This came up at the office today. I have no plans of doing such a thing, but theoretically could you write a compiler in SQL? At first glance it appears to me to be turing complete, though extremely cumbersome for many classes of problems.

If it is not turing complete, what would it require to become so?

Note: I have no desire to do anything like write a compiler in SQL, I know it would be a silly thing to do, so if we can avoid that discussion I would appreciate it.

up vote 165 down vote accepted

It turns out that SQL can be Turing Complete even without a true 'scripting' extension such as PL/SQL or PSM (which are designed to be true programming languages, so that's kinda cheating).

In this set of slides Andrew Gierth proves that with CTE and Windowing SQL is Turing Complete, by constructing a cyclic tag system, which has been proved to be Turing Complete. The CTE feature is the important part however -- it allows you to create named sub-expressions that can refer to themselves, and thereby recursively solve problems.

The interesting thing to note is that CTE was not really added to turn SQL into a programming language -- just to turn a declarative querying language into a more powerful declarative querying language. Sort of like in C++, whose templates turned out to be Turing complete even though they weren't intended to create a meta programming language.

Oh, the Mandelbrot set in SQL example is very impressive, as well :)

  • 1
    Oracle SQL is also turing complete, although in a rather sick way: blog.schauderhaft.de/2009/06/18/… – Jens Schauder Aug 19 '14 at 5:38
  • 1
    >It turns out that SQL Shouldn't it say: It turns out that SQL:1999? Just saying this because CTEs were added in version 99 and way too many people associate standard sql with Sql 92. – Ernesto Nov 13 '14 at 14:22
  • @JensSchauder that can be generalised to "Oracle $technology is $some_good_feature, although in a rather sick way" – Robert Grant Oct 4 '16 at 12:49
  • The Mandelbrot set in SQL made my day!!! – C0ppert0p Apr 11 at 21:09

http://channel9.msdn.com/forums/TechOff/431432-SQL-Turing-Completeness-question/

Is a discussion of this topic. A quote:

SQL as such (i.e. the SQL92 standard) is not turing complete. However, many of the languages derived from SQL, such as Oracle's PL/SQL and SQL Server's T-SQL and others are turing complete.

PL/SQL and T-SQL certainly qualify as programming languages, whether SQL92 itself qualifies is open for debate. Some people claim that any piece of code that tells a computer what to do qualifies as a programming language; by that definition SQL92 is one, but so is e.g. HTML. The definition is rather vague, and it's imo a pointless thing to argue about.

The TSQL is Turing Complete.To prove it I made a BrainFuck interpreter.

BrainFuck interpreter in SQL - GitHub

-- Brain Fuck interpreter in SQL

DECLARE @Code  VARCHAR(MAX) = ', [>,] < [.<]'
DECLARE @Input VARCHAR(MAX) = '!dlroW olleH';

-- Creates a "BrainFuck" DataBase.
-- CREATE DATABASE BrainFuck;

-- Creates the Source code table
DECLARE @CodeTable TABLE (
    [Id]      INT IDENTITY(1,1) PRIMARY KEY NOT NULL,
    [Command] CHAR(1) NOT NULL
);

-- Populate the source code into CodeTable
DECLARE @CodeLen INT = LEN(@Code);
DECLARE @CodePos INT = 0;
DECLARE @CodeChar CHAR(1);

WHILE @CodePos < @CodeLen
BEGIN
    SET @CodePos  = @CodePos + 1;
    SET @CodeChar = SUBSTRING(@Code, @CodePos, 1);
    IF @CodeChar IN ('+', '-', '>', '<', ',', '.', '[', ']')
        INSERT INTO @CodeTable ([Command]) VALUES (@CodeChar)
END

-- Creates the Input table
DECLARE @InputTable TABLE (
    [Id]   INT IDENTITY(1,1) PRIMARY KEY NOT NULL,
    [Char] CHAR(1) NOT NULL
);

-- Populate the input text into InputTable
DECLARE @InputLen INT = LEN(@Input);
DECLARE @InputPos INT = 0;

WHILE @InputPos < @InputLen
BEGIN
    SET @InputPos = @InputPos + 1;
    INSERT INTO @InputTable ([Char])
    VALUES (SUBSTRING(@Input, @InputPos, 1))
END

-- Creates the Output table
DECLARE @OutputTable TABLE (
    [Id]   INT IDENTITY(1,1) PRIMARY KEY NOT NULL,
    [Char] CHAR(1) NOT NULL
);

-- Creates the Buffer table
DECLARE @BufferTable TABLE (
    [Id]     INT IDENTITY(1,1) PRIMARY KEY NOT NULL,
    [Memory] INT DEFAULT 0  NOT NULL
);
INSERT INTO @BufferTable ([Memory])
VALUES (0);

-- Initialization of temporary variables 
DECLARE @CodeLength INT = (SELECT COUNT(*) FROM @CodeTable);
DECLARE @CodeIndex  INT = 0;
DECLARE @Pointer    INT = 1;
DECLARE @InputIndex INT = 0;
DECLARE @Command    CHAR(1);
DECLARE @Depth      INT;

-- Main calculation cycle
WHILE @CodeIndex < @CodeLength
BEGIN
    -- Read the next command.
    SET @CodeIndex = @CodeIndex + 1;
    SET @Command = (SELECT [Command] FROM @CodeTable WHERE [Id] = @CodeIndex);

    -- Increment the pointer.
    IF @Command = '>'
    BEGIN
        SET @Pointer = @Pointer + 1;
        IF (SELECT [Id] FROM @BufferTable WHERE [Id] = @Pointer) IS NULL
            INSERT INTO @BufferTable ([Memory]) VALUES (0);
    END

    -- Decrement the pointer.
    ELSE IF @Command = '<'
        SET @Pointer = @Pointer - 1;

    -- Increment the byte at the pointer.
    ELSE IF @Command = '+'
        UPDATE @BufferTable SET [Memory] = [Memory] + 1 WHERE [Id] = @Pointer;

    -- Decrement the byte at the pointer.
    ELSE IF @Command = '-'
        UPDATE @BufferTable SET [Memory] = [Memory] - 1 WHERE [Id] = @Pointer;

    -- Output the byte at the pointer.
    ELSE IF @Command = '.'
        INSERT INTO @OutputTable ([Char]) (SELECT CHAR([Memory]) FROM @BufferTable WHERE [Id] = @Pointer);

    -- Input a byte and store it in the byte at the pointer.
    ELSE IF @Command = ','
    BEGIN
        SET @InputIndex = @InputIndex + 1;
        UPDATE @BufferTable SET [Memory] = COALESCE((SELECT ASCII([Char]) FROM @InputTable WHERE [Id] = @InputIndex), 0) WHERE [Id] = @Pointer;
    END

    -- Jump forward past the matching ] if the byte at the pointer is zero.
    ELSE IF @Command = '[' AND COALESCE((SELECT [Memory] FROM @BufferTable WHERE [Id] = @Pointer), 0) = 0
    BEGIN
        SET @Depth = 1;
        WHILE @Depth > 0
        BEGIN
            SET @CodeIndex = @CodeIndex + 1;
            SET @Command = (SELECT [Command] FROM @CodeTable WHERE [Id] = @CodeIndex);
            IF @Command = '[' SET @Depth = @Depth + 1;
            ELSE IF @Command = ']' SET @Depth = @Depth - 1;
        END
    END

    -- Jump backward to the matching [ unless the byte at the pointer is zero.
    ELSE IF @Command = ']' AND COALESCE((SELECT [Memory] FROM @BufferTable WHERE [Id] = @Pointer), 0) != 0
    BEGIN
        SET @Depth = 1;
        WHILE @Depth > 0
        BEGIN
            SET @CodeIndex = @CodeIndex - 1;
            SET @Command = (SELECT [Command] FROM @CodeTable WHERE [Id] = @CodeIndex);
            IF @Command = ']' SET @Depth = @Depth + 1;
            ELSE IF @Command = '[' SET @Depth = @Depth - 1;
        END
    END
END;

-- Collects and prints the output
DECLARE @Output VARCHAR(MAX);
SELECT @Output = COALESCE(@Output, '') + [Char]
FROM @OutputTable;

PRINT @Output;
Go
  • That's transact SQL which is Turing complete, ANSI SQL I understood is not TC. But good effort! – alimack Jun 14 '16 at 16:43

Strictly speaking, SQL is now a turing complete language because the latest SQL standard includes the "Persistent Stored Modules" (PSMs). In short, a PSM is the standard version of the PL/SQL language in Oracle (and other similar procedural extensions of current DBMS).

With the inclusion of these PSMs, SQL became turing complete

An ANSI select statement, as originally defined in SQL-86, is not turing complete because it always terminates (except for recursive CTEs and only if the implementation supports arbitrarily deep recursion). It is therefore not possible to simulate any other turing machine. Stored procedures are turing complete but thats cheating ;-)

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