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+Bounded-index Extensible Hashing (bihash)
+=========================================
+
+Vpp uses bounded-index extensible hashing to solve a variety of
+exact-match (key, value) lookup problems. Benefits of the current
+implementation:
+
+* Very high record count scaling, tested to 100,000,000 records.
+* Lookup performance degrades gracefully as the number of records increases
+* No reader locking required
+* Template implementation, it's easy to support arbitrary (key,value) types
+
+Bounded-index extensible hashing has been widely used in databases for
+decades. 
+
+Bihash uses a two-level data structure:
+
+```
+    +-----------------+                                              
+    | bucket-0        |                                             
+    |  log2_size      |                                             
+    |  backing store  |                                             
+    +-----------------+                                             
+    | bucket-1        |                                             
+    |  log2_size      |           +--------------------------------+
+    |  backing store  | --------> | KVP_PER_PAGE * key-value-pairs |
+    +-----------------+           | page 0                         |
+         ...                      +--------------------------------+
+    +-----------------+           | KVP_PER_PAGE * key-value-pairs |
+    | bucket-2**N-1   |           | page 1                         |
+    |  log2_size      |           +--------------------------------+
+    |  backing store  |                       ---                   
+    +-----------------+           +--------------------------------+
+                                  | KVP_PER_PAGE * key-value-pairs |
+                                  | page 2**(log2(size)) - 1       |
+                                  +--------------------------------+
+```                                  
+
+Discussion of the algorithm
+---------------------------
+
+This structure has a couple of major advantages. In practice, each
+bucket entry fits into a 64-bit integer. Coincidentally, vpp's target
+CPU architectures support 64-bit atomic operations. When modifying the
+contents of a specific bucket, we do the following:
+
+* Make a working copy of the bucket's backing storage
+* Atomically swap a pointer to the working copy into the bucket array
+* Change the original backing store data
+* Atomically swap back to the original
+
+So, no reader locking is required to search a bihash table.
+
+At lookup time, the implementation computes a key hash code. We use
+the least-significant N bits of the hash to select the bucket.
+
+With the bucket in hand, we learn log2 (nBackingPages) for the
+selected bucket. At this point, we use the next log2_size bits from
+the hash code to select the specific backing page in which the
+(key,value) page will be found.
+
+Net result: we search **one** backing page, not 2**log2_size
+pages. This is a key property of the algorithm.
+
+When sufficient collisions occur to fill the backing pages for a given
+bucket, we double the bucket size, rehash, and deal the bucket
+contents into a double-sized set of backing pages. In the future, we
+may represent the size as a linear combination of two powers-of-two,
+to increase space efficiency.
+
+To solve the "jackpot case" where a set of records collide under
+hashing in a bad way, the implementation will fall back to linear
+search across 2**log2_size backing pages on a per-bucket basis.
+
+To maintain *space* efficiency, we should configure the bucket array
+so that backing pages are effectively utilized. Lookup performance
+tends to change *very litte* if the bucket array is too small or too
+large.
+
+Bihash depends on selecting an effective hash function. If one were to
+use a truly broken hash function such as "return 1ULL." bihash would
+still work, but it would be equivalent to poorly-programmed linear
+search.
+
+We often use cpu intrinsic functions - think crc32 - to rapidly
+compute a hash code which has decent statistics.
+
+Bihash Cookbook
+---------------
+
+### Using current (key,value) template instance types
+
+It's quite easy to use one of the template instance types. As of this
+writing, .../src/vppinfra provides pre-built templates for 8, 16, 20,
+24, 40, and 48 byte keys, u8 * vector keys, and 8 byte values.
+
+See .../src/vppinfra/{bihash_<key-size>_8}.h
+
+To define the data types, #include a specific template instance, most
+often in a subsystem header file:
+
+```c
+     #include <vppinfra/bihash_8_8.h>
+```
+
+If you're building a standalone application, you'll need to define the
+various functions by #including the method implementation file in a C
+source file. 
+
+The core vpp engine currently uses most if not all of the known bihash
+types, so you probably won't need to #include the method
+implementation file.
+
+
+```c
+     #include <vppinfra/bihash_template.c>
+```
+
+Add an instance of the selected bihash data structure to e.g. a
+"main_t" structure:
+
+```c
+    typedef struct
+    {
+      ...
+      BVT (clib_bihash) hash;
+      or
+      clib_bihash_8_8_t hash;
+      ...
+    } my_main_t;
+```
+
+The BV macro concatenate its argument with the value of the
+preprocessor symbol BIHASH_TYPE. The BVT macro concatenates its
+argument with the value of BIHASH_TYPE and the fixed-string "_t". So
+in the above example, BVT (clib_bihash) generates "clib_bihash_8_8_t".
+
+If you're sure you won't decide to change the template / type name
+later, it's perfectly OK to code "clib_bihash_8_8_t" and so forth.
+
+In fact, if you #include multiple template instances in a single
+source file, you **must** use fully-enumerated type names. The macros
+stand no chance of working.
+
+### Initializing a bihash table
+
+Call the init function as shown. As a rough guide, pick a number of
+buckets which is approximately
+number_of_expected_records/BIHASH_KVP_PER_PAGE from the relevant
+template instance header-file.  See previous discussion. 
+
+The amount of memory selected should easily contain all of the
+records, with a generous allowance for hash collisions. Bihash memory
+is allocated separately from the main heap, and won't cost anything
+except kernel PTE's until touched, so it's OK to be reasonably
+generous.
+
+For example:
+
+```c
+    my_main_t *mm = &my_main;
+    clib_bihash_8_8_t *h;
+        
+    h = &mm->hash_table;
+
+    clib_bihash_init_8_8 (h, "test", (u32) number_of_buckets, 
+                           (uword) memory_size);
+```
+
+### Add or delete a key/value pair
+
+Use BV(clib_bihash_add_del), or the explicit type variant:
+
+```c
+   clib_bihash_kv_8_8_t kv;
+   clib_bihash_8_8_t * h;
+   my_main_t *mm = &my_main;
+   clib_bihash_8_8_t *h;
+        
+   h = &mm->hash_table;
+   kv.key = key_to_add_or_delete;
+   kv.value = value_to_add_or_delete;
+
+   clib_bihash_add_del_8_8 (h, &kv, is_add /* 1=add, 0=delete */);
+```
+
+In the delete case, kv.value is irrelevant. To change the value associated
+with an existing (key,value) pair, simply re-add the [new] pair.
+
+### Simple search
+
+The simplest possible (key, value) search goes like so:
+
+```c
+   clib_bihash_kv_8_8_t search_kv, return_kv;
+   clib_bihash_8_8_t * h;
+   my_main_t *mm = &my_main;
+   clib_bihash_8_8_t *h;
+        
+   h = &mm->hash_table;
+   search_kv.key = key_to_add_or_delete;
+
+   if (clib_bihash_search_8_8 (h, &search_kv, &return_kv) < 0)
+     key_not_found()
+   else
+     key_not_found();
+```
+
+Note that it's perfectly fine to collect the lookup result
+
+```c
+   if (clib_bihash_search_8_8 (h, &search_kv, &search_kv))
+     key_not_found();
+   etc.
+```
+
+### Bihash vector processing
+
+When processing a vector of packets which need a certain lookup
+performed, it's worth the trouble to compute the key hash, and
+prefetch the correct bucket ahead of time.
+
+Here's a sketch of one way to write the required code:
+
+Dual-loop:
+* 6 packets ahead, prefetch 2x vlib_buffer_t's and 2x packet data
+  required to form the record keys
+* 4 packets ahead, form 2x record keys and call BV(clib_bihash_hash)
+  or the explicit hash function to calculate the record hashes.
+  Call 2x BV(clib_bihash_prefetch_bucket) to prefetch the buckets
+* 2 packets ahead, call 2x BV(clib_bihash_prefetch_data) to prefetch 
+  2x (key,value) data pages.
+* In the processing section, call 2x BV(clib_bihash_search_inline_with_hash)
+  to perform the search
+
+Programmer's choice whether to stash the hash code somewhere in
+vnet_buffer(b) metadata, or to use local variables.
+
+Single-loop:
+* Use simple search as shown above.
+
+### Walking a bihash table
+
+A fairly common scenario to build "show" commands involves walking a
+bihash table. It's simple enough:
+
+```c
+   my_main_t *mm = &my_main;
+   clib_bihash_8_8_t *h;
+   void callback_fn (clib_bihash_kv_8_8_t *, void *);
+
+   h = &mm->hash_table;
+
+   BV(clib_bihash_foreach_key_value_pair) (h, callback_fn, (void *) arg);
+```
+To nobody's great surprise: clib_bihash_foreach_key_value_pair
+iterates across the entire table, calling callback_fn with active
+entries.
+
+### Creating a new template instance
+
+Creating a new template is easy. Use one of the existing templates as
+a model, and make the obvious changes. The hash and key_compare
+methods are performance-critical in multiple senses.
+
+If the key compare method is slow, every lookup will be slow. If the
+hash function is slow, same story. If the hash function has poor
+statistical properties, space efficiency will suffer. In the limit, a
+bad enough hash function will cause large portions of the table to
+revert to linear search.
+
+Use of the best available vector unit is well worth the trouble in the
+hash and key_compare functions.