design

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Published: May 1, 2015 License: BSD-3-Clause, Apache-2.0 Imports: 0 Imported by: 0

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Overview

Package design describes some of the data structures used in QL.

Handles

A handle is a 7 byte "pointer" to a block in the DB[0].

Scalar encoding

Encoding of so called "scalars" provided by [1]. Unless specified otherwise, all values discussed below are scalars, encoded scalars or encoding of scalar arrays.

Database root

DB root is a 1-scalar found at a fixed handle (#1).

+---+------+--------+-----------------------+
| # | Name |  Type  |     Description       |
+---+------+--------+-----------------------+
| 0 | head | handle | First table meta data |
+---+------+--------+-----------------------+

Head is the head of a single linked list of table of meta data. It's zero if there are no tables in the DB.

Table meta data

Table meta data are a 6-scalar.

+---+---------+--------+--------------------------+
| # | Name    | Type   |      Description         |
+---+---------+--------+--------------------------+
| 0 | next    | handle | Next table meta data.    |
| 1 | scols   | string | Column defintitions      |
| 2 | hhead   | handle | -> head -> first record  |
| 3 | name    | string | Table name               |
| 4 | indices | string | Index definitions        |
| 5 | hxroots | handle | Index B+Trees roots list |
+---+---------+--------+--------------------------+

Fields #4 and #5 are optional for backward compatibility with existing databases. OTOH, forward compatibility will not work. Once any indices are created using a newer QL version the older versions of QL, expecting only 4 fields of meta data will not be able to use the DB. That's the intended behavior because the older versions of QL cannot update the indexes, which can break queries runned by the newer QL version which expect indices to be always actualized on any table-with-indices mutation.

The handle of the next table meta data is in the field #0 (next). If there is no next table meta data, the field is zero. Names and types of table columns are stored in field #1 (scols). A single field is described by concatenating a type tag and the column name. The type tags are

bool       'b'
complex64  'c'
complex128 'd'
float32    'f'
float64    'g', alias float
int8       'i'
int16      'j'
int32      'k'
int64      'l', alias int
string     's'
uint8      'u', alias byte
uint16     'v'
uint32     'w'
uint64     'x', alias uint
bigInt     'I'
bigRat     'R'
blob       'B'
duration   'D'
time       'T'

The scols value is the above described encoded fields joined using "|". For example

CREATE TABLE t (Foo bool, Bar string, Baz float);

This statement adds a table meta data with scols

"bFool|sBar|gBaz"

Columns can be dropped from a table

ALTER TABLE t DROP COLUMN Bar;

This "erases" the field info in scols, so the value becomes

"bFool||gBaz"

Colums can be added to a table

ALTER TABLE t ADD Count uint;

New fields are always added to the end of scols

"bFool||gBaz|xCount"

Index of a field in strings.Split(scols, "|") is the index of the field in a table record. The above discussed rules for column dropping and column adding allow for schema evolution without a need to reshape any existing table data. Dropped columns are left where they are and new records insert nil in their place. The encoded nil is one byte. Added columns, when not present in preexisting records are returned as nil values. If the overhead of dropped columns becomes an issue and there's time/space and memory enough to move the records of a table around:

BEGIN TRANSACTION;
	CREATE TABLE new (column definitions);
	INSERT INTO new SELECT * FROM old;
	DROP TABLE old;
	CREATE TABLE old (column definitions);
	INSERT INTO old SELECT * FROM new;
	DROP TABLE new;
END TRANSACTION;

This is not very time/space effective and for Big Data it can cause an OOM because transactions are limited by memory resources available to the process. Perhaps a method and/or QL statement to do this in-place should be added (MAYBE consider adopting MySQL's OPTIMIZE TABLE syntax).

Field #2 (hhead) is a handle to a head of table records, i.e. not a handle to the first record in the table. It is thus always non zero even for a table having no records. The reason for this "double pointer" schema is to enable adding (linking) a new record by updating a single value of the (hhead pointing to) head.

tableMeta.hhead	-> head	-> firstTableRecord

The table name is stored in field #3 (name).

Indices

Consider an index named N, indexing column named C. The encoding of this particular index is a string "<tag>N". <tag> is a string "n" for non unique indices and "u" for unique indices. There is this index information for the index possibly indexing the record id() and for all other columns of scols. Where the column is not indexed, the index info is an empty string. Infos for all indexes are joined with "|". For example

BEGIN TRANSACTION;
	CREATE TABLE t (Foo int, Bar bool, Baz string);
	CREATE INDEX X ON t (Baz);
	CREATE UNIQUE INDEX Y ON t (Foo);
COMMIT;

The values of fields #1 and #4 for the above are

  scols: "lFoo|bBar|sBaz"
indices: "|uY||nX"

Aligning properly the "|" split parts

                     id   col #0   col#1    col#2
	+----------+----+--------+--------+--------+
	|   scols: |    | "lFoo" | "bBar" | "sBaz" |
	+----------+----+--------+--------+--------+
	| indices: | "" | "uY"   | ""     | "nX"   |
	+----------+----+--------+--------+--------+

shows that the record id() is not indexed for this table while the columns Foo and Baz are.

Note that there cannot be two differently named indexes for the same column and it's intended. The indices are B+Trees[2]. The list of handles to their roots is pointed to by hxroots with zeros for non indexed columns. For the previous example

tableMeta.hxroots -> {0, y, 0, x}

where x is the root of the B+Tree for the X index and y is the root of the B+Tree for the Y index. If there would be an index for id(), its B+Tree root will be present where the first zero is. Similarly to hhead, hxroots is never zero, even when there are no indices for a table.

Table record

A table record is an N-scalar.

+-----+------------+--------+-------------------------------+
|  #  |    Name    |  Type  |      Description              |
+-----+------------+--------+-------------------------------+
|  0  | next       | handle | Next record or zero.          |
|  1  | id         | int64  | Automatically assigned unique |
|     |            |        | value obtainable by id().     |
|  2  | field #0   | scalar | First field of the record.    |
|  3  | field #1   | scalar | Second field of the record.   |
     ...
| N-1 | field #N-2 | scalar | Last field of the record.     |
+-----+------------+--------+-------------------------------+

The linked "ordering" of table records has no semantics and it doesn't have to correlate to the order of how the records were added to the table. In fact, an efficient way of the linking leads to "ordering" which is actually reversed wrt the insertion order.

Non unique index

The composite key of the B+Tree is {indexed value, record handle}. The B+Tree value is not used.

           B+Tree key                    B+Tree value
+---------------+---------------+      +--------------+
| Indexed Value | Record Handle |  ->  |   not used   |
+---------------+---------------+      +--------------+

Unique index

If the indexed value is NULL then the composite B+Tree key is {nil, record handle} and the B+Tree value is not used.

        B+Tree key                B+Tree value
+------+-----------------+      +--------------+
| NULL |  Record Handle  |  ->  |   not used   |
+------+-----------------+      +--------------+

If the indexed value is not NULL then key of the B+Tree key is the indexed value and the B+Tree value is the record handle.

        B+Tree key                B+Tree value
+------------------------+      +---------------+
| Non NULL Indexed Value |  ->  | Record Handle |
+------------------------+      +---------------+

Non scalar types

Scalar types of [1] are bool, complex*, float*, int*, uint*, string and []byte types. All other types are "blob-like".

QL type         Go type
-----------------------------
blob            []byte
bigint          big.Int
bigrat          big.Rat
time            time.Time
duration        time.Duration

Memory back-end stores the Go type directly. File back-end must resort to encode all of the above as (tagged) []byte due to the lack of more types supported natively by lldb. NULL values of blob-like types are encoded as nil (gbNull in lldb/gb.go), exactly the same as the already existing QL types are.

Blob encoding

The values of the blob-like types are first encoded into a []byte slice:

+-----------------------+-------------------+
| blob                  | raw               |
| bigint, bigrat, time	| gob encoded       |
| duration		| gob encoded int64 |
+-----------------------+-------------------+

The gob encoding is "differential" wrt an initial encoding of all of the blob-like type. IOW, the initial type descriptors which gob encoding must write out are stripped off and "resupplied" on decoding transparently. See also blob.go. If the length of the resulting slice is <= shortBlob, the first and only chunk is the scalar encoding of

[]interface{}{typeTag, slice}.                  // initial (and last) chunk

The length of slice can be zero (for blob("")). If the resulting slice is long (> shortBlob), the first chunk comes from encoding

[]interface{}{typeTag, nextHandle, firstPart}.  // initial, but not final chunk

In this case len(firstPart) <= shortBlob. Second and other chunks: If the chunk is the last one, src is

[]interface{lastPart}.                          // overflow chunk (last)

In this case len(lastPart) <= 64kB. If the chunk is not the last one, src is

[]interface{}{nextHandle, part}.                // overflow chunk (not last)

In this case len(part) == 64kB.

Rationale

While these notes might be useful to anyone looking at QL sources, the specifically intended reader is my future self.

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