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rculfhash.c
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rculfhash.c
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/*
* rculfhash.c
*
* Userspace RCU library - Lock-Free Resizable RCU Hash Table
*
* Copyright 2010-2011 - Mathieu Desnoyers <[email protected]>
* Copyright 2011 - Lai Jiangshan <[email protected]>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*
* Based on the following articles:
* - Ori Shalev and Nir Shavit. Split-ordered lists: Lock-free
* extensible hash tables. J. ACM 53, 3 (May 2006), 379-405.
* - Michael, M. M. High performance dynamic lock-free hash tables
* and list-based sets. In Proceedings of the fourteenth annual ACM
* symposium on Parallel algorithms and architectures, ACM Press,
* (2002), 73-82.
*
* Some specificities of this Lock-Free Resizable RCU Hash Table
* implementation:
*
* - RCU read-side critical section allows readers to perform hash
* table lookups, as well as traversals, and use the returned objects
* safely by allowing memory reclaim to take place only after a grace
* period.
* - Add and remove operations are lock-free, and do not need to
* allocate memory. They need to be executed within RCU read-side
* critical section to ensure the objects they read are valid and to
* deal with the cmpxchg ABA problem.
* - add and add_unique operations are supported. add_unique checks if
* the node key already exists in the hash table. It ensures not to
* populate a duplicate key if the node key already exists in the hash
* table.
* - The resize operation executes concurrently with
* add/add_unique/add_replace/remove/lookup/traversal.
* - Hash table nodes are contained within a split-ordered list. This
* list is ordered by incrementing reversed-bits-hash value.
* - An index of bucket nodes is kept. These bucket nodes are the hash
* table "buckets". These buckets are internal nodes that allow to
* perform a fast hash lookup, similarly to a skip list. These
* buckets are chained together in the split-ordered list, which
* allows recursive expansion by inserting new buckets between the
* existing buckets. The split-ordered list allows adding new buckets
* between existing buckets as the table needs to grow.
* - The resize operation for small tables only allows expanding the
* hash table. It is triggered automatically by detecting long chains
* in the add operation.
* - The resize operation for larger tables (and available through an
* API) allows both expanding and shrinking the hash table.
* - Split-counters are used to keep track of the number of
* nodes within the hash table for automatic resize triggering.
* - Resize operation initiated by long chain detection is executed by a
* call_rcu thread, which keeps lock-freedom of add and remove.
* - Resize operations are protected by a mutex.
* - The removal operation is split in two parts: first, a "removed"
* flag is set in the next pointer within the node to remove. Then,
* a "garbage collection" is performed in the bucket containing the
* removed node (from the start of the bucket up to the removed node).
* All encountered nodes with "removed" flag set in their next
* pointers are removed from the linked-list. If the cmpxchg used for
* removal fails (due to concurrent garbage-collection or concurrent
* add), we retry from the beginning of the bucket. This ensures that
* the node with "removed" flag set is removed from the hash table
* (not visible to lookups anymore) before the RCU read-side critical
* section held across removal ends. Furthermore, this ensures that
* the node with "removed" flag set is removed from the linked-list
* before its memory is reclaimed. After setting the "removal" flag,
* only the thread which removal is the first to set the "removal
* owner" flag (with an xchg) into a node's next pointer is considered
* to have succeeded its removal (and thus owns the node to reclaim).
* Because we garbage-collect starting from an invariant node (the
* start-of-bucket bucket node) up to the "removed" node (or find a
* reverse-hash that is higher), we are sure that a successful
* traversal of the chain leads to a chain that is present in the
* linked-list (the start node is never removed) and that it does not
* contain the "removed" node anymore, even if concurrent delete/add
* operations are changing the structure of the list concurrently.
* - The add operations perform garbage collection of buckets if they
* encounter nodes with removed flag set in the bucket where they want
* to add their new node. This ensures lock-freedom of add operation by
* helping the remover unlink nodes from the list rather than to wait
* for it do to so.
* - There are three memory backends for the hash table buckets: the
* "order table", the "chunks", and the "mmap".
* - These bucket containers contain a compact version of the hash table
* nodes.
* - The RCU "order table":
* - has a first level table indexed by log2(hash index) which is
* copied and expanded by the resize operation. This order table
* allows finding the "bucket node" tables.
* - There is one bucket node table per hash index order. The size of
* each bucket node table is half the number of hashes contained in
* this order (except for order 0).
* - The RCU "chunks" is best suited for close interaction with a page
* allocator. It uses a linear array as index to "chunks" containing
* each the same number of buckets.
* - The RCU "mmap" memory backend uses a single memory map to hold
* all buckets.
* - synchronize_rcu is used to garbage-collect the old bucket node table.
*
* Ordering Guarantees:
*
* To discuss these guarantees, we first define "read" operation as any
* of the the basic cds_lfht_lookup, cds_lfht_next_duplicate,
* cds_lfht_first, cds_lfht_next operation, as well as
* cds_lfht_add_unique (failure).
*
* We define "read traversal" operation as any of the following
* group of operations
* - cds_lfht_lookup followed by iteration with cds_lfht_next_duplicate
* (and/or cds_lfht_next, although less common).
* - cds_lfht_add_unique (failure) followed by iteration with
* cds_lfht_next_duplicate (and/or cds_lfht_next, although less
* common).
* - cds_lfht_first followed iteration with cds_lfht_next (and/or
* cds_lfht_next_duplicate, although less common).
*
* We define "write" operations as any of cds_lfht_add,
* cds_lfht_add_unique (success), cds_lfht_add_replace, cds_lfht_del.
*
* When cds_lfht_add_unique succeeds (returns the node passed as
* parameter), it acts as a "write" operation. When cds_lfht_add_unique
* fails (returns a node different from the one passed as parameter), it
* acts as a "read" operation. A cds_lfht_add_unique failure is a
* cds_lfht_lookup "read" operation, therefore, any ordering guarantee
* referring to "lookup" imply any of "lookup" or cds_lfht_add_unique
* (failure).
*
* We define "prior" and "later" node as nodes observable by reads and
* read traversals respectively before and after a write or sequence of
* write operations.
*
* Hash-table operations are often cascaded, for example, the pointer
* returned by a cds_lfht_lookup() might be passed to a cds_lfht_next(),
* whose return value might in turn be passed to another hash-table
* operation. This entire cascaded series of operations must be enclosed
* by a pair of matching rcu_read_lock() and rcu_read_unlock()
* operations.
*
* The following ordering guarantees are offered by this hash table:
*
* A.1) "read" after "write": if there is ordering between a write and a
* later read, then the read is guaranteed to see the write or some
* later write.
* A.2) "read traversal" after "write": given that there is dependency
* ordering between reads in a "read traversal", if there is
* ordering between a write and the first read of the traversal,
* then the "read traversal" is guaranteed to see the write or
* some later write.
* B.1) "write" after "read": if there is ordering between a read and a
* later write, then the read will never see the write.
* B.2) "write" after "read traversal": given that there is dependency
* ordering between reads in a "read traversal", if there is
* ordering between the last read of the traversal and a later
* write, then the "read traversal" will never see the write.
* C) "write" while "read traversal": if a write occurs during a "read
* traversal", the traversal may, or may not, see the write.
* D.1) "write" after "write": if there is ordering between a write and
* a later write, then the later write is guaranteed to see the
* effects of the first write.
* D.2) Concurrent "write" pairs: The system will assign an arbitrary
* order to any pair of concurrent conflicting writes.
* Non-conflicting writes (for example, to different keys) are
* unordered.
* E) If a grace period separates a "del" or "replace" operation
* and a subsequent operation, then that subsequent operation is
* guaranteed not to see the removed item.
* F) Uniqueness guarantee: given a hash table that does not contain
* duplicate items for a given key, there will only be one item in
* the hash table after an arbitrary sequence of add_unique and/or
* add_replace operations. Note, however, that a pair of
* concurrent read operations might well access two different items
* with that key.
* G.1) If a pair of lookups for a given key are ordered (e.g. by a
* memory barrier), then the second lookup will return the same
* node as the previous lookup, or some later node.
* G.2) A "read traversal" that starts after the end of a prior "read
* traversal" (ordered by memory barriers) is guaranteed to see the
* same nodes as the previous traversal, or some later nodes.
* G.3) Concurrent "read" pairs: concurrent reads are unordered. For
* example, if a pair of reads to the same key run concurrently
* with an insertion of that same key, the reads remain unordered
* regardless of their return values. In other words, you cannot
* rely on the values returned by the reads to deduce ordering.
*
* Progress guarantees:
*
* * Reads are wait-free. These operations always move forward in the
* hash table linked list, and this list has no loop.
* * Writes are lock-free. Any retry loop performed by a write operation
* is triggered by progress made within another update operation.
*
* Bucket node tables:
*
* hash table hash table the last all bucket node tables
* order size bucket node 0 1 2 3 4 5 6(index)
* table size
* 0 1 1 1
* 1 2 1 1 1
* 2 4 2 1 1 2
* 3 8 4 1 1 2 4
* 4 16 8 1 1 2 4 8
* 5 32 16 1 1 2 4 8 16
* 6 64 32 1 1 2 4 8 16 32
*
* When growing/shrinking, we only focus on the last bucket node table
* which size is (!order ? 1 : (1 << (order -1))).
*
* Example for growing/shrinking:
* grow hash table from order 5 to 6: init the index=6 bucket node table
* shrink hash table from order 6 to 5: fini the index=6 bucket node table
*
* A bit of ascii art explanation:
*
* The order index is the off-by-one compared to the actual power of 2
* because we use index 0 to deal with the 0 special-case.
*
* This shows the nodes for a small table ordered by reversed bits:
*
* bits reverse
* 0 000 000
* 4 100 001
* 2 010 010
* 6 110 011
* 1 001 100
* 5 101 101
* 3 011 110
* 7 111 111
*
* This shows the nodes in order of non-reversed bits, linked by
* reversed-bit order.
*
* order bits reverse
* 0 0 000 000
* 1 | 1 001 100 <-
* 2 | | 2 010 010 <- |
* | | | 3 011 110 | <- |
* 3 -> | | | 4 100 001 | |
* -> | | 5 101 101 |
* -> | 6 110 011
* -> 7 111 111
*/
#define _LGPL_SOURCE
#define _GNU_SOURCE
#include <stdlib.h>
#include <errno.h>
#include <assert.h>
#include <stdio.h>
#include <stdint.h>
#include <string.h>
#include <sched.h>
#include "config.h"
#include <urcu.h>
#include <urcu-call-rcu.h>
#include <urcu-flavor.h>
#include <urcu/arch.h>
#include <urcu/uatomic.h>
#include <urcu/compiler.h>
#include <urcu/rculfhash.h>
#include <rculfhash-internal.h>
#include <stdio.h>
#include <pthread.h>
/*
* Split-counters lazily update the global counter each 1024
* addition/removal. It automatically keeps track of resize required.
* We use the bucket length as indicator for need to expand for small
* tables and machines lacking per-cpu data suppport.
*/
#define COUNT_COMMIT_ORDER 10
#define DEFAULT_SPLIT_COUNT_MASK 0xFUL
#define CHAIN_LEN_TARGET 1
#define CHAIN_LEN_RESIZE_THRESHOLD 3
/*
* Define the minimum table size.
*/
#define MIN_TABLE_ORDER 0
#define MIN_TABLE_SIZE (1UL << MIN_TABLE_ORDER)
/*
* Minimum number of bucket nodes to touch per thread to parallelize grow/shrink.
*/
#define MIN_PARTITION_PER_THREAD_ORDER 12
#define MIN_PARTITION_PER_THREAD (1UL << MIN_PARTITION_PER_THREAD_ORDER)
/*
* The removed flag needs to be updated atomically with the pointer.
* It indicates that no node must attach to the node scheduled for
* removal, and that node garbage collection must be performed.
* The bucket flag does not require to be updated atomically with the
* pointer, but it is added as a pointer low bit flag to save space.
* The "removal owner" flag is used to detect which of the "del"
* operation that has set the "removed flag" gets to return the removed
* node to its caller. Note that the replace operation does not need to
* iteract with the "removal owner" flag, because it validates that
* the "removed" flag is not set before performing its cmpxchg.
*/
#define REMOVED_FLAG (1UL << 0)
#define BUCKET_FLAG (1UL << 1)
#define REMOVAL_OWNER_FLAG (1UL << 2)
#define FLAGS_MASK ((1UL << 3) - 1)
/* Value of the end pointer. Should not interact with flags. */
#define END_VALUE NULL
/*
* ht_items_count: Split-counters counting the number of node addition
* and removal in the table. Only used if the CDS_LFHT_ACCOUNTING flag
* is set at hash table creation.
*
* These are free-running counters, never reset to zero. They count the
* number of add/remove, and trigger every (1 << COUNT_COMMIT_ORDER)
* operations to update the global counter. We choose a power-of-2 value
* for the trigger to deal with 32 or 64-bit overflow of the counter.
*/
struct ht_items_count {
unsigned long add, del;
} __attribute__((aligned(CAA_CACHE_LINE_SIZE)));
/*
* rcu_resize_work: Contains arguments passed to RCU worker thread
* responsible for performing lazy resize.
*/
struct rcu_resize_work {
struct rcu_head head;
struct cds_lfht *ht;
};
/*
* partition_resize_work: Contains arguments passed to worker threads
* executing the hash table resize on partitions of the hash table
* assigned to each processor's worker thread.
*/
struct partition_resize_work {
pthread_t thread_id;
struct cds_lfht *ht;
unsigned long i, start, len;
void (*fct)(struct cds_lfht *ht, unsigned long i,
unsigned long start, unsigned long len);
};
/*
* Algorithm to reverse bits in a word by lookup table, extended to
* 64-bit words.
* Source:
* http://graphics.stanford.edu/~seander/bithacks.html#BitReverseTable
* Originally from Public Domain.
*/
static const uint8_t BitReverseTable256[256] =
{
#define R2(n) (n), (n) + 2*64, (n) + 1*64, (n) + 3*64
#define R4(n) R2(n), R2((n) + 2*16), R2((n) + 1*16), R2((n) + 3*16)
#define R6(n) R4(n), R4((n) + 2*4 ), R4((n) + 1*4 ), R4((n) + 3*4 )
R6(0), R6(2), R6(1), R6(3)
};
#undef R2
#undef R4
#undef R6
static
uint8_t bit_reverse_u8(uint8_t v)
{
return BitReverseTable256[v];
}
#if (CAA_BITS_PER_LONG == 32)
static
uint32_t bit_reverse_u32(uint32_t v)
{
return ((uint32_t) bit_reverse_u8(v) << 24) |
((uint32_t) bit_reverse_u8(v >> 8) << 16) |
((uint32_t) bit_reverse_u8(v >> 16) << 8) |
((uint32_t) bit_reverse_u8(v >> 24));
}
#else
static
uint64_t bit_reverse_u64(uint64_t v)
{
return ((uint64_t) bit_reverse_u8(v) << 56) |
((uint64_t) bit_reverse_u8(v >> 8) << 48) |
((uint64_t) bit_reverse_u8(v >> 16) << 40) |
((uint64_t) bit_reverse_u8(v >> 24) << 32) |
((uint64_t) bit_reverse_u8(v >> 32) << 24) |
((uint64_t) bit_reverse_u8(v >> 40) << 16) |
((uint64_t) bit_reverse_u8(v >> 48) << 8) |
((uint64_t) bit_reverse_u8(v >> 56));
}
#endif
static
unsigned long bit_reverse_ulong(unsigned long v)
{
#if (CAA_BITS_PER_LONG == 32)
return bit_reverse_u32(v);
#else
return bit_reverse_u64(v);
#endif
}
/*
* fls: returns the position of the most significant bit.
* Returns 0 if no bit is set, else returns the position of the most
* significant bit (from 1 to 32 on 32-bit, from 1 to 64 on 64-bit).
*/
#if defined(__i386) || defined(__x86_64)
static inline
unsigned int fls_u32(uint32_t x)
{
int r;
asm("bsrl %1,%0\n\t"
"jnz 1f\n\t"
"movl $-1,%0\n\t"
"1:\n\t"
: "=r" (r) : "rm" (x));
return r + 1;
}
#define HAS_FLS_U32
#endif
#if defined(__x86_64)
static inline
unsigned int fls_u64(uint64_t x)
{
long r;
asm("bsrq %1,%0\n\t"
"jnz 1f\n\t"
"movq $-1,%0\n\t"
"1:\n\t"
: "=r" (r) : "rm" (x));
return r + 1;
}
#define HAS_FLS_U64
#endif
#ifndef HAS_FLS_U64
static __attribute__((unused))
unsigned int fls_u64(uint64_t x)
{
unsigned int r = 64;
if (!x)
return 0;
if (!(x & 0xFFFFFFFF00000000ULL)) {
x <<= 32;
r -= 32;
}
if (!(x & 0xFFFF000000000000ULL)) {
x <<= 16;
r -= 16;
}
if (!(x & 0xFF00000000000000ULL)) {
x <<= 8;
r -= 8;
}
if (!(x & 0xF000000000000000ULL)) {
x <<= 4;
r -= 4;
}
if (!(x & 0xC000000000000000ULL)) {
x <<= 2;
r -= 2;
}
if (!(x & 0x8000000000000000ULL)) {
x <<= 1;
r -= 1;
}
return r;
}
#endif
#ifndef HAS_FLS_U32
static __attribute__((unused))
unsigned int fls_u32(uint32_t x)
{
unsigned int r = 32;
if (!x)
return 0;
if (!(x & 0xFFFF0000U)) {
x <<= 16;
r -= 16;
}
if (!(x & 0xFF000000U)) {
x <<= 8;
r -= 8;
}
if (!(x & 0xF0000000U)) {
x <<= 4;
r -= 4;
}
if (!(x & 0xC0000000U)) {
x <<= 2;
r -= 2;
}
if (!(x & 0x80000000U)) {
x <<= 1;
r -= 1;
}
return r;
}
#endif
unsigned int cds_lfht_fls_ulong(unsigned long x)
{
#if (CAA_BITS_PER_LONG == 32)
return fls_u32(x);
#else
return fls_u64(x);
#endif
}
/*
* Return the minimum order for which x <= (1UL << order).
* Return -1 if x is 0.
*/
int cds_lfht_get_count_order_u32(uint32_t x)
{
if (!x)
return -1;
return fls_u32(x - 1);
}
/*
* Return the minimum order for which x <= (1UL << order).
* Return -1 if x is 0.
*/
int cds_lfht_get_count_order_ulong(unsigned long x)
{
if (!x)
return -1;
return cds_lfht_fls_ulong(x - 1);
}
static
void cds_lfht_resize_lazy_grow(struct cds_lfht *ht, unsigned long size, int growth);
static
void cds_lfht_resize_lazy_count(struct cds_lfht *ht, unsigned long size,
unsigned long count);
static long nr_cpus_mask = -1;
static long split_count_mask = -1;
#if defined(HAVE_SYSCONF)
static void ht_init_nr_cpus_mask(void)
{
long maxcpus;
maxcpus = sysconf(_SC_NPROCESSORS_CONF);
if (maxcpus <= 0) {
nr_cpus_mask = -2;
return;
}
/*
* round up number of CPUs to next power of two, so we
* can use & for modulo.
*/
maxcpus = 1UL << cds_lfht_get_count_order_ulong(maxcpus);
nr_cpus_mask = maxcpus - 1;
}
#else /* #if defined(HAVE_SYSCONF) */
static void ht_init_nr_cpus_mask(void)
{
nr_cpus_mask = -2;
}
#endif /* #else #if defined(HAVE_SYSCONF) */
static
void alloc_split_items_count(struct cds_lfht *ht)
{
if (nr_cpus_mask == -1) {
ht_init_nr_cpus_mask();
if (nr_cpus_mask < 0)
split_count_mask = DEFAULT_SPLIT_COUNT_MASK;
else
split_count_mask = nr_cpus_mask;
}
assert(split_count_mask >= 0);
if (ht->flags & CDS_LFHT_ACCOUNTING) {
ht->split_count = calloc(split_count_mask + 1,
sizeof(struct ht_items_count));
assert(ht->split_count);
} else {
ht->split_count = NULL;
}
}
static
void free_split_items_count(struct cds_lfht *ht)
{
poison_free(ht->split_count);
}
#if defined(HAVE_SCHED_GETCPU)
static
int ht_get_split_count_index(unsigned long hash)
{
int cpu;
assert(split_count_mask >= 0);
cpu = sched_getcpu();
if (caa_unlikely(cpu < 0))
return hash & split_count_mask;
else
return cpu & split_count_mask;
}
#else /* #if defined(HAVE_SCHED_GETCPU) */
static
int ht_get_split_count_index(unsigned long hash)
{
return hash & split_count_mask;
}
#endif /* #else #if defined(HAVE_SCHED_GETCPU) */
static
void ht_count_add(struct cds_lfht *ht, unsigned long size, unsigned long hash)
{
unsigned long split_count;
int index;
long count;
if (caa_unlikely(!ht->split_count))
return;
index = ht_get_split_count_index(hash);
split_count = uatomic_add_return(&ht->split_count[index].add, 1);
if (caa_likely(split_count & ((1UL << COUNT_COMMIT_ORDER) - 1)))
return;
/* Only if number of add multiple of 1UL << COUNT_COMMIT_ORDER */
dbg_printf("add split count %lu\n", split_count);
count = uatomic_add_return(&ht->count,
1UL << COUNT_COMMIT_ORDER);
if (caa_likely(count & (count - 1)))
return;
/* Only if global count is power of 2 */
if ((count >> CHAIN_LEN_RESIZE_THRESHOLD) < size)
return;
dbg_printf("add set global %ld\n", count);
cds_lfht_resize_lazy_count(ht, size,
count >> (CHAIN_LEN_TARGET - 1));
}
static
void ht_count_del(struct cds_lfht *ht, unsigned long size, unsigned long hash)
{
unsigned long split_count;
int index;
long count;
if (caa_unlikely(!ht->split_count))
return;
index = ht_get_split_count_index(hash);
split_count = uatomic_add_return(&ht->split_count[index].del, 1);
if (caa_likely(split_count & ((1UL << COUNT_COMMIT_ORDER) - 1)))
return;
/* Only if number of deletes multiple of 1UL << COUNT_COMMIT_ORDER */
dbg_printf("del split count %lu\n", split_count);
count = uatomic_add_return(&ht->count,
-(1UL << COUNT_COMMIT_ORDER));
if (caa_likely(count & (count - 1)))
return;
/* Only if global count is power of 2 */
if ((count >> CHAIN_LEN_RESIZE_THRESHOLD) >= size)
return;
dbg_printf("del set global %ld\n", count);
/*
* Don't shrink table if the number of nodes is below a
* certain threshold.
*/
if (count < (1UL << COUNT_COMMIT_ORDER) * (split_count_mask + 1))
return;
cds_lfht_resize_lazy_count(ht, size,
count >> (CHAIN_LEN_TARGET - 1));
}
static
void check_resize(struct cds_lfht *ht, unsigned long size, uint32_t chain_len)
{
unsigned long count;
if (!(ht->flags & CDS_LFHT_AUTO_RESIZE))
return;
count = uatomic_read(&ht->count);
/*
* Use bucket-local length for small table expand and for
* environments lacking per-cpu data support.
*/
if (count >= (1UL << COUNT_COMMIT_ORDER))
return;
if (chain_len > 100)
dbg_printf("WARNING: large chain length: %u.\n",
chain_len);
if (chain_len >= CHAIN_LEN_RESIZE_THRESHOLD)
cds_lfht_resize_lazy_grow(ht, size,
cds_lfht_get_count_order_u32(chain_len - (CHAIN_LEN_TARGET - 1)));
}
static
struct cds_lfht_node *clear_flag(struct cds_lfht_node *node)
{
return (struct cds_lfht_node *) (((unsigned long) node) & ~FLAGS_MASK);
}
static
int is_removed(struct cds_lfht_node *node)
{
return ((unsigned long) node) & REMOVED_FLAG;
}
static
int is_bucket(struct cds_lfht_node *node)
{
return ((unsigned long) node) & BUCKET_FLAG;
}
static
struct cds_lfht_node *flag_bucket(struct cds_lfht_node *node)
{
return (struct cds_lfht_node *) (((unsigned long) node) | BUCKET_FLAG);
}
static
int is_removal_owner(struct cds_lfht_node *node)
{
return ((unsigned long) node) & REMOVAL_OWNER_FLAG;
}
static
struct cds_lfht_node *flag_removal_owner(struct cds_lfht_node *node)
{
return (struct cds_lfht_node *) (((unsigned long) node) | REMOVAL_OWNER_FLAG);
}
static
struct cds_lfht_node *flag_removed_or_removal_owner(struct cds_lfht_node *node)
{
return (struct cds_lfht_node *) (((unsigned long) node) | REMOVED_FLAG | REMOVAL_OWNER_FLAG);
}
static
struct cds_lfht_node *get_end(void)
{
return (struct cds_lfht_node *) END_VALUE;
}
static
int is_end(struct cds_lfht_node *node)
{
return clear_flag(node) == (struct cds_lfht_node *) END_VALUE;
}
static
unsigned long _uatomic_xchg_monotonic_increase(unsigned long *ptr,
unsigned long v)
{
unsigned long old1, old2;
old1 = uatomic_read(ptr);
do {
old2 = old1;
if (old2 >= v)
return old2;
} while ((old1 = uatomic_cmpxchg(ptr, old2, v)) != old2);
return old2;
}
static
void cds_lfht_alloc_bucket_table(struct cds_lfht *ht, unsigned long order)
{
return ht->mm->alloc_bucket_table(ht, order);
}
/*
* cds_lfht_free_bucket_table() should be called with decreasing order.
* When cds_lfht_free_bucket_table(0) is called, it means the whole
* lfht is destroyed.
*/
static
void cds_lfht_free_bucket_table(struct cds_lfht *ht, unsigned long order)
{
return ht->mm->free_bucket_table(ht, order);
}
static inline
struct cds_lfht_node *bucket_at(struct cds_lfht *ht, unsigned long index)
{
return ht->bucket_at(ht, index);
}
static inline
struct cds_lfht_node *lookup_bucket(struct cds_lfht *ht, unsigned long size,
unsigned long hash)
{
assert(size > 0);
return bucket_at(ht, hash & (size - 1));
}
/*
* Remove all logically deleted nodes from a bucket up to a certain node key.
*/
static
void _cds_lfht_gc_bucket(struct cds_lfht_node *bucket, struct cds_lfht_node *node)
{
struct cds_lfht_node *iter_prev, *iter, *next, *new_next;
assert(!is_bucket(bucket));
assert(!is_removed(bucket));
assert(!is_bucket(node));
assert(!is_removed(node));
for (;;) {
iter_prev = bucket;
/* We can always skip the bucket node initially */
iter = rcu_dereference(iter_prev->next);
assert(!is_removed(iter));
assert(iter_prev->reverse_hash <= node->reverse_hash);
/*
* We should never be called with bucket (start of chain)
* and logically removed node (end of path compression
* marker) being the actual same node. This would be a
* bug in the algorithm implementation.
*/
assert(bucket != node);
for (;;) {
if (caa_unlikely(is_end(iter)))
return;
if (caa_likely(clear_flag(iter)->reverse_hash > node->reverse_hash))
return;
next = rcu_dereference(clear_flag(iter)->next);
if (caa_likely(is_removed(next)))
break;
iter_prev = clear_flag(iter);
iter = next;
}
assert(!is_removed(iter));
if (is_bucket(iter))
new_next = flag_bucket(clear_flag(next));
else
new_next = clear_flag(next);
(void) uatomic_cmpxchg(&iter_prev->next, iter, new_next);
}
}
static
int _cds_lfht_replace(struct cds_lfht *ht, unsigned long size,
struct cds_lfht_node *old_node,
struct cds_lfht_node *old_next,
struct cds_lfht_node *new_node)
{
struct cds_lfht_node *bucket, *ret_next;
if (!old_node) /* Return -ENOENT if asked to replace NULL node */
return -ENOENT;
assert(!is_removed(old_node));
assert(!is_bucket(old_node));
assert(!is_removed(new_node));
assert(!is_bucket(new_node));
assert(new_node != old_node);
for (;;) {
/* Insert after node to be replaced */
if (is_removed(old_next)) {
/*
* Too late, the old node has been removed under us
* between lookup and replace. Fail.
*/
return -ENOENT;
}
assert(old_next == clear_flag(old_next));
assert(new_node != old_next);
/*
* REMOVAL_OWNER flag is _NEVER_ set before the REMOVED
* flag. It is either set atomically at the same time
* (replace) or after (del).
*/
assert(!is_removal_owner(old_next));
new_node->next = old_next;
/*
* Here is the whole trick for lock-free replace: we add
* the replacement node _after_ the node we want to
* replace by atomically setting its next pointer at the
* same time we set its removal flag. Given that
* the lookups/get next use an iterator aware of the
* next pointer, they will either skip the old node due
* to the removal flag and see the new node, or use
* the old node, but will not see the new one.
* This is a replacement of a node with another node
* that has the same value: we are therefore not
* removing a value from the hash table. We set both the
* REMOVED and REMOVAL_OWNER flags atomically so we own
* the node after successful cmpxchg.
*/
ret_next = uatomic_cmpxchg(&old_node->next,
old_next, flag_removed_or_removal_owner(new_node));
if (ret_next == old_next)
break; /* We performed the replacement. */
old_next = ret_next;
}
/*
* Ensure that the old node is not visible to readers anymore:
* lookup for the node, and remove it (along with any other
* logically removed node) if found.
*/
bucket = lookup_bucket(ht, size, bit_reverse_ulong(old_node->reverse_hash));
_cds_lfht_gc_bucket(bucket, new_node);
assert(is_removed(CMM_LOAD_SHARED(old_node->next)));
return 0;
}
/*
* A non-NULL unique_ret pointer uses the "add unique" (or uniquify) add
* mode. A NULL unique_ret allows creation of duplicate keys.
*/
static
void _cds_lfht_add(struct cds_lfht *ht,
unsigned long hash,
cds_lfht_match_fct match,
const void *key,
unsigned long size,
struct cds_lfht_node *node,
struct cds_lfht_iter *unique_ret,
int bucket_flag)
{
struct cds_lfht_node *iter_prev, *iter, *next, *new_node, *new_next,
*return_node;
struct cds_lfht_node *bucket;
assert(!is_bucket(node));
assert(!is_removed(node));
bucket = lookup_bucket(ht, size, hash);
for (;;) {
uint32_t chain_len = 0;
/*
* iter_prev points to the non-removed node prior to the
* insert location.
*/
iter_prev = bucket;
/* We can always skip the bucket node initially */
iter = rcu_dereference(iter_prev->next);
assert(iter_prev->reverse_hash <= node->reverse_hash);
for (;;) {
if (caa_unlikely(is_end(iter)))
goto insert;
if (caa_likely(clear_flag(iter)->reverse_hash > node->reverse_hash))
goto insert;
/* bucket node is the first node of the identical-hash-value chain */
if (bucket_flag && clear_flag(iter)->reverse_hash == node->reverse_hash)
goto insert;
next = rcu_dereference(clear_flag(iter)->next);
if (caa_unlikely(is_removed(next)))
goto gc_node;
/* uniquely add */
if (unique_ret
&& !is_bucket(next)
&& clear_flag(iter)->reverse_hash == node->reverse_hash) {
struct cds_lfht_iter d_iter = { .node = node, .next = iter, };
/*
* uniquely adding inserts the node as the first
* node of the identical-hash-value node chain.
*
* This semantic ensures no duplicated keys
* should ever be observable in the table
* (including traversing the table node by
* node by forward iterations)
*/
cds_lfht_next_duplicate(ht, match, key, &d_iter);