ANL-CEEESA/MIPLearn
1
0
Fork 0
mirror of https://github.com/ANL-CEEESA/MIPLearn.git synced 2025-12-06 09:28:51 -06:00
Code Issues Packages Projects Releases Wiki Activity

Remove methods to set solver parameters

Browse Source
This commit is contained in:
Alinson S. Xavier
2021-01-19 21:38:01 -06:00
parent ffc77075f5
commit 185025e86c
5 changed files with 38 additions and 132 deletions
Download Patch File Download Diff File Expand all files Collapse all files

16
miplearn/solvers/gurobi.py
View File

@@ -315,22 +315,6 @@ class GurobiSolver(InternalSolver):
self._raise_if_callback()
logger.warning("set_branching_priorities not implemented")
def set_threads(self, threads):
self._raise_if_callback()
self.params["Threads"] = threads
def set_time_limit(self, time_limit):
self._raise_if_callback()
self.params["TimeLimit"] = time_limit
def set_node_limit(self, node_limit):
self._raise_if_callback()
self.params["NodeLimit"] = node_limit
def set_gap_tolerance(self, gap_tolerance):
self._raise_if_callback()
self.params["MIPGap"] = gap_tolerance
def _extract_warm_start_value(self, log):
ws = self.__extract(log, "MIP start with objective ([0-9.e+-]*)")
if ws is not None:

98
miplearn/solvers/internal.py
View File

@@ -36,6 +36,40 @@ class InternalSolver(ABC):
"""
pass
@abstractmethod
def solve(self, tee=False, iteration_cb=None, lazy_cb=None):
"""
Solves the currently loaded instance. After this method finishes,
the best solution found can be retrieved by calling `get_solution`.
Parameters
----------
iteration_cb: () -> Bool
By default, InternalSolver makes a single call to the native `solve`
method and returns the result. If an iteration callback is provided
instead, InternalSolver enters a loop, where `solve` and `iteration_cb`
are called alternatively. To stop the loop, `iteration_cb` should
return False. Any other result causes the solver to loop again.
lazy_cb: (internal_solver, model) -> None
This function is called whenever the solver finds a new candidate
solution and can be used to add lazy constraints to the model. Only
the following operations within the callback are allowed:
- Querying the value of a variable, through `get_value(var, idx)`
- Querying if a constraint is satisfied, through `is_constraint_satisfied(cobj)`
- Adding a new constraint to the problem, through `add_constraint`
Additional operations may be allowed by specific subclasses.
tee: Bool
If true, prints the solver log to the screen.
Returns
-------
dict
A dictionary of solver statistics containing the following keys:
"Lower bound", "Upper bound", "Wallclock time", "Nodes", "Sense",
"Log" and "Warm start value".
"""
pass
@abstractmethod
def get_solution(self):
"""
@@ -43,7 +77,7 @@ class InternalSolver(ABC):
If called after `solve`, returns the best primal solution found during
the search. If called after `solve_lp`, returns the optimal solution
to the LP relaxation.
to the LP relaxation. If no primal solution is available, return None.
The solution is a dictionary `sol`, where the optimal value of `var[idx]`
is given by `sol[var][idx]`.
@@ -62,13 +96,6 @@ class InternalSolver(ABC):
"""
pass
@abstractmethod
def clear_warm_start(self):
"""
Removes any existing warm start from the solver.
"""
pass
@abstractmethod
def set_instance(self, instance, model=None):
"""
@@ -76,7 +103,7 @@ class InternalSolver(ABC):
Parameters
----------
instance: miplearn.Instance
instance: Instance
The instance to be loaded.
model:
The concrete optimization model corresponding to this instance
@@ -118,40 +145,6 @@ class InternalSolver(ABC):
"""
pass
@abstractmethod
def solve(self, tee=False, iteration_cb=None, lazy_cb=None):
"""
Solves the currently loaded instance. After this method finishes,
the best solution found can be retrieved by calling `get_solution`.
Parameters
----------
iteration_cb: () -> Bool
By default, InternalSolver makes a single call to the native `solve`
method and returns the result. If an iteration callback is provided
instead, InternalSolver enters a loop, where `solve` and `iteration_cb`
are called alternatively. To stop the loop, `iteration_cb` should
return False. Any other result causes the solver to loop again.
lazy_cb: (internal_solver, model) -> None
This function is called whenever the solver finds a new candidate
solution and can be used to add lazy constraints to the model. Only
the following operations within the callback are allowed:
- Querying the value of a variable, through `get_value(var, idx)`
- Querying if a constraint is satisfied, through `is_constraint_satisfied(cobj)`
- Adding a new constraint to the problem, through `add_constraint`
Additional operations may be allowed by specific subclasses.
tee: Bool
If true, prints the solver log to the screen.
Returns
-------
dict
A dictionary of solver statistics containing the following keys:
"Lower bound", "Upper bound", "Wallclock time", "Nodes", "Sense",
"Log" and "Warm start value".
"""
pass
@abstractmethod
def get_value(self, var_name, index):
"""
@@ -206,7 +199,7 @@ class InternalSolver(ABC):
value of the dual variable associated with this constraint. If the model is infeasible,
returns a portion of the infeasibility certificate corresponding to the given constraint.
Solve must be called prior to this method.
Must be called after solve.
"""
pass
@@ -219,6 +212,7 @@ class InternalSolver(ABC):
@abstractmethod
def is_constraint_satisfied(self, cobj):
"""Returns True if the current solution satisfies the given constraint."""
pass
@abstractmethod
@@ -233,22 +227,6 @@ class InternalSolver(ABC):
def set_constraint_rhs(self, cid, rhs):
pass
@abstractmethod
def set_threads(self, threads):
pass
@abstractmethod
def set_time_limit(self, time_limit):
pass
@abstractmethod
def set_node_limit(self, node_limit):
pass
@abstractmethod
def set_gap_tolerance(self, gap_tolerance):
pass
@abstractmethod
def get_variables(self):
pass

32
miplearn/solvers/pyomo/base.py
View File

@@ -204,22 +204,6 @@ class BasePyomoSolver(InternalSolver):
def _extract_node_count(self, log):
return int(self.__extract(log, self._get_node_count_regexp(), default=1))
def set_threads(self, threads):
key = self._get_threads_option_name()
self._pyomo_solver.options[key] = threads
def set_time_limit(self, time_limit):
key = self._get_time_limit_option_name()
self._pyomo_solver.options[key] = time_limit
def set_node_limit(self, node_limit):
key = self._get_node_limit_option_name()
self._pyomo_solver.options[key] = node_limit
def set_gap_tolerance(self, gap_tolerance):
key = self._get_gap_tolerance_option_name()
self._pyomo_solver.options[key] = gap_tolerance
def get_constraint_ids(self):
return list(self._cname_to_constr.keys())
@@ -231,22 +215,6 @@ class BasePyomoSolver(InternalSolver):
def _get_node_count_regexp(self):
pass
@abstractmethod
def _get_threads_option_name(self):
pass
@abstractmethod
def _get_time_limit_option_name(self):
pass
@abstractmethod
def _get_node_limit_option_name(self):
pass
@abstractmethod
def _get_gap_tolerance_option_name(self):
pass
def extract_constraint(self, cid):
raise Exception("Not implemented")

12
miplearn/solvers/pyomo/cplex.py
View File

@@ -33,17 +33,5 @@ class CplexPyomoSolver(BasePyomoSolver):
def _get_node_count_regexp(self):
return "^[ *] *([0-9]+)"
def _get_threads_option_name(self):
return "threads"
def _get_time_limit_option_name(self):
return "timelimit"
def _get_node_limit_option_name(self):
return "mip_limits_nodes"
def _get_gap_tolerance_option_name(self):
return "mip_tolerances_mipgap"
def set_branching_priorities(self, priorities):
raise NotImplementedError

12
miplearn/solvers/pyomo/gurobi.py
View File

@@ -41,18 +41,6 @@ class GurobiPyomoSolver(BasePyomoSolver):
def _get_node_count_regexp(self):
return None
def _get_threads_option_name(self):
return "Threads"
def _get_time_limit_option_name(self):
return "TimeLimit"
def _get_node_limit_option_name(self):
return "NodeLimit"
def _get_gap_tolerance_option_name(self):
return "MIPGap"
def set_branching_priorities(self, priorities):
from gurobipy import GRB