为演示如何解决此问题,以下是一些示例表定义。
CREATE TABLE [Description]
(
[DescriptionId] INT IDENTITY NOT NULL CONSTRAINT [PK_Description] PRIMARY KEY,
[DescriptionText] NVARCHAR(50) NOT NULL
)
GO
CREATE TABLE [Hierarchy]
(
[HierarchyId] INT NOT NULL CONSTRAINT [PK_Hierarchy] PRIMARY KEY,
[ParentHierarchyId] INT NULL CONSTRAINT [FK_Hierarchy_ParentHierarchyId] REFERENCES [Hierarchy] ([HierarchyId]) ON DELETE NO ACTION ON UPDATE NO ACTION,
[Price] MONEY NOT NULL,
[DescriptionId] INT NULL CONSTRAINT [FK_Hierarchy_Description] REFERENCES [Description] ([DescriptionId]) ON DELETE SET NULL ON UPDATE CASCADE
)
GO
CREATE INDEX [IX_Hierarchy_ParentHierarchyId] ON [Hierarchy]
([ParentHierarchyId]) INCLUDE ([HierarchyId], [Price], [DescriptionId])
GO
一个天真的方式来获得一个层次 - 也就是说,一个是不可能解决您的性能问题 - 可能是:
;WITH RowEnds AS
(
SELECT h.[HierarchyId], h.[ParentHierarchyId], h.[Price], h.[DescriptionId], h.[HierarchyId] AS [RowEndHierarchyId], 0 AS [ReverseLevel]
FROM [Hierarchy] h
WHERE NOT EXISTS (SELECT 1 FROM [Hierarchy] i WHERE i.[ParentHierarchyId] = h.[HierarchyId])
UNION ALL
SELECT h.[HierarchyId], h.[ParentHierarchyId], h.[Price], h.[DescriptionId], r.[RowEndHierarchyId], r.[ReverseLevel] + 1 AS [ReverseLevel]
FROM [Hierarchy] h
INNER JOIN RowEnds r ON h.[HierarchyId] = r.[ParentHierarchyId]
),
InOrder AS
(
SELECT r.RowEndHierarchyId, r.[HierarchyId], r.Price, d.DescriptionText, RANK() OVER (PARTITION BY r.[RowEndHierarchyId] ORDER BY r.[ReverseLevel] DESC) AS [Level]
FROM RowEnds r
LEFT JOIN [Description] d ON r.DescriptionId = d.DescriptionId
)
SELECT DISTINCT o.RowEndHierarchyId, p.[1] AS Price1, d.[1] AS Description1, p.[2] AS Price2, d.[2] AS Description2, p.[3] AS Price3, d.[3] AS Description3,
p.[4] AS Price4, d.[4] AS Description4, p.[5] AS Price5, d.[5] AS Description5, p.[6] AS Price6, d.[6] AS Description6,
p.[7] AS Price7, d.[7] AS Description7
FROM InOrder o
INNER JOIN
(SELECT projp.RowEndHierarchyId, projp.[Level], projp.[Price]
FROM InOrder projp) ppre
PIVOT (MIN([Price]) FOR [Level] IN ([1], [2], [3], [4], [5], [6], [7])) p
ON o.RowEndHierarchyId = p.RowEndHierarchyId
LEFT JOIN
(SELECT projd.RowEndHierarchyId, projd.[Level], projd.DescriptionText
FROM INOrder projd) dpre
PIVOT (MIN(DescriptionText) FOR [Level] IN ([1], [2], [3], [4], [5], [6], [7])) d
ON o.RowEndHierarchyId = d.RowEndHierarchyId
ORDER BY o.RowEndHierarchyId
这个例子,当然,使用递归公用表表达式来获得层次结构。该查询不是从树的根部开始,而是朝着树叶工作,而是采用相反的方法。这样做的好处是输出中的每一行都对应树中的一个叶节点。
但是,这种方法的性能可能仍然不理想,因为您没有机会对公共表表达式进行索引,其结果集可能非常大。假设tempdb具有足够的空间和性能,以下更详细的查询可能会提高性能。
CREATE TABLE #RowEnd
(
[RowEndHierarchyId] INT NOT NULL,
[HierarchyId] INT NOT NULL,
[ParentHierarchyId] INT NULL,
[Price] MONEY NOT NULL,
[DescriptionId] INT NULL,
[ReverseLevel] INT NOT NULL,
PRIMARY KEY ([RowEndHierarchyId], [ReverseLevel] DESC)
)
CREATE INDEX [IX_RowEnd_ParentHierarchyId] ON #RowEnd
([ParentHierarchyId], [RowEndHierarchyId], [ReverseLevel])
CREATE INDEX [IX_RowEnd_ReverseLevel] ON #RowEnd
([ReverseLevel] DESC, [ParentHierarchyId], [RowEndHierarchyId])
INSERT #RowEnd ([HierarchyId], [ParentHierarchyId], [Price], [DescriptionId], [RowEndHierarchyId], [ReverseLevel])
SELECT h.[HierarchyId], h.[ParentHierarchyId], h.[Price], h.[DescriptionId], h.[HierarchyId], 1
FROM [Hierarchy] h
WHERE NOT EXISTS (SELECT 1 FROM [Hierarchy] i WHERE i.ParentHierarchyId = h.[HierarchyId])
DECLARE @ReverseLevel INT
SET @ReverseLevel = 0
WHILE EXISTS (SELECT 1 FROM #RowEnd re WHERE re.ReverseLevel > @ReverseLevel)
BEGIN
SET @ReverseLevel = @ReverseLevel + 1
INSERT #RowEnd ([HierarchyId], [ParentHierarchyId], [Price], [DescriptionId], [RowEndHierarchyId], [ReverseLevel])
SELECT h.[HierarchyId], h.[ParentHierarchyId], h.[Price], h.[DescriptionId], re.[RowEndHierarchyId], @ReverseLevel + 1
FROM [Hierarchy] h
INNER JOIN #RowEnd re ON re.ParentHierarchyId = h.[HierarchyId] AND re.ReverseLevel = @ReverseLevel
END
CREATE TABLE #Price
(
RowEndHierarchyId INT NOT NULL PRIMARY KEY,
[1] MONEY NULL,
[2] MONEY NULL,
[3] MONEY NULL,
[4] MONEY NULL,
[5] MONEY NULL,
[6] MONEY NULL,
[7] MONEY NULL
)
INSERT #Price (RowEndHierarchyId, [1], [2], [3], [4], [5], [6], [7])
SELECT p.RowEndHierarchyId, p.[1], p.[2], p.[3], p.[4], p.[5], p.[6], p.[7]
FROM (SELECT re.RowEndHierarchyId, re.Price, RANK() OVER (PARTITION BY re.RowEndHierarchyId ORDER BY re.ReverseLevel DESC) AS [Level]
FROM #RowEnd re) ppre
PIVOT (MIN([Price]) FOR [Level] IN ([1], [2], [3], [4], [5], [6], [7])) p
CREATE TABLE #Description
(
RowEndHierarchyId INT NOT NULL PRIMARY KEY,
[1] NVARCHAR(50) NULL,
[2] NVARCHAR(50) NULL,
[3] NVARCHAR(50) NULL,
[4] NVARCHAR(50) NULL,
[5] NVARCHAR(50) NULL,
[6] NVARCHAR(50) NULL,
[7] NVARCHAR(50) NULL
)
INSERT #Description (RowEndHierarchyId, [1], [2], [3], [4], [5], [6], [7])
SELECT d.RowEndHierarchyId, d.[1], d.[2], d.[3], d.[4], d.[5], d.[6], d.[7]
FROM (SELECT re.RowEndHierarchyId, dt.DescriptionText, RANK() OVER (PARTITION BY re.RowEndHierarchyId ORDER BY re.ReverseLevel DESC) AS [Level]
FROM #RowEnd re
LEFT JOIN [Description] dt ON re.DescriptionId = dt.DescriptionId) dpre
PIVOT (MIN([DescriptionText]) FOR [Level] IN ([1], [2], [3], [4], [5], [6], [7])) d
SELECT p.RowEndHierarchyId,
p.[1] AS Price1, d.[1] AS Description1,
p.[2] AS Price2, d.[2] AS Description2,
p.[3] AS Price3, d.[3] AS Description3,
p.[4] AS Price4, d.[4] AS Description4,
p.[5] AS Price5, d.[5] AS Description5,
p.[6] AS Price6, d.[6] AS Description6,
p.[7] AS Price7, d.[7] AS Description7
FROM #Price p
INNER JOIN #Description d ON p.RowEndHierarchyId = d.RowEndHierarchyId
ORDER BY p.RowEndHierarchyId
DROP TABLE #Description
DROP TABLE #Price
DROP TABLE #RowEnd
获取层次结构的基本逻辑与先前的版本类似。但是,以这种方式为临时表建立索引可能会大大提高查询性能。
由于行数的原因,这需要很长时间。你真的需要把他们全部拿走吗? – DavidG 2014-10-20 08:23:10
首先推出查询计划,以便我们了解您是否错过索引等。然后描述您的硬件 - 像这样的东西在适当的中档服务器上并不那么困难,但对于小的东西 - 哎哟。 – TomTom 2014-10-20 08:36:19
尝试使用'CASE'表达式'WHEN A.Levels = 0',这样你只需要查询表格一次。你能提供一些DDL或SQLFiddle吗? – NickyvV 2014-10-20 08:46:01