This module defines simple to use predicates for running goals concurrently. Where the core multi-threaded API is targeted at communicating long-living threads, the predicates here are defined to run goals concurrently without having to deal with thread creation and maintenance explicitely.
Note that these predicates run goals concurrently and therefore these goals need to be thread-safe. As the predicates in this module also abort branches of the computation that are no longer needed, predicates that have side-effect must act properly. In a nutshell, this has the following consequences:
Execution succeeds if all goals have succeeded. If one goal fails or throws an exception, other workers are abandoned as soon as possible and the entire computation fails or re-throws the exception. Note that if multiple goals fail or raise an error it is not defined which error or failure is reported.
On successful completion, variable bindings are returned. Note however that threads have independent stacks and therefore the goal is copied to the worker thread and the result is copied back to the caller of concurrent/3.
Choosing the right number of threads is not always obvious. Here are some scenarios:
goal(Id, Goal, Vars)
. Vars is unified with a list of
lists of free variables appearing in each goal.true
, signal all workers to make them stop prematurely. If
result is true we assume all workers have been instructed to
stop or have stopped themselves.cpu_count
.(Generator,Test)
. This predicate creates a
thread providing solutions for Generator that are handed to a pool
of threads that run Test for the different instantiations provided
by Generator concurrently. The predicate is logically equivalent to
a simple conjunction except for two aspects: (1) terms are copied
from Generator to the test Test threads while answers are copied
back to the calling thread and (2) answers may be produced out of
order.
If the evaluation of some Test raises an exception, concurrent_and/2,3 is terminated with this exception. If the caller commits after a given answer or raises an exception while concurrent_and/2,3 is active with pending choice points, all involved resources are reclaimed.
Options:
cpu_count
.
This predicate was proposed by Jan Burse as
balance((Generator,Test))
.
cpu_count
. If
this flag is absent or 1 or List has less than two elements, this
predicate calls the corresponding maplist/N version using a wrapper
based on once/1. Note that all goals are executed as if wrapped in
once/1 and therefore these predicates are semidet.
Note that the the overhead of this predicate is considerable and therefore Goal must be fairly expensive before one reaches a speedup.
For example, if it is unclear whether it is better to search a graph breadth-first or depth-first we can use:
search_graph(Grap, Path) :- first_solution(Path, [ breadth_first(Graph, Path), depth_first(Graph, Path) ], []).
Options include thread stack-sizes passed to thread_create, as
well as the options on_fail
and on_error
that specify what
to do if a solver fails or triggers an error. By default
execution of all solvers is terminated and the result is
returned. Sometimes one may wish to continue. One such scenario
is if one of the solvers may run out of resources or one of the
solvers is known to be incomplete.
stop
(default), terminate all threads and stop with
the failure. If continue
, keep waiting.thread(-size)
options and other
options.stop(Reason)
exception into Goal. Interrupts can be nested, i.e., it is allowed
to run a call_in_thread/2 while the target thread is processing such
an interrupt.
This predicate is primarily intended for debugging and inspection tasks.
The following predicates are exported from this file while their implementation is defined in imported modules or non-module files loaded by this module.
(Generator,Test)
. This predicate creates a
thread providing solutions for Generator that are handed to a pool
of threads that run Test for the different instantiations provided
by Generator concurrently. The predicate is logically equivalent to
a simple conjunction except for two aspects: (1) terms are copied
from Generator to the test Test threads while answers are copied
back to the calling thread and (2) answers may be produced out of
order.
If the evaluation of some Test raises an exception, concurrent_and/2,3 is terminated with this exception. If the caller commits after a given answer or raises an exception while concurrent_and/2,3 is active with pending choice points, all involved resources are reclaimed.
Options:
cpu_count
.
This predicate was proposed by Jan Burse as
balance((Generator,Test))
.
cpu_count
. If
this flag is absent or 1 or List has less than two elements, this
predicate calls the corresponding maplist/N version using a wrapper
based on once/1. Note that all goals are executed as if wrapped in
once/1 and therefore these predicates are semidet.
Note that the the overhead of this predicate is considerable and therefore Goal must be fairly expensive before one reaches a speedup.
cpu_count
.cpu_count
. If
this flag is absent or 1 or List has less than two elements, this
predicate calls the corresponding maplist/N version using a wrapper
based on once/1. Note that all goals are executed as if wrapped in
once/1 and therefore these predicates are semidet.
Note that the the overhead of this predicate is considerable and therefore Goal must be fairly expensive before one reaches a speedup.