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<article id="content">
<header>
<h1 class="title">Module <code>miplearn.instance</code></h1>
</header>
<section id="section-intro">
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python"># MIPLearn: Extensible Framework for Learning-Enhanced Mixed-Integer Optimization
# Copyright (C) 2020, UChicago Argonne, LLC. All rights reserved.
# Released under the modified BSD license. See COPYING.md for more details.
import gzip
import json
from abc import ABC, abstractmethod
from typing import Any, List
import numpy as np
from miplearn.types import TrainingSample
class Instance(ABC):
&#34;&#34;&#34;
Abstract class holding all the data necessary to generate a concrete model of the
problem.
In the knapsack problem, for example, this class could hold the number of items,
their weights and costs, as well as the size of the knapsack. Objects
implementing this class are able to convert themselves into a concrete
optimization model, which can be optimized by a solver, or into arrays of
features, which can be provided as inputs to machine learning models.
&#34;&#34;&#34;
def __init__(self):
self.training_data: List[TrainingSample] = []
@abstractmethod
def to_model(self) -&gt; Any:
&#34;&#34;&#34;
Returns the optimization model corresponding to this instance.
&#34;&#34;&#34;
pass
def get_instance_features(self):
&#34;&#34;&#34;
Returns a 1-dimensional Numpy array of (numerical) features describing the
entire instance.
The array is used by LearningSolver to determine how similar two instances
are. It may also be used to predict, in combination with variable-specific
features, the values of binary decision variables in the problem.
There is not necessarily a one-to-one correspondence between models and
instance features: the features may encode only part of the data necessary to
generate the complete model. Features may also be statistics computed from
the original data. For example, in the knapsack problem, an implementation
may decide to provide as instance features only the average weights, average
prices, number of items and the size of the knapsack.
The returned array MUST have the same length for all relevant instances of
the problem. If two instances map into arrays of different lengths,
they cannot be solved by the same LearningSolver object.
By default, returns [0].
&#34;&#34;&#34;
return np.zeros(1)
def get_variable_features(self, var, index):
&#34;&#34;&#34;
Returns a 1-dimensional array of (numerical) features describing a particular
decision variable.
The argument `var` is a pyomo.core.Var object, which represents a collection
of decision variables. The argument `index` specifies which variable in the
collection is the relevant one.
In combination with instance features, variable features are used by
LearningSolver to predict, among other things, the optimal value of each
decision variable before the optimization takes place. In the knapsack
problem, for example, an implementation could provide as variable features
the weight and the price of a specific item.
Like instance features, the arrays returned by this method MUST have the same
length for all variables within the same category, for all relevant instances
of the problem.
By default, returns [0].
&#34;&#34;&#34;
return np.zeros(1)
def get_variable_category(self, var, index):
&#34;&#34;&#34;
Returns the category (a string, an integer or any hashable type) for each
decision variable.
If two variables have the same category, LearningSolver will use the same
internal ML model to predict the values of both variables. If the returned
category is None, ML models will ignore the variable.
By default, returns &#34;default&#34;.
&#34;&#34;&#34;
return &#34;default&#34;
def get_constraint_features(self, cid):
return np.zeros(1)
def get_constraint_category(self, cid):
return cid
def has_static_lazy_constraints(self):
return False
def has_dynamic_lazy_constraints(self):
return False
def is_constraint_lazy(self, cid):
return False
def find_violated_lazy_constraints(self, model):
&#34;&#34;&#34;
Returns lazy constraint violations found for the current solution.
After solving a model, LearningSolver will ask the instance to identify which
lazy constraints are violated by the current solution. For each identified
violation, LearningSolver will then call the build_lazy_constraint, add the
generated Pyomo constraint to the model, then resolve the problem. The
process repeats until no further lazy constraint violations are found.
Each &#34;violation&#34; is simply a string, a tuple or any other hashable type which
allows the instance to identify unambiguously which lazy constraint should be
generated. In the Traveling Salesman Problem, for example, a subtour
violation could be a frozen set containing the cities in the subtour.
For a concrete example, see TravelingSalesmanInstance.
&#34;&#34;&#34;
return []
def build_lazy_constraint(self, model, violation):
&#34;&#34;&#34;
Returns a Pyomo constraint which fixes a given violation.
This method is typically called immediately after
find_violated_lazy_constraints. The violation object provided to this method
is exactly the same object returned earlier by
find_violated_lazy_constraints. After some training, LearningSolver may
decide to proactively build some lazy constraints at the beginning of the
optimization process, before a solution is even available. In this case,
build_lazy_constraints will be called without a corresponding call to
find_violated_lazy_constraints.
The implementation should not directly add the constraint to the model. The
constraint will be added by LearningSolver after the method returns.
For a concrete example, see TravelingSalesmanInstance.
&#34;&#34;&#34;
pass
def find_violated_user_cuts(self, model):
return []
def build_user_cut(self, model, violation):
pass
def load(self, filename):
with gzip.GzipFile(filename, &#34;r&#34;) as f:
data = json.loads(f.read().decode(&#34;utf-8&#34;))
self.__dict__ = data
def dump(self, filename):
data = json.dumps(self.__dict__, indent=2).encode(&#34;utf-8&#34;)
with gzip.GzipFile(filename, &#34;w&#34;) as f:
f.write(data)</code></pre>
</details>
</section>
<section>
</section>
<section>
</section>
<section>
</section>
<section>
<h2 class="section-title" id="header-classes">Classes</h2>
<dl>
<dt id="miplearn.instance.Instance"><code class="flex name class">
<span>class <span class="ident">Instance</span></span>
</code></dt>
<dd>
<section class="desc"><p>Abstract class holding all the data necessary to generate a concrete model of the
problem.</p>
<p>In the knapsack problem, for example, this class could hold the number of items,
their weights and costs, as well as the size of the knapsack. Objects
implementing this class are able to convert themselves into a concrete
optimization model, which can be optimized by a solver, or into arrays of
features, which can be provided as inputs to machine learning models.</p></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">class Instance(ABC):
&#34;&#34;&#34;
Abstract class holding all the data necessary to generate a concrete model of the
problem.
In the knapsack problem, for example, this class could hold the number of items,
their weights and costs, as well as the size of the knapsack. Objects
implementing this class are able to convert themselves into a concrete
optimization model, which can be optimized by a solver, or into arrays of
features, which can be provided as inputs to machine learning models.
&#34;&#34;&#34;
def __init__(self):
self.training_data: List[TrainingSample] = []
@abstractmethod
def to_model(self) -&gt; Any:
&#34;&#34;&#34;
Returns the optimization model corresponding to this instance.
&#34;&#34;&#34;
pass
def get_instance_features(self):
&#34;&#34;&#34;
Returns a 1-dimensional Numpy array of (numerical) features describing the
entire instance.
The array is used by LearningSolver to determine how similar two instances
are. It may also be used to predict, in combination with variable-specific
features, the values of binary decision variables in the problem.
There is not necessarily a one-to-one correspondence between models and
instance features: the features may encode only part of the data necessary to
generate the complete model. Features may also be statistics computed from
the original data. For example, in the knapsack problem, an implementation
may decide to provide as instance features only the average weights, average
prices, number of items and the size of the knapsack.
The returned array MUST have the same length for all relevant instances of
the problem. If two instances map into arrays of different lengths,
they cannot be solved by the same LearningSolver object.
By default, returns [0].
&#34;&#34;&#34;
return np.zeros(1)
def get_variable_features(self, var, index):
&#34;&#34;&#34;
Returns a 1-dimensional array of (numerical) features describing a particular
decision variable.
The argument `var` is a pyomo.core.Var object, which represents a collection
of decision variables. The argument `index` specifies which variable in the
collection is the relevant one.
In combination with instance features, variable features are used by
LearningSolver to predict, among other things, the optimal value of each
decision variable before the optimization takes place. In the knapsack
problem, for example, an implementation could provide as variable features
the weight and the price of a specific item.
Like instance features, the arrays returned by this method MUST have the same
length for all variables within the same category, for all relevant instances
of the problem.
By default, returns [0].
&#34;&#34;&#34;
return np.zeros(1)
def get_variable_category(self, var, index):
&#34;&#34;&#34;
Returns the category (a string, an integer or any hashable type) for each
decision variable.
If two variables have the same category, LearningSolver will use the same
internal ML model to predict the values of both variables. If the returned
category is None, ML models will ignore the variable.
By default, returns &#34;default&#34;.
&#34;&#34;&#34;
return &#34;default&#34;
def get_constraint_features(self, cid):
return np.zeros(1)
def get_constraint_category(self, cid):
return cid
def has_static_lazy_constraints(self):
return False
def has_dynamic_lazy_constraints(self):
return False
def is_constraint_lazy(self, cid):
return False
def find_violated_lazy_constraints(self, model):
&#34;&#34;&#34;
Returns lazy constraint violations found for the current solution.
After solving a model, LearningSolver will ask the instance to identify which
lazy constraints are violated by the current solution. For each identified
violation, LearningSolver will then call the build_lazy_constraint, add the
generated Pyomo constraint to the model, then resolve the problem. The
process repeats until no further lazy constraint violations are found.
Each &#34;violation&#34; is simply a string, a tuple or any other hashable type which
allows the instance to identify unambiguously which lazy constraint should be
generated. In the Traveling Salesman Problem, for example, a subtour
violation could be a frozen set containing the cities in the subtour.
For a concrete example, see TravelingSalesmanInstance.
&#34;&#34;&#34;
return []
def build_lazy_constraint(self, model, violation):
&#34;&#34;&#34;
Returns a Pyomo constraint which fixes a given violation.
This method is typically called immediately after
find_violated_lazy_constraints. The violation object provided to this method
is exactly the same object returned earlier by
find_violated_lazy_constraints. After some training, LearningSolver may
decide to proactively build some lazy constraints at the beginning of the
optimization process, before a solution is even available. In this case,
build_lazy_constraints will be called without a corresponding call to
find_violated_lazy_constraints.
The implementation should not directly add the constraint to the model. The
constraint will be added by LearningSolver after the method returns.
For a concrete example, see TravelingSalesmanInstance.
&#34;&#34;&#34;
pass
def find_violated_user_cuts(self, model):
return []
def build_user_cut(self, model, violation):
pass
def load(self, filename):
with gzip.GzipFile(filename, &#34;r&#34;) as f:
data = json.loads(f.read().decode(&#34;utf-8&#34;))
self.__dict__ = data
def dump(self, filename):
data = json.dumps(self.__dict__, indent=2).encode(&#34;utf-8&#34;)
with gzip.GzipFile(filename, &#34;w&#34;) as f:
f.write(data)</code></pre>
</details>
<h3>Ancestors</h3>
<ul class="hlist">
<li>abc.ABC</li>
</ul>
<h3>Subclasses</h3>
<ul class="hlist">
<li><a title="miplearn.problems.knapsack.KnapsackInstance" href="problems/knapsack.html#miplearn.problems.knapsack.KnapsackInstance">KnapsackInstance</a></li>
<li><a title="miplearn.problems.knapsack.MultiKnapsackInstance" href="problems/knapsack.html#miplearn.problems.knapsack.MultiKnapsackInstance">MultiKnapsackInstance</a></li>
<li><a title="miplearn.problems.stab.MaxWeightStableSetInstance" href="problems/stab.html#miplearn.problems.stab.MaxWeightStableSetInstance">MaxWeightStableSetInstance</a></li>
<li><a title="miplearn.problems.tsp.TravelingSalesmanInstance" href="problems/tsp.html#miplearn.problems.tsp.TravelingSalesmanInstance">TravelingSalesmanInstance</a></li>
</ul>
<h3>Methods</h3>
<dl>
<dt id="miplearn.instance.Instance.build_lazy_constraint"><code class="name flex">
<span>def <span class="ident">build_lazy_constraint</span></span>(<span>self, model, violation)</span>
</code></dt>
<dd>
<section class="desc"><p>Returns a Pyomo constraint which fixes a given violation.</p>
<p>This method is typically called immediately after
find_violated_lazy_constraints. The violation object provided to this method
is exactly the same object returned earlier by
find_violated_lazy_constraints. After some training, LearningSolver may
decide to proactively build some lazy constraints at the beginning of the
optimization process, before a solution is even available. In this case,
build_lazy_constraints will be called without a corresponding call to
find_violated_lazy_constraints.</p>
<p>The implementation should not directly add the constraint to the model. The
constraint will be added by LearningSolver after the method returns.</p>
<p>For a concrete example, see TravelingSalesmanInstance.</p></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def build_lazy_constraint(self, model, violation):
&#34;&#34;&#34;
Returns a Pyomo constraint which fixes a given violation.
This method is typically called immediately after
find_violated_lazy_constraints. The violation object provided to this method
is exactly the same object returned earlier by
find_violated_lazy_constraints. After some training, LearningSolver may
decide to proactively build some lazy constraints at the beginning of the
optimization process, before a solution is even available. In this case,
build_lazy_constraints will be called without a corresponding call to
find_violated_lazy_constraints.
The implementation should not directly add the constraint to the model. The
constraint will be added by LearningSolver after the method returns.
For a concrete example, see TravelingSalesmanInstance.
&#34;&#34;&#34;
pass</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.build_user_cut"><code class="name flex">
<span>def <span class="ident">build_user_cut</span></span>(<span>self, model, violation)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def build_user_cut(self, model, violation):
pass</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.dump"><code class="name flex">
<span>def <span class="ident">dump</span></span>(<span>self, filename)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def dump(self, filename):
data = json.dumps(self.__dict__, indent=2).encode(&#34;utf-8&#34;)
with gzip.GzipFile(filename, &#34;w&#34;) as f:
f.write(data)</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.find_violated_lazy_constraints"><code class="name flex">
<span>def <span class="ident">find_violated_lazy_constraints</span></span>(<span>self, model)</span>
</code></dt>
<dd>
<section class="desc"><p>Returns lazy constraint violations found for the current solution.</p>
<p>After solving a model, LearningSolver will ask the instance to identify which
lazy constraints are violated by the current solution. For each identified
violation, LearningSolver will then call the build_lazy_constraint, add the
generated Pyomo constraint to the model, then resolve the problem. The
process repeats until no further lazy constraint violations are found.</p>
<p>Each "violation" is simply a string, a tuple or any other hashable type which
allows the instance to identify unambiguously which lazy constraint should be
generated. In the Traveling Salesman Problem, for example, a subtour
violation could be a frozen set containing the cities in the subtour.</p>
<p>For a concrete example, see TravelingSalesmanInstance.</p></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def find_violated_lazy_constraints(self, model):
&#34;&#34;&#34;
Returns lazy constraint violations found for the current solution.
After solving a model, LearningSolver will ask the instance to identify which
lazy constraints are violated by the current solution. For each identified
violation, LearningSolver will then call the build_lazy_constraint, add the
generated Pyomo constraint to the model, then resolve the problem. The
process repeats until no further lazy constraint violations are found.
Each &#34;violation&#34; is simply a string, a tuple or any other hashable type which
allows the instance to identify unambiguously which lazy constraint should be
generated. In the Traveling Salesman Problem, for example, a subtour
violation could be a frozen set containing the cities in the subtour.
For a concrete example, see TravelingSalesmanInstance.
&#34;&#34;&#34;
return []</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.find_violated_user_cuts"><code class="name flex">
<span>def <span class="ident">find_violated_user_cuts</span></span>(<span>self, model)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def find_violated_user_cuts(self, model):
return []</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.get_constraint_category"><code class="name flex">
<span>def <span class="ident">get_constraint_category</span></span>(<span>self, cid)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def get_constraint_category(self, cid):
return cid</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.get_constraint_features"><code class="name flex">
<span>def <span class="ident">get_constraint_features</span></span>(<span>self, cid)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def get_constraint_features(self, cid):
return np.zeros(1)</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.get_instance_features"><code class="name flex">
<span>def <span class="ident">get_instance_features</span></span>(<span>self)</span>
</code></dt>
<dd>
<section class="desc"><p>Returns a 1-dimensional Numpy array of (numerical) features describing the
entire instance.</p>
<p>The array is used by LearningSolver to determine how similar two instances
are. It may also be used to predict, in combination with variable-specific
features, the values of binary decision variables in the problem.</p>
<p>There is not necessarily a one-to-one correspondence between models and
instance features: the features may encode only part of the data necessary to
generate the complete model. Features may also be statistics computed from
the original data. For example, in the knapsack problem, an implementation
may decide to provide as instance features only the average weights, average
prices, number of items and the size of the knapsack.</p>
<p>The returned array MUST have the same length for all relevant instances of
the problem. If two instances map into arrays of different lengths,
they cannot be solved by the same LearningSolver object.</p>
<p>By default, returns [0].</p></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def get_instance_features(self):
&#34;&#34;&#34;
Returns a 1-dimensional Numpy array of (numerical) features describing the
entire instance.
The array is used by LearningSolver to determine how similar two instances
are. It may also be used to predict, in combination with variable-specific
features, the values of binary decision variables in the problem.
There is not necessarily a one-to-one correspondence between models and
instance features: the features may encode only part of the data necessary to
generate the complete model. Features may also be statistics computed from
the original data. For example, in the knapsack problem, an implementation
may decide to provide as instance features only the average weights, average
prices, number of items and the size of the knapsack.
The returned array MUST have the same length for all relevant instances of
the problem. If two instances map into arrays of different lengths,
they cannot be solved by the same LearningSolver object.
By default, returns [0].
&#34;&#34;&#34;
return np.zeros(1)</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.get_variable_category"><code class="name flex">
<span>def <span class="ident">get_variable_category</span></span>(<span>self, var, index)</span>
</code></dt>
<dd>
<section class="desc"><p>Returns the category (a string, an integer or any hashable type) for each
decision variable.</p>
<p>If two variables have the same category, LearningSolver will use the same
internal ML model to predict the values of both variables. If the returned
category is None, ML models will ignore the variable.</p>
<p>By default, returns "default".</p></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def get_variable_category(self, var, index):
&#34;&#34;&#34;
Returns the category (a string, an integer or any hashable type) for each
decision variable.
If two variables have the same category, LearningSolver will use the same
internal ML model to predict the values of both variables. If the returned
category is None, ML models will ignore the variable.
By default, returns &#34;default&#34;.
&#34;&#34;&#34;
return &#34;default&#34;</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.get_variable_features"><code class="name flex">
<span>def <span class="ident">get_variable_features</span></span>(<span>self, var, index)</span>
</code></dt>
<dd>
<section class="desc"><p>Returns a 1-dimensional array of (numerical) features describing a particular
decision variable.</p>
<p>The argument <code>var</code> is a pyomo.core.Var object, which represents a collection
of decision variables. The argument <code>index</code> specifies which variable in the
collection is the relevant one.</p>
<p>In combination with instance features, variable features are used by
LearningSolver to predict, among other things, the optimal value of each
decision variable before the optimization takes place. In the knapsack
problem, for example, an implementation could provide as variable features
the weight and the price of a specific item.</p>
<p>Like instance features, the arrays returned by this method MUST have the same
length for all variables within the same category, for all relevant instances
of the problem.</p>
<p>By default, returns [0].</p></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def get_variable_features(self, var, index):
&#34;&#34;&#34;
Returns a 1-dimensional array of (numerical) features describing a particular
decision variable.
The argument `var` is a pyomo.core.Var object, which represents a collection
of decision variables. The argument `index` specifies which variable in the
collection is the relevant one.
In combination with instance features, variable features are used by
LearningSolver to predict, among other things, the optimal value of each
decision variable before the optimization takes place. In the knapsack
problem, for example, an implementation could provide as variable features
the weight and the price of a specific item.
Like instance features, the arrays returned by this method MUST have the same
length for all variables within the same category, for all relevant instances
of the problem.
By default, returns [0].
&#34;&#34;&#34;
return np.zeros(1)</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.has_dynamic_lazy_constraints"><code class="name flex">
<span>def <span class="ident">has_dynamic_lazy_constraints</span></span>(<span>self)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def has_dynamic_lazy_constraints(self):
return False</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.has_static_lazy_constraints"><code class="name flex">
<span>def <span class="ident">has_static_lazy_constraints</span></span>(<span>self)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def has_static_lazy_constraints(self):
return False</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.is_constraint_lazy"><code class="name flex">
<span>def <span class="ident">is_constraint_lazy</span></span>(<span>self, cid)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def is_constraint_lazy(self, cid):
return False</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.load"><code class="name flex">
<span>def <span class="ident">load</span></span>(<span>self, filename)</span>
</code></dt>
<dd>
<section class="desc"></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">def load(self, filename):
with gzip.GzipFile(filename, &#34;r&#34;) as f:
data = json.loads(f.read().decode(&#34;utf-8&#34;))
self.__dict__ = data</code></pre>
</details>
</dd>
<dt id="miplearn.instance.Instance.to_model"><code class="name flex">
<span>def <span class="ident">to_model</span></span>(<span>self)</span>
</code></dt>
<dd>
<section class="desc"><p>Returns the optimization model corresponding to this instance.</p></section>
<details class="source">
<summary>
<span>Expand source code</span>
</summary>
<pre><code class="python">@abstractmethod
def to_model(self) -&gt; Any:
&#34;&#34;&#34;
Returns the optimization model corresponding to this instance.
&#34;&#34;&#34;
pass</code></pre>
</details>
</dd>
</dl>
</dd>
</dl>
</section>
</article>
<nav id="sidebar">
<h1>Index</h1>
<div class="toc">
<ul></ul>
</div>
<ul id="index">
<li><h3>Super-module</h3>
<ul>
<li><code><a title="miplearn" href="index.html">miplearn</a></code></li>
</ul>
</li>
<li><h3><a href="#header-classes">Classes</a></h3>
<ul>
<li>
<h4><code><a title="miplearn.instance.Instance" href="#miplearn.instance.Instance">Instance</a></code></h4>
<ul class="">
<li><code><a title="miplearn.instance.Instance.build_lazy_constraint" href="#miplearn.instance.Instance.build_lazy_constraint">build_lazy_constraint</a></code></li>
<li><code><a title="miplearn.instance.Instance.build_user_cut" href="#miplearn.instance.Instance.build_user_cut">build_user_cut</a></code></li>
<li><code><a title="miplearn.instance.Instance.dump" href="#miplearn.instance.Instance.dump">dump</a></code></li>
<li><code><a title="miplearn.instance.Instance.find_violated_lazy_constraints" href="#miplearn.instance.Instance.find_violated_lazy_constraints">find_violated_lazy_constraints</a></code></li>
<li><code><a title="miplearn.instance.Instance.find_violated_user_cuts" href="#miplearn.instance.Instance.find_violated_user_cuts">find_violated_user_cuts</a></code></li>
<li><code><a title="miplearn.instance.Instance.get_constraint_category" href="#miplearn.instance.Instance.get_constraint_category">get_constraint_category</a></code></li>
<li><code><a title="miplearn.instance.Instance.get_constraint_features" href="#miplearn.instance.Instance.get_constraint_features">get_constraint_features</a></code></li>
<li><code><a title="miplearn.instance.Instance.get_instance_features" href="#miplearn.instance.Instance.get_instance_features">get_instance_features</a></code></li>
<li><code><a title="miplearn.instance.Instance.get_variable_category" href="#miplearn.instance.Instance.get_variable_category">get_variable_category</a></code></li>
<li><code><a title="miplearn.instance.Instance.get_variable_features" href="#miplearn.instance.Instance.get_variable_features">get_variable_features</a></code></li>
<li><code><a title="miplearn.instance.Instance.has_dynamic_lazy_constraints" href="#miplearn.instance.Instance.has_dynamic_lazy_constraints">has_dynamic_lazy_constraints</a></code></li>
<li><code><a title="miplearn.instance.Instance.has_static_lazy_constraints" href="#miplearn.instance.Instance.has_static_lazy_constraints">has_static_lazy_constraints</a></code></li>
<li><code><a title="miplearn.instance.Instance.is_constraint_lazy" href="#miplearn.instance.Instance.is_constraint_lazy">is_constraint_lazy</a></code></li>
<li><code><a title="miplearn.instance.Instance.load" href="#miplearn.instance.Instance.load">load</a></code></li>
<li><code><a title="miplearn.instance.Instance.to_model" href="#miplearn.instance.Instance.to_model">to_model</a></code></li>
</ul>
</li>
</ul>
</li>
</ul>
</nav>
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