the B-tree. */ static void intset_flush_buffered_values(IntegerSet *intset) { uint64 *values = intset->buffered_values; uint64 num_values = intset->num_buffered_values; int num_packed = 0; intset_leaf_node *leaf; leaf = (intset_leaf_node *) intset->rightmost_nodes[0]; /* * If the tree is completely empty, create the first leaf page, which is * also the root. */ if (leaf == NULL) { /* * This is the very first item in the set. * * Allocate root node. It's also a leaf. */ leaf = intset_new_leaf_node(intset); intset->root = (intset_node *) leaf; intset->leftmost_leaf = leaf; intset->rightmost_nodes[0] = (intset_node *) leaf; intset->num_levels = 1; } /* * If there are less than MAX_VALUES_PER_LEAF_ITEM values in the buffer, * stop. In most cases, we cannot encode that many values in a single * value, but this way, the encoder doesn't have to worry about running * out of input. */ while (num_values - num_packed >= MAX_VALUES_PER_LEAF_ITEM) { leaf_item item; int num_encoded; /* * Construct the next leaf item, packing as many buffered values as * possible. */ item.first = values[num_packed]; item.codeword = simple8b_encode(&values[num_packed + 1], &num_encoded, item.first); /* * Add the item to the node, allocating a new node if the old one is * full. */ if (leaf->num_items >= MAX_LEAF_ITEMS) { /* Allocate new leaf and link it to the tree */ intset_leaf_node *old_leaf = leaf; leaf = intset_new_leaf_node(intset); old_leaf->next = leaf; intset->rightmost_nodes[0] = (intset_node *) leaf; intset_update_upper(intset, 1, (intset_node *) leaf, item.first); } leaf->items[leaf->num_items++] = item; num_packed += 1 + num_encoded; } /* * Move any remaining buffered values to the beginning of the array. */ if (num_packed < intset->num_buffered_values) { memmove(&intset->buffered_values[0], &intset->buffered_values[num_packed], (intset->num_buffered_values - num_packed) * sizeof(uint64)); } intset->num_buffered_values -= num_packed; } /* * Insert a downlink into parent node, after creating a new node. * * Recurses if the parent node is full, too. */ static void intset_update_upper(IntegerSet *intset, int level, intset_node *child, uint64 child_key) { intset_internal_node *parent; Assert(level > 0); /* * Create a new root node, if necessary. */ if (level >= intset->num_levels) { intset_node *oldroot = intset->root; uint64 downlink_key; /* MAX_TREE_LEVELS should be more than enough, this shouldn't happen */ if (intset->num_levels == MAX_TREE_LEVELS) elog(ERROR, "could not expand integer set, maximum number of levels reached"); intset->num_levels++; /* * Get the first value on the old root page, to be used as the * downlink. */ if (intset->root->level == 0) downlink_key = ((intset_leaf_node *) oldroot)->items[0].first; else downlink_key = ((intset_internal_node *) oldroot)->values[0]; parent = intset_new_internal_node(intset); parent->level = level; parent->values[0] = downlink_key; parent->downlinks[0] = oldroot; parent->num_items = 1; intset->root = (intset_node *) parent; intset->rightmost_nodes[level] = (intset_node *) parent; } /* * Place the downlink on the parent page. */ parent = (intset_internal_node *) intset->rightmost_nodes[level]; if (parent->num_items < MAX_INTERNAL_ITEMS) { parent->values[parent->num_items] = child_key; parent->downlinks[parent->num_items] = child; parent->num_items++; } else { /* * Doesn't fit. Allocate new parent, with the downlink as the first * item on it, and recursively insert the downlink to the new parent * to the grandparent. */ parent = intset_new_internal_node(intset); parent->level = level; parent->values[0] = child_key; parent->downlinks[0] = child; parent->num_items = 1; intset->rightmost_nodes[level] = (intset_node *) parent; intset_update_upper(intset, level + 1, (intset_node *) parent, child_key); } } /* * Does the set contain the given value? */ bool intset_is_member(IntegerSet *intset, uint64 x) { intset_node *node; intset_leaf_node *leaf; int level; int itemno; leaf_item *item; /* * The value might be in the buffer of newly-added values. */ if (intset->num_buffered_values > 0 && x >= intset->buffered_values[0]) { itemno = intset_binsrch_uint64(x, intset->buffered_values, intset->num_buffered_values, false); if (itemno >= intset->num_buffered_values) return false; else return (intset->buffered_values[itemno] == x); } /* * Start from the root, and walk down the B-tree to find the right leaf * node. */ if (!intset->root) return false; node = intset->root; for (level = intset->num_levels - 1; level > 0; level--) { intset_internal_node *n = (intset_internal_node *) node; Assert(node->level == level); itemno = intset_binsrch_uint64(x, n->values, n->num_items, true); if (itemno == 0) return false; node = n->downlinks[itemno - 1]; } Assert(node->level == 0); leaf = (intset_leaf_node *) node; /* * Binary search to find the right item on the leaf page */ itemno = intset_binsrch_leaf(x, leaf->items, leaf->num_items, true); if (itemno == 0) return false; item = &leaf->items[itemno - 1]; /* Is this a match to the first value on the item? */ if (item->first == x) return true; Assert(x > item->first); /* Is it in the packed codeword? */ if (simple8b_contains(item->codeword, x, item->first)) return true; return false; } /* * Begin in-order scan through all the values. * * While the iteration is in-progress, you cannot add new values to the set. */ void intset_begin_iterate(IntegerSet *intset) { /* Note that we allow an iteration to be abandoned midway */ intset->iter_active = true; intset->iter_node = intset->leftmost_leaf; intset->iter_itemno = 0; intset->iter_valueno = 0; intset->iter_num_values = 0; intset->iter_values = intset->iter_values_buf; } /* * Returns the next integer, when iterating. * * intset_begin_iterate() must be called first. intset_iterate_next() returns * the next value in the set. Returns true, if there was another value, and * stores the value in *next. Otherwise, returns false. */ bool intset_iterate_next(IntegerSet *intset, uint64 *next) { Assert(intset->iter_active); for (;;) { /* Return next iter_values[] entry if any */ if (intset->iter_valueno < intset->iter_num_values) { *next = intset->iter_values[intset->iter_valueno++]; return true; } /* Decode next item in current leaf node, if any */ if (intset->iter_node && intset->iter_itemno < intset->iter_node->num_items) { leaf_item *item; int num_decoded; item = &intset->iter_node->items[intset->iter_itemno++]; intset->iter_values_buf[0] = item->first; num_decoded = simple8b_decode(item->codeword, &intset->iter_values_buf[1], item->first); intset->iter_num_values = num_decoded + 1; intset->iter_valueno = 0; continue; } /* No more items on this leaf, step to next node */ if (intset->iter_node) { intset->iter_node = intset->iter_node->next; intset->iter_itemno = 0; continue; } /* * We have reached the end of the B-tree. But we might still have * some integers in the buffer of newly-added values. */ if (intset->iter_values == (const uint64 *) intset->iter_values_buf) { intset->iter_values = intset->buffered_values; intset->iter_num_values = intset->num_buffered_values; intset->iter_valueno = 0; continue; } break; } /* No more results. */ intset->iter_active = false; *next = 0; /* prevent uninitialized-variable warnings */ return false; } /* * intset_binsrch_uint64() -- search a sorted array of uint64s * * Returns the first position with key equal or less than the given key. * The returned position would be the "insert" location for the given key, * that is, the position where the new key should be inserted to. * * 'nextkey' affects the behavior on equal keys. If true, and there is an * equal key in the array, this returns the position immediately after the * equal key. If false, this returns the position of the equal key itself. */ static int intset_binsrch_uint64(uint64 item, uint64 *arr, int arr_elems, bool nextkey) { int low, high, mid; low = 0; high = arr_elems; while (high > low) { mid = low + (high - low) / 2; if (nextkey) { if (item >= arr[mid]) low = mid + 1; else high = mid; } else { if (item > arr[mid]) low = mid + 1; else high = mid; } } return low; } /* same, but for an array of leaf items */ static int intset_binsrch_leaf(uint64 item, leaf_item *arr, int arr_elems, bool nextkey) { int low, high, mid; low = 0; high = arr_elems; while (high > low) { mid = low + (high - low) / 2; if (nextkey) { if (item >= arr[mid].first) low = mid + 1; else high = mid; } else { if (item > arr[mid].first) low = mid + 1; else high = mid; } } return low; } /* * Simple-8b encoding. * * The simple-8b algorithm packs between 1 and 240 integers into 64-bit words, * called "codewords". The number of integers packed into a single codeword * depends on the integers being packed; small integers are encoded using * fewer bits than large integers. A single codeword can store a single * 60-bit integer, or two 30-bit integers, for example. * * Since we're storing a unique, sorted, set of integers, we actually encode * the *differences* between consecutive integers. That way, clusters of * integers that are close to each other are packed efficiently, regardless * of their absolute values. * * In Simple-8b, each codeword consists of a 4-bit selector, which indicates * how many integers are encoded in the codeword, and the encoded integers are * packed into the remaining 60 bits. The selector allows for 16 different * ways of using the remaining 60 bits, called "modes". The number of integers * packed into a single codeword in each mode is listed in the simple8b_modes * table below. For example, consider the following codeword: * * 20-bit integer 20-bit integer 20-bit integer * 1101 00000000000000010010 01111010000100100000 00000000000000010100 * ^ * selector * * The selector 1101 is 13 in decimal. From the modes table below, we see * that it means that the codeword encodes three 20-bit integers. In decimal, * those integers are 18, 500000 and 20. Because we encode deltas rather than * absolute values, the actual values that they represent are 18, 500018 and * 500038. * * Modes 0 and 1 are a bit special; they encode a run of 240 or 120 zeroes * (which means 240 or 120 consecutive integers, since we're encoding the * deltas between integers), without using the rest of the codeword bits * for anything. * * Simple-8b cannot encode integers larger than 60 bits. Values larger than * that are always stored in the 'first' field of a leaf item, never in the * packed codeword. If there is a sequence of integers that are more than * 2^60 apart, the codeword will go unused on those items. To represent that, * we use a magic EMPTY_CODEWORD codeword value. */ static const struct simple8b_mode { uint8 bits_per_int; uint8 num_ints; } simple8b_modes[17] = { {0, 240}, /* mode 0: 240 zeroes */ {0, 120}, /* mode 1: 120 zeroes */ {1, 60}, /* mode 2: sixty 1-bit integers */ {2, 30}, /* mode 3: thirty 2-bit integers */ {3, 20}, /* mode 4: twenty 3-bit integers */ {4, 15}, /* mode 5: fifteen 4-bit integers */ {5, 12}, /* mode 6: twelve 5-bit integers */ {6, 10}, /* mode 7: ten 6-bit integers */ {7, 8}, /* mode 8: eight 7-bit integers (four bits * are wasted) */ {8, 7}, /* mode 9: seven 8-bit integers (four bits * are wasted) */ {10, 6}, /* mode 10: six 10-bit integers */ {12, 5}, /* mode 11: five 12-bit integers */ {15, 4}, /* mode 12: four 15-bit integers */ {20, 3}, /* mode 13: three 20-bit integers */ {30, 2}, /* mode 14: two 30-bit integers */ {60, 1}, /* mode 15: one 60-bit integer */ {0, 0} /* sentinel value */ }; /* * EMPTY_CODEWORD is a special value, used to indicate "no values". * It is used if the next value is too large to be encoded with Simple-8b. * * This value looks like a mode-0 codeword, but we can distinguish it * because a regular mode-0 codeword would have zeroes in the unused bits. */ #define EMPTY_CODEWORD UINT64CONST(0x0FFFFFFFFFFFFFFF) /* * Encode a number of integers into a Simple-8b codeword. * * (What we actually encode are deltas between successive integers. * "base" is the value before ints[0].) * * The input array must contain at least SIMPLE8B_MAX_VALUES_PER_CODEWORD * elements, ensuring that we can produce a full codeword. * * Returns the encoded codeword, and sets *num_encoded to the number of * input integers that were encoded. That can be zero, if the first delta * is too large to be encoded. */ static uint64 simple8b_encode(const uint64 *ints, int *num_encoded, uint64 base) { int selector; int nints; int bits; uint64 diff; uint64 last_val; uint64 codeword; int i; Assert(ints[0] > base); /* * Select the "mode" to use for this codeword. * * In each iteration, check if the next value can be represented in the * current mode we're considering. If it's too large, then step up the * mode to a wider one, and repeat. If it fits, move on to the next * integer. Repeat until the codeword is full, given the current mode. * * Note that we don't have any way to represent unused slots in the * codeword, so we require each codeword to be "full". It is always * possible to produce a full codeword unless the very first delta is too * large to be encoded. For example, if the first delta is small but the * second is too large to be encoded, we'll end up using the last "mode", * which has nints == 1. */ selector = 0; nints = simple8b_modes[0].num_ints; bits = simple8b_modes[0].bits_per_int; diff = ints[0] - base - 1; last_val = ints[0]; i = 0; /* number of deltas we have accepted */ for (;;) { if (diff >= (UINT64CONST(1) << bits)) { /* too large, step up to next mode */ selector++; nints = simple8b_modes[selector].num_ints; bits = simple8b_modes[selector].bits_per_int; /* we might already have accepted enough deltas for this mode */ if (i >= nints) break; } else { /* accept this delta; then done if codeword is full */ i++; if (i >= nints) break; /* examine next delta */ Assert(ints[i] > last_val); diff = ints[i] - last_val - 1; last_val = ints[i]; } } if (nints == 0) { /* * The first delta is too large to be encoded with Simple-8b. * * If there is at least one not-too-large integer in the input, we * will encode it using mode 15 (or a more compact mode). Hence, we * can only get here if the *first* delta is >= 2^60. */ Assert(i == 0); *num_encoded = 0; return EMPTY_CODEWORD; } /* * Encode the integers using the selected mode. Note that we shift them * into the codeword in reverse order, so that they will come out in the * correct order in the decoder. */ codeword = 0; if (bits > 0) { for (i = nints - 1; i > 0; i--) { diff = ints[i] - ints[i - 1] - 1; codeword |= diff; codeword <<= bits; } diff = ints[0] - base - 1; codeword |= diff; } /* add selector to the codeword, and return */ codeword |= (uint64) selector << 60; *num_encoded = nints; return codeword; } /* * Decode a codeword into an array of integers. * Returns the number of integers decoded. */ static int simple8b_decode(uint64 codeword, uint64 *decoded, uint64 base) { int selector = (codeword >> 60); int nints = simple8b_modes[selector].num_ints; int bits = simple8b_modes[selector].bits_per_int; uint64 mask = (UINT64CONST(1) << bits) - 1; uint64 curr_value; if (codeword == EMPTY_CODEWORD) return 0; curr_value = base; for (int i = 0; i < nints; i++) { uint64 diff = codeword & mask; curr_value += 1 + diff; decoded[i] = curr_value; codeword >>= bits; } return nints; } /* * This is very similar to simple8b_decode(), but instead of decoding all * the values to an array, it just checks if the given "key" is part of * the codeword. */ static bool simple8b_contains(uint64 codeword, uint64 key, uint64 base) { int selector = (codeword >> 60); int nints = simple8b_modes[selector].num_ints; int bits = simple8b_modes[selector].bits_per_int; if (codeword == EMPTY_CODEWORD) return false; if (bits == 0) { /* Special handling for 0-bit cases. */ return (key - base) <= nints; } else { uint64 mask = (UINT64CONST(1) << bits) - 1; uint64 curr_value; curr_value = base; for (int i = 0; i < nints; i++) { uint64 diff = codeword & mask; curr_value += 1 + diff; if (curr_value >= key) { if (curr_value == key) return true; else return false; } codeword >>= bits; } } return false; }