Composite queries
Sometimes writing arbitrary SQL command is not enough. Especially, when the query accepts complex, user-provided search criteria.
Of course, the criteria changeability can be achieved with some smart combination of NULL checking and CASE WHEN:
select id, blogId, name, title, content, author, createdAt, modifiedAt, modifiedBy
where (@name is null or name like '%' + @name + '%')
and (@title is null or title like '%' + @title + '%')
and (@content is null or content like '%' + @content + '%')
order by case
when @order = 1 then createdAt
when @order = 2 then author
when @order = 3 then status
end
The ugly truth is, that whenever a @param is null or order by case is used, the query optimizer abandons use of indexes (at least when we use MS SQL).
Templating
With SqlFun, it’s easy to change the query with dynamic SQL generation, since the command is an ordinary string. It even provides simple templating module, based on ordinary string manipulation. A template is a string with placholders, denoted as names in double braces , e.g.:
let template = "select id, blogId, name, title, content, author, createdAt, modifiedAt, modifiedBy
from Post
{{WHERE-CLAUSE}}
{{ORDER-BY-CALUSE}}"
The expandTemplate placeholder clause separator value template function substitutes placeholder with some text, potentially more, than once, adding separators between substitutions and a clause before a first item, e.g:
let templateWithWhereExpanded =
template
|> expandTemplate "WHERE-CLAUSE" "where " " and " "author = @author"
|> expandTemplate "WHERE-CLAUSE" "where " " and " "createdAt >= @date"
The cleanupTemplate template function removes remaining placeholders from template, making it valid sql command:
let command = cleanupTemplate templateWithWhereExpanded
It’s a good habit to define some small templating DSL before implementing template transformations, e.g.:
let expandWhere = expandTemplate "WHERE-CLAUSE" "where " " and "
let expandOrderBy = expandTemplate "ORDER-BY-CLAUSE" "order by " ", "
It greatly improves conciseness and readibility:
let templateWithWhereExpanded = template |> expandWhere "author = @author" |> expandWhere "createdAt >= @date"
Records of options
With templates, we can generate queries with different number of parameters, depending on data provided, e.g. we can add conditions to the where clause only for parameters that are not None.
Simplest way of managing changeable parameter list is to define our search criteria as a record of options. It allows to take advantage of parameter matching by name (not positionally), e.g.:
type PostCriteria =
{
Title: string option
Content: string option
Author: string option
CreatedAfter: DateTime option
CreatedBefore: DateTime option
}
The sort order descriptor can be defined like this:
type SortDirection =
| Asc
| Desc
type SortColumn =
| Title
| CreationDate
| Author
type PostSortOrder = SortColumn * SortDirection
Now, we can generate a query from a template, adding parameters containing values:
let filterPosts (criteria: PostSearchCriteria list) template =
let template = if criteria.Title.IsSome
then template |> expandWhere "title like '%' + @title + '%'"
else template
let template = if criteria.Content.IsSome
then template |> expandWhere "content like '%' + @content + '%'"
else template
let template = if criteria.Author.IsSome
then template |> expandWhere "author = @author"
else template
let template = if criteria.CreatedBefore.IsSome
then template |> expandWhere "createdAt < @createdBefore"
else template
let template = if criteria.CreatedAfter.IsSome
then template |> expandWhere "createdAt > @createdAfter"
else template
template
let getOrderSql (col, dir) =
let name = match col with
| Title -> "title"
| CreationDate -> "createdAt"
| Author -> "author"
match dir with
| Asc -> name
| Desc -> name + " desc"
let sortPostsBy orders template =
if not (List.isEmpty orders) then
let cols = orders |> Seq.map getOrderSql |> String.concat ", "
template |> expandOrderBy cols
else
template
let findPosts (criteria: PostSearchCriteria list) (order: PostSortOrder) =
let template = "select p.id, p.blogId, p.name, p.title, p.content,
p.author, p.createdAt, p.modifiedAt, p.modifiedBy, p.status
from post p
{{WHERE-CLAUSE}}
{{ORDER-BY-CLAUSE}}"
let query = template |> filterPosts criteria |> sortPostsBy order |> cleanupTemplate
buildAndMemoizeQuery sql query criteria
Query Parts
There is also another mechanism of composition, based on recursive function type definition. The composition blocks are classes implementing following interface:
type IQueryPart<'t> =
abstract member Combine: 't-> 'q
and, since the string type is the most obvious template type:
type IQueryPart = IQueryPart<string>
where the parameter is a query template and return value is a query function. The whole point is to define Combine method:
type FilterByName(string name, next: IQueryPart) =
interface IQueryPart with
override this.Combine (template: string) : 't =
let exp = template |> expandTemplate "WHERE-CLAUSE" "where " " and " "name like '%' + @name + '%'"
let f = this.Combine<string -> 't> exp
f name
by passing to next query part modified command template and modified function type, i.e. with additional parameter, then applying provided parameter value to returned function.
The last query part in a chain should be an object of the FinalQueryPart, that generates needed function and caches it.
The expandTemplate placeholder clause separator value function, used in the example above, allows to incrementally replace `` pattern in template with a value, adding a specified clause and separators when needed.
Although it’s possible to implement each query part by implementing the interface, SqlFun offers some built-in, generic parts:
TransformWithValueQueryPart<'t>(expand, value)allows to specify transformations that add single parameters,TransformWithValueListQueryPart<'t>(expand, valueList)allows to specify transformations that add multiple parameters basing on lists of valuesTransformWithTextQueryPartallows to specify transformations that expand query template without adding any parameters
where expand is a query template expansion function of type string -> string.
Additionally there are functions transformWithValue, transformWithValueList and transformWithText, that build subsequent query parts, wrapped in AsyncDb.
At first sight, this technique needs a lot of boilerplate. But it is not about ad-hoc querying, it’s about building query DSL-s, that need more effort. If we apply it to five parameters, using list of discriminated unions, it starts to make much more sense:
type PostCriteria =
| TitleContains of string
| ContentContains of string
| AuthorIs of string
| CreatedAfter of DateTime
| CreatedBefore of DateTime
let rec filterPosts(criteria: PostCriteria list) (next: AsyncDb<IQueryPart>) =
match criteria with
| (TitleContains title) :: others ->
let intermediate = filterPosts others next
transformWithValue (expandWhere "title like '%' + @title + '%'") title intermediate
| (ContentContains content) :: others ->
let intermediate = filterPosts others next
transformWithValue (expandWhere "content like '%' + @content + '%'") content intermediate
| (AuthorIs author) :: others ->
let intermediate = filterPosts others next
transformWithValue (expandWhere "author = @author") author intermediate
| (CreatedAfter date) :: others ->
let intermediate = filterPosts others next
transformWithValue (expandWhere "createdAt >= @date") date intermediate
| (CreatedBefore date) :: others ->
let intermediate = filterPosts others next
transformWithValue (expandWhere "createdAt <= @date") date intermediate
| [] ->
next
Composing with another query parts is fairly easy. Let’s define query part for sorting posts
type SortDirection =
| Asc
| Desc
type SortColumn =
| Title
| CreationDate
| Author
type PostSortOrder = SortColumn * SortDirection
let getOrderSql (col, dir) =
let name = match col with
| Title -> "title"
| CreationDate -> "createdAt"
| Author -> "author"
match dir with
| Asc -> name
| Desc -> name + " desc"
let sortPostsBy orders next =
if not (List.isEmpty orders)
then
let cols = orders |> Seq.map getOrderSql |> String.concat ", "
transformWithText (expandOrderBy cols) next
else
next
Before we can use the FinalQueryPart class, we have to bind query generation config to it:
let createConnection () = new SqlConnection(connectionString)
let generatorConfig = createDefaultConfig createConnection
let buildQuery ctx = async {
FinalQueryPart(ctx, generatorConfig, cleanUpTemplate)
}
The last step is to specify SQL template:
let selectPosts (next: QueryPart): Post list =
next |> withTemplate "select p.id, p.blogId, p.name, p.title, p.content,
p.author, p.createdAt, p.modifiedAt, p.modifiedBy, p.status
from post p
{{WHERE-CLAUSE}}
{{ORDER-BY-CLAUSE}}"
And then, we can compose parts:
let findPosts (criteria: PostSearchCriteria list) (orders: PostSortOrder list) =
buildQuery
|> filterPosts criteria
|> sortPostsBy orders
|> selectPosts
Or without sorting:
let findPosts (criteria: PostSearchCriteria list) =
buildQuery
|> filterPosts criteria
|> selectPosts
Query parts and it’s creation functions allow for many approaches to define query DSL. One can build a DSL as a set of small functions, that can be composed with |> operator, another one can define one big function, that consumes list of discriminated union values (like in example above), yet another can define simple record with optional values instead of discriminated union.
The downside of composite queries is, that they are not generated during module initialization, but during their first use, and as such, they don’t participate in usual SqlFun type safety mechanisms. Thus, each of them should have it’s own tests defined. I recommend to use FsCheck for comprehensive query DSL testing.