Namespace for functions that plan queries
Namespace for functions that plan queries
(aggregate-constraint aggregating? needed-vars aggregate-vars constraint)
Inputs: [aggregating? :- s/Bool needed-vars :- #{Var} aggregate-vars :- #{VarOrWild} constraint :- Pattern] Returns: (s/maybe Pattern)
Returns a constraint when it does or does not contains aggregates, selected by the aggregating? flag. For a compound constraint (and, or, not) then returns all non-empty elements that contain or do-not-contain aggregate vars.
Inputs: [aggregating? :- s/Bool needed-vars :- #{Var} aggregate-vars :- #{VarOrWild} constraint :- Pattern] Returns: (s/maybe Pattern) Returns a constraint when it does or does not contains aggregates, selected by the aggregating? flag. For a compound constraint (and, or, not) then returns all non-empty elements that contain or do-not-contain aggregate vars.
(aggregate-form? s)
Determines if a term is an aggregate. Also detects if a wildcard is used for anything that isn't count
Determines if a term is an aggregate. Also detects if a wildcard is used for anything that isn't count
(append s e)
Inputs: [s e]
Appends a single element to the end of a seq
Inputs: [s e] Appends a single element to the end of a seq
(bindings-chain evs bound-vars patterns)
Inputs: [evs :- [EvalPattern] bound-vars :- #{Var} patterns :- [EPVPattern]] Returns: (s/maybe [(s/one [EvalPattern] "eval-patterns that can be used to bind a pattern") (s/one [EvalPattern] "eval-patterns that cannot be used to bind a pattern")])
This is a helper function for first-group. When first-group has found a set of patterns that share vars with each other, this will look for any eval-patterns (binding through evaluation) which, if added, would allow even more patterns to be added to the group. So if we had: [?a :prop ?b] [?a :attr ?c] [(inc ?c) ?d] [(str ?b "-" ?d) ?e] [(dec ?c) ?f] [?x :label ?e] [?y :included true] Then first-group would find the first 2 patterns, which would bind: #{?a ?b ?c} This function is then called, with: evs = [[(inc ?c) ?d] [(str ?b "-" ?d) ?e] [(dec ?c) ?f]] bound-vars = #{?a ?b ?c} patterns = [[?x :label ?e] [?y :included true]] It will identify that [?x :label ?e] can be included if the first 2 evaluations are used, since they can be used to bind ?e. The result will be a split of the bindings that can be used to match a pattern, and the bindings which cannot: [ [[(inc ?c) ?d] [(str ?b "-" ?d) ?e]] , [[(dec ?c) ?f]] ] The loop in first-group will then use this result to pull in all possible patterns.
Finds all bindings will can be used to connect unused patterns to a group. Returns a pair: Bindings that can be used to connect patterns to the current group / Remaining bindings evs: eval patterns that are available to use bound-vars: the vars that have been bound for the current group patterns: the patterns that aren't used in any groups yet
Inputs: [evs :- [EvalPattern] bound-vars :- #{Var} patterns :- [EPVPattern]] Returns: (s/maybe [(s/one [EvalPattern] "eval-patterns that can be used to bind a pattern") (s/one [EvalPattern] "eval-patterns that cannot be used to bind a pattern")]) This is a helper function for first-group. When first-group has found a set of patterns that share vars with each other, this will look for any eval-patterns (binding through evaluation) which, if added, would allow even more patterns to be added to the group. So if we had: [?a :prop ?b] [?a :attr ?c] [(inc ?c) ?d] [(str ?b "-" ?d) ?e] [(dec ?c) ?f] [?x :label ?e] [?y :included true] Then first-group would find the first 2 patterns, which would bind: #{?a ?b ?c} This function is then called, with: evs = [[(inc ?c) ?d] [(str ?b "-" ?d) ?e] [(dec ?c) ?f]] bound-vars = #{?a ?b ?c} patterns = [[?x :label ?e] [?y :included true]] It will identify that [?x :label ?e] can be included if the first 2 evaluations are used, since they can be used to bind ?e. The result will be a split of the bindings that can be used to match a pattern, and the bindings which cannot: [ [[(inc ?c) ?d] [(str ?b "-" ?d) ?e]] , [[(dec ?c) ?f]] ] The loop in first-group will then use this result to pull in all possible patterns. Finds all bindings will can be used to connect unused patterns to a group. Returns a pair: Bindings that can be used to connect patterns to the current group / Remaining bindings evs: eval patterns that are available to use bound-vars: the vars that have been bound for the current group patterns: the patterns that aren't used in any groups yet
(estimated-counts count-map path)
Inputs: [count-map :- {CountablePattern s/Num} path :- [CountablePattern]] Returns: [s/Num]
Return list of ordered counts for the patterns. This skips the eval-patterns. It also attaches meta-data to indicate if a path can short circuit comparisons.
Inputs: [count-map :- {CountablePattern s/Num} path :- [CountablePattern]] Returns: [s/Num] Return list of ordered counts for the patterns. This skips the eval-patterns. It also attaches meta-data to indicate if a path can short circuit comparisons.
(extract-patterns-by-type patterns)
Inputs: [patterns :- [PatternOrBindings]] Returns: #:s{Keyword [PatternOrBindings]}
Categorizes elements of a WHERE clause, returning a keyword map
Inputs: [patterns :- [PatternOrBindings]] Returns: #:s{Keyword [PatternOrBindings]} Categorizes elements of a WHERE clause, returning a keyword map
(find-first count-map [first-path & all-paths])
Inputs: [count-map :- {CountablePattern s/Num} [first-path & all-paths] :- CountablePattern
]
Returns: [CountablePattern]
Finds a min (or approximate minimum) path
Inputs: [count-map :- {CountablePattern s/Num} [first-path & all-paths] :- [[CountablePattern]]] Returns: [CountablePattern] Finds a min (or approximate minimum) path
(find-start pattern-counts patterns)
Inputs: [pattern-counts :- {CountablePattern s/Num} patterns :- [CountablePattern]] Returns: (s/maybe CountablePattern)
Returns the first pattern with the smallest count
Inputs: [pattern-counts :- {CountablePattern s/Num} patterns :- [CountablePattern]] Returns: (s/maybe CountablePattern) Returns the first pattern with the smallest count
Queries are often executed multiple times. Memoizing first-group* allows the optimizer to avoid redundant work.
Queries are often executed multiple times. Memoizing first-group* allows the optimizer to avoid redundant work.
(first-group* bound patterns eval-patterns)
Inputs: [bound :- (s/maybe #{Var}) patterns :- [CountablePattern] eval-patterns :- [EvalPattern]] Returns: [(s/one [CountablePattern] "group") (s/one [CountablePattern] "remainder") (s/one [EvalPattern] "unused eval bindings")]
Finds a group from a sequence of patterns. A group is defined by every pattern sharing at least one var with at least one other pattern. This is done to group patterns by those which can be joined with inner joins. Groups do not share variables, so a join from a group to any pattern in a different group will be an outer join. The optimizer has to work on one group at a time. For the following query: [?a :prop ?b] [?a :attr ?c] [(inc ?c) ?d] [(str ?b "-" ?d) ?e] [(dec ?c) ?f] [?x :label ?e] [?y :included true] All patterns except the last one are in the same group. Returns a pair. The first returned element is the Patterns in the group, the second is what was left over. This remainder contains all the patterns that appear in other groups. The function can be called again on the remainder.
Inputs: [bound :- (s/maybe #{Var}) patterns :- [CountablePattern] eval-patterns :- [EvalPattern]] Returns: [(s/one [CountablePattern] "group") (s/one [CountablePattern] "remainder") (s/one [EvalPattern] "unused eval bindings")] Finds a group from a sequence of patterns. A group is defined by every pattern sharing at least one var with at least one other pattern. This is done to group patterns by those which can be joined with inner joins. Groups do not share variables, so a join from a group to any pattern in a different group will be an outer join. The optimizer has to work on one group at a time. For the following query: [?a :prop ?b] [?a :attr ?c] [(inc ?c) ?d] [(str ?b "-" ?d) ?e] [(dec ?c) ?f] [?x :label ?e] [?y :included true] All patterns except the last one are in the same group. Returns a pair. The first returned element is the Patterns in the group, the second is what was left over. This remainder contains all the patterns that appear in other groups. The function can be called again on the remainder.
(get-vars this)
Returns the vars for the object
Returns the vars for the object
(merge-operations graph
options
planned-patterns
general-patterns
filter-patterns
opt-patterns
not-patterns)
Inputs: [graph options planned-patterns general-patterns filter-patterns opt-patterns not-patterns]
Merges filters and NOT operations into the sequence of patterns, so that they appear as soon as all their variables are first bound. By pushing filters as far to the front as possible, it minimizes the work of subsequent joins. TODO: if not-patterns relies on the output of an eval-pattern, then the eval can be pushed further ahead in the path. This should happen before this merge is called.
Inputs: [graph options planned-patterns general-patterns filter-patterns opt-patterns not-patterns] Merges filters and NOT operations into the sequence of patterns, so that they appear as soon as all their variables are first bound. By pushing filters as far to the front as possible, it minimizes the work of subsequent joins. TODO: if not-patterns relies on the output of an eval-pattern, then the eval can be pushed further ahead in the path. This should happen before this merge is called.
(min-join-path bound count-map patterns eval-patterns)
Inputs: [bound :- (s/maybe #{Var}) count-map :- {CountablePattern s/Num} patterns :- [CountablePattern] eval-patterns :- [EvalPattern]] Returns: [CountablePattern]
Calculates a plan based on no outer joins (a cross product), and minimized joins. A plan is the order in which to evaluate constraints and join them to the accumulated evaluated data. If it is not possible to create a path without a cross product, then return a plan which is a concatenation of all inner-product groups, where the groups are all ordered by minimized joins.
Inputs: [bound :- (s/maybe #{Var}) count-map :- {CountablePattern s/Num} patterns :- [CountablePattern] eval-patterns :- [EvalPattern]] Returns: [CountablePattern] Calculates a plan based on no outer joins (a cross product), and minimized joins. A plan is the order in which to evaluate constraints and join them to the accumulated evaluated data. If it is not possible to create a path without a cross product, then return a plan which is a concatenation of all inner-product groups, where the groups are all ordered by minimized joins.
(minimal-first-planner graph patterns options)
Inputs: [graph patterns :- [PatternOrBindings] options] Returns: [PatternOrBindings]
Attempts to optimize a query, based on the principle that if smaller resolutions appear first in a product term, then lazy evaluation will lead to less iteration on the later terms. This is not always true, but is in the general case.
Inputs: [graph patterns :- [PatternOrBindings] options] Returns: [PatternOrBindings] Attempts to optimize a query, based on the principle that if smaller resolutions appear first in a product term, then lazy evaluation will lead to less iteration on the later terms. This is not always true, but is in the general case.
(nested-seq? s)
Test for Bindings, which can be [] or [[value] [value]...]
Test for Bindings, which can be [] or [[value] [value]...]
(new-and terms)
Inputs: [terms]
Create an AND expression from a sequence of arguments. If an argument is a nested AND, then these terms are flattened into this level.
Inputs: [terms] Create an AND expression from a sequence of arguments. If an argument is a nested AND, then these terms are flattened into this level.
(new-or terms)
Inputs: [terms]
Create an OR expression from a sequence of arguments. If an argument is a nested OR, then these terms are flattened into this level. If an argument is a NOT, then an exception is thrown.
Inputs: [terms] Create an OR expression from a sequence of arguments. If an argument is a nested OR, then these terms are flattened into this level. If an argument is a NOT, then an exception is thrown.
(normalize-sum-of-products patterns)
Inputs: [patterns]
Converts an expression that is not a sum into a sum operation of one argument.
Inputs: [patterns] Converts an expression that is not a sum into a sum operation of one argument.
Returns true if a pattern is a NOT operation
Returns true if a pattern is a NOT operation
Returns true if a pattern is a NOT operation
Returns true if a pattern is a NOT operation
(opt-type? types pattern)
Inputs: [types :- #{s/Symbol} pattern :- PatternOrBindings] Returns: s/Bool
Returns true if a pattern is a given operation type
Inputs: [types :- #{s/Symbol} pattern :- PatternOrBindings] Returns: s/Bool Returns true if a pattern is a given operation type
(order patterns)
Inputs: [patterns :- [EvalPattern]] Returns: [EvalPattern]
Takes a sequence of Evaluation binding patterns and returns them in an internally consistent order
Inputs: [patterns :- [EvalPattern]] Returns: [EvalPattern] Takes a sequence of Evaluation binding patterns and returns them in an internally consistent order
(path prebound patterns pattern-counts eval-patterns)
Inputs: [prebound :- (s/maybe #{Var}) patterns :- [CountablePattern] pattern-counts :- {CountablePattern s/Num} eval-patterns :- [EvalPattern]] Returns: [CountablePattern]
Returns an efficient path through the constraints. A path is defined by new patterns containing at least one variable common to the patterns that appeared before it. Patterns must form a group.
Inputs: [prebound :- (s/maybe #{Var}) patterns :- [CountablePattern] pattern-counts :- {CountablePattern s/Num} eval-patterns :- [EvalPattern]] Returns: [CountablePattern] Returns an efficient path through the constraints. A path is defined by new patterns containing at least one variable common to the patterns that appeared before it. Patterns must form a group.
(plan-path graph patterns options)
Inputs: [graph patterns :- [PatternOrBindings] options] Returns: [PatternOrBindings]
Determines the order in which to perform the elements that go into a query. Tries to optimize, so it uses the graph to determine some of the properties of the query elements. Options can describe which planner to use. Planning will determine the resolution map, and this is returned with the plan. By default the min-join-path function is used. This can be overriden with options: [:planner plan] The plan can be one of :user, :min. :min is the default. :user means to execute in provided order.
Inputs: [graph patterns :- [PatternOrBindings] options] Returns: [PatternOrBindings] Determines the order in which to perform the elements that go into a query. Tries to optimize, so it uses the graph to determine some of the properties of the query elements. Options can describe which planner to use. Planning will determine the resolution map, and this is returned with the plan. By default the min-join-path function is used. This can be overriden with options: [:planner plan] The plan can be one of :user, :min. :min is the default. :user means to execute in provided order.
(simplify-algebra patterns)
(simplify-algebra patterns options)
(simplify-algebra G__34430)
(simplify-algebra G__34434 G__34435)
Inputs: ([patterns :- [PatternOrBindings]] [patterns :- [PatternOrBindings] options]) Returns: [PatternOrBindings]
This operation simplifies the algebra into a sum-of-products form.
Inputs: ([patterns :- [PatternOrBindings]] [patterns :- [PatternOrBindings] options]) Returns: [PatternOrBindings] This operation simplifies the algebra into a sum-of-products form.
(split-aggregate-terms constraints selection withs)
Inputs: [constraints :- Pattern selection :- [FindElement] withs :- [Var]] Returns: [(s/one [s/Any] "outer query constraints") (s/one [s/Any] "inner query constraints") (s/one #{VarOrWild} "vars to get aggregations for")]
Splits a WHERE clause up into the part suitable for an outer query, and the remaining constraints, which will be used for an inner query.
Inputs: [constraints :- Pattern selection :- [FindElement] withs :- [Var]] Returns: [(s/one [s/Any] "outer query constraints") (s/one [s/Any] "inner query constraints") (s/one #{VarOrWild} "vars to get aggregations for")] Splits a WHERE clause up into the part suitable for an outer query, and the remaining constraints, which will be used for an inner query.
(user-plan graph patterns options)
Inputs: [graph patterns :- [PatternOrBindings] options] Returns: [CountablePattern]
Returns the original order of patterns specified by the user. No optimization is attempted.
Inputs: [graph patterns :- [PatternOrBindings] options] Returns: [CountablePattern] Returns the original order of patterns specified by the user. No optimization is attempted.
(without e s)
Inputs: [e :- s/Any s :- [s/Any]] Returns: [s/Any]
Returns a sequence minus a specific element
Inputs: [e :- s/Any s :- [s/Any]] Returns: [s/Any] Returns a sequence minus a specific element
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