I want to select the right generic method via reflection and then call it.

Usually this is quite easy. For example

var method = typeof(MyType).GetMethod("TheMethod");
var typedMethod = method.MakeGenericMethod(theTypeToInstantiate);

However the issue start when there are different generic overloads of the method. For example the static-methods in the System.Linq.Queryable-class. There are two definitions of the 'Where'-method

static IQueryable<T> Where(this IQueryable<T> source, Expression<Func<T,bool>> predicate)
static IQueryable<T> Where(this IQueryable<T> source, Expression<Func<T,int,bool>> predicate)

This meand that GetMethod doesn't work, because it cannot destiguish the two. Therefore I want to select the right one.

So far I often just took the first or second method, depending on my need. Like this:

var method = typeof (Queryable).GetMethods().First(m => m.Name == "Where");
var typedMethod = method.MakeGenericMethod(theTypeToInstantiate);

However I'm not happy with this, because I make a huge assumption that the first method is the right one. I rather want to find the right method by the argument type. But I couldn't figure out how.

I tried it with passing the 'types', but it didn't work.

        var method = typeof (Queryable).GetMethod(
            "Where", BindingFlags.Static,
            new Type[] {typeof (IQueryable<T>), typeof (Expression<Func<T, bool>>)},

So has anyone an idea how I can find the 'right' generic method via reflection. For example the right version of the 'Where'-method on the Queryable-class?

13 Answers 13


You can somewhat elegantly select a specific generic overload of a method at compile-time, without passing any strings to run-time searches like the other answers here do.

Static Methods

Suppose you have multiple static methods of the same name like:

public static void DoSomething<TModel>(TModel model)

public static void DoSomething<TViewModel, TModel>(TViewModel viewModel, TModel model)

// etc

If you create an Action or Func that matches the generic count and parameter count of the overload you're looking for, you can select it at compile-time with relatively few acrobatics.

Example: Select the first method - returns void, so use an Action, takes one generic. We use object to avoid specifying type just yet:

var method = new Action<object>(MyClass.DoSomething<object>);

Example: Select the second method - returns void, so Action, 2 generic types so use type object twice, once for each of the 2 generic parameters:

var method = new Action<object, object>(MyClass.DoSomething<object, object>);

You just got the method you wanted without doing any crazy plumbing, and no run-time searching or usage of risky strings.


Typically in Reflection you want the MethodInfo object, which you can also get in a compile-safe way. This is when you pass the actual generic types you want to use in your method. Assuming you wanted the second method above:

var methodInfo = method.Method.MakeGenericMethod(type1, type2);

There's your generic method without any of the reflection searching or calls to GetMethod(), or flimsy strings.

Static Extension Methods

The specific example you cite with Queryable.Where overloads forces you to get a little fancy in the Func definition, but generally follows the same pattern. The signature for the most commonly used Where() extension method is:

public static IQueryable<TModel> Where<TModel>(this IQueryable<TModel>, Expression<Func<TModel, bool>>)

Obviously this will be slightly more complicated - here it is:

var method = new Func<IQueryable<object>,
                      Expression<Func<object, bool>>,

var methodInfo = method.Method.MakeGenericMethod(modelType);

Instance Methods

Incorporating Valerie's comment - to get an instance method, you'll need to do something very similar. Suppose you had this instance method in your class:

public void MyMethod<T1>(T1 thing)

First select the method the same way as for statics:

var method = new Action<object>(MyMethod<object>);

Then call GetGenericMethodDefinition() to get to the generic MethodInfo, and finally pass your type(s) with MakeGenericMethod():

var methodInfo = method.Method.GetGenericMethodDefinition().MakeGenericMethod(type1);

Decoupling MethodInfo and Parameter Types

This wasn't requested in the question, but once you do the above you may find yourself selecting the method in one place, and deciding what types to pass it in another. You can decouple those 2 steps.

If you're uncertain of the generic type parameters you're going to pass in, you can always acquire the MethodInfo object without them.


var methodInfo = method.Method;


var methodInfo = method.Method.GetGenericMethodDefinition();

And pass that on to some other method that knows the types it wants to instantiate and call the method with - for example:

processCollection(methodInfo, type2);


protected void processCollection(MethodInfo method, Type type2)
    var type1 = typeof(MyDataClass);
    object output = method.MakeGenericMethod(type1, type2).Invoke(null, new object[] { collection });

One thing this especially helps with is selecting a specific instance method of a class, from inside the class, then exposing that to outside callers who need it with various types later on.


A number of comments below say they cannot get this to work. It might not be surprising that I don't often have to select a generic method like this, but I happen to be doing so today, in well-tested code used behind the scenes all the time, so I thought I'd provide that real-world example - and perhaps it will help those who struggle to get this to work.

C# lacks a Clone method, so we have our own. It can take a number of arguments, including those that explain how to recursively copy IEnumerable properties inside the source object.

The method that copies an IEnumerable is named CopyList, and looks like this:

public static IEnumerable<TTo> CopyList<TTo>(
    IEnumerable<object> from,
    Func<PropertyInfo, bool> whereProps,
    Dictionary<Type, Type> typeMap
    where TTo : new()

To complicate things (and flex the muscles of this approach), it has several overloads, like this one:

public static IEnumerable<TTo> CopyList<TTo>(
    IEnumerable<object> from,
    Dictionary<Type, Type> typeMap
    where TTo : new()

So, we've got several (I'm only showing you 2, but there are more in the code) method signatures. They have the same number of Generic arguments, but a different number of method arguments. The names are identical. How are we possibly going to call the right method? Begin the C# ninjaing!

var listTo = ReflectionHelper.GetIEnumerableType(

var fn = new Func<
    Func<PropertyInfo, bool>,
    Dictionary<Type, Type>,

var copyListMethod = fn.GetMethodInfo()

    new object[] { fromValue, whereProps, typeMap });

The first line uses a helper method we'll come back to, but all it's doing is getting the generic type of the IEnumerable list in this property, and assigning it to listTo. The next line is where we really begin performing this trick, where we lay out a Func with adequate parameters to match up with the specific CopyList() overload we intend to grab. Specifically, the CopyList() we want has 3 arguments, and returns IEnumerable<TTo>. Remember that Func takes its return type as its last generic arg, and that we're substituting object wherever there's a generic in the method we intend to grab. But, as you can see in this example, we do not need to substitute object anywhere else. For example, we know we want to pass a where clause that accepts a PropertyInfo and returns true/false (bool), and we just say those types right in the Func.

As the constructor arg to the Func, we pass CopyList() - but remember that the name CopyList is vague because of the method overloads. What's really cool is that C# is doing the hard work for you right now, by looking at the Func args, and identifying the right one. In fact, if you get the types or number of args wrong, Visual Studio will actually mark the line with an error:

No overload for 'CopyList' matches delegate 'Func...'

It's not smart enough to tell you what exactly you need to fix, but if you see that error you're close - you need to carefully double-check the args and return type and match them up exactly, replacing Generic args with object.

On the third line, we call the C# built-in .GetMethodInfo() and then .MakeGeneric(listTo). We have only one Generic to set for this, so we pass that in as listTo. If we had 2, we'd pass 2 args here. These Type args are replacing the object substitutions we made earlier.

And that's it - we can call copyListMethod(), with no strings, fully compile-safe. The final line makes the call, first passing null because it's a static method, then an object[] array with the 3 args. Done.

I said I'd come back to the ReflectionHelper method. Here it is:

public static Type GetIEnumerableType(Type type)
    var ienumerable = type.GetInterface(typeof(System.Collections.Generic.IEnumerable<>).FullName);
    var generics = ienumerable.GetGenericArguments();
    return generics[0];
  • 8
    I don't know why this isn't the top answer! It is simple and type-safe. I got this to work for our code, with a slight change. I was calling a non-static method and had to first get the generic definition before making into a generic method: var methodInfo = method.Method.GetGenericMethodDefinition().MakeGenericMethod(type1);
    – Valerie
    Nov 15, 2013 at 18:39
  • 3
    I concur with Valerie. This is the way I now do this. No more mistyped strings giving me null reference exceptions... For the original question, a Func<> is needed instead of an Action<> and the GetGenericMethodDefinition() must be called.
    – mheyman
    Feb 18, 2014 at 15:27
  • 1
    I got a InvalidOperationException on the call to MakeGenericMethod trying to call the Queryable.Where: System.Linq.IQueryable1[System.Object] Where[Object](System.Linq.IQueryable1[System.Object], System.Linq.Expressions.Expression1[System.Func2[System.Object,System.Boolean]]) is not a GenericMethodDefinition. MakeGenericMethod may only be called on a method for which MethodBase.IsGenericMethodDefinition is true. Jul 9, 2014 at 12:01
  • I have always used this to get the specific generic methods at runtime, but I stumbled on a problem I could not solve. I'm implementing an EF interface that passes an instance of an internal class to me, and I need to get a generic method with runtime typing on this instance. It works fine inside of said interface method, but I wanted to extract the logic of getting the generic method info and wasn't able to, since it's an internal type and I couldn't instantiate it to access the method and put it into a Func. Is there a workaround to that, or do I need to pass the instance around?
    – julealgon
    Oct 9, 2014 at 16:29
  • @julealgon That's complex enough that it merits its own question, since the answer could help others, and would likely benefit from code examples. Write up the Q and link to this answer! Oct 9, 2014 at 19:49

It can be done, but it's not pretty!

For example, to get the first overload of Where mentioned in your question you could do this:

var where1 = typeof(Queryable).GetMethods()
                 .Where(x => x.Name == "Where")
                 .Select(x => new { M = x, P = x.GetParameters() })
                 .Where(x => x.P.Length == 2
                             && x.P[0].ParameterType.IsGenericType
                             && x.P[0].ParameterType.GetGenericTypeDefinition() == typeof(IQueryable<>)
                             && x.P[1].ParameterType.IsGenericType
                             && x.P[1].ParameterType.GetGenericTypeDefinition() == typeof(Expression<>))
                 .Select(x => new { x.M, A = x.P[1].ParameterType.GetGenericArguments() })
                 .Where(x => x.A[0].IsGenericType
                             && x.A[0].GetGenericTypeDefinition() == typeof(Func<,>))
                 .Select(x => new { x.M, A = x.A[0].GetGenericArguments() })
                 .Where(x => x.A[0].IsGenericParameter
                             && x.A[1] == typeof(bool))
                 .Select(x => x.M)

Or if you wanted the second overload:

var where2 = typeof(Queryable).GetMethods()
                 .Where(x => x.Name == "Where")
                 .Select(x => new { M = x, P = x.GetParameters() })
                 .Where(x => x.P.Length == 2
                             && x.P[0].ParameterType.IsGenericType
                             && x.P[0].ParameterType.GetGenericTypeDefinition() == typeof(IQueryable<>)
                             && x.P[1].ParameterType.IsGenericType
                             && x.P[1].ParameterType.GetGenericTypeDefinition() == typeof(Expression<>))
                 .Select(x => new { x.M, A = x.P[1].ParameterType.GetGenericArguments() })
                 .Where(x => x.A[0].IsGenericType
                             && x.A[0].GetGenericTypeDefinition() == typeof(Func<,,>))
                 .Select(x => new { x.M, A = x.A[0].GetGenericArguments() })
                 .Where(x => x.A[0].IsGenericParameter
                             && x.A[1] == typeof(int)
                             && x.A[2] == typeof(bool))
                 .Select(x => x.M)
  • 1
    If you want to invoke the resulting MethodInfo, you would have to call .MakeGenericMethod() on it and invoke it's returned MethodInfo. Jul 10, 2014 at 8:16
  • How would you find any method if you only have the specific parameters? How would it look if you didn't hard-code the 3 types (queryable, expression, func)?
    – Riki
    Feb 10, 2019 at 8:16

This question is about 2 years old, but I came up with (what I think is) an elegant solution, and thought I'd share it with the fine folks here at StackOverflow. Hopefully it will help those who arrive here via various search queries.

The problem, as the poster stated, is to get the correct generic method. For example, a LINQ extension method may have tons of overloads, with type arguments nested inside other generic types, all used as parameters. I wanted to do something like this:

var where = typeof(Enumerable).GetMethod(
  typeof(Expression<Func<Refl.T1, bool>>

var group = typeof(Enumerable).GetMethod(
  typeof(Expression<Func<Refl.T1, Refl.T2>>

As you can see, I've created some stub types "T1" and "T2", nested classes within a class "Refl" (a static class which contains all my various Reflection utility extension functions, etc. They serve as placeholders for where the type parameters would have normally went. The examples above correspond to getting the following LINQ methods, respectively:

Enumerable.Where(IQueryable<TSource> source, Func<TSource, bool> predicate);
Enumerable.GroupBy(IQueryable<Source> source, Func<TSource, TKey> selector);

So it should be clear that Refl.T1 goes where TSource would gone, in both of those calls; and the Refl.T2 represents the TKey parameter.The TX classes are declared as such:

static class Refl {
  public sealed class T1 { }
  public sealed class T2 { }
  public sealed class T3 { }
  // ... more, if you so desire.

With three TX classes, your code can identify methods containing up to three generic type parameters.

The next bit of magic is to implement the function that does the search via GetMethods():

public static MethodInfo GetMethod(this Type t, string name, params Type[] parameters)
    foreach (var method in t.GetMethods())
        // easiest case: the name doesn't match!
        if (method.Name != name)
        // set a flag here, which will eventually be false if the method isn't a match.
        var correct = true;
        if (method.IsGenericMethodDefinition)
            // map the "private" Type objects which are the type parameters to
            // my public "Tx" classes...
            var d = new Dictionary<Type, Type>();
            var args = method.GetGenericArguments();
            if (args.Length >= 1)
                d[typeof(T1)] = args[0];
            if (args.Length >= 2)
                d[typeof(T2)] = args[1];
            if (args.Length >= 3)
                d[typeof (T3)] = args[2];
            if (args.Length > 3)
                throw new NotSupportedException("Too many type parameters.");

            var p = method.GetParameters();
            for (var i = 0; i < p.Length; i++)
                // Find the Refl.TX classes and replace them with the 
                // actual type parameters.
                var pt = Substitute(parameters[i], d);
                // Then it's a simple equality check on two Type instances.
                if (pt != p[i].ParameterType)
                    correct = false;
            if (correct)
                return method;
            var p = method.GetParameters();
            for (var i = 0; i < p.Length; i++)
                var pt = parameters[i];
                if (pt != p[i].ParameterType)
                    correct = false;
            if (correct)
                return method;
    return null;

The code above does the bulk of the work -- it iterates through all the Methods in a particular type, and compares them to the given parameter types to search for. But wait! What about that "substitute" function? That's a nice little recursive function that will search through the entire parameter type tree -- after all, a parameter type can itself be a generic type, which may contain Refl.TX types, which have to be swapped for the "real" type parameters which are hidden from us.

private static Type Substitute(Type t, IDictionary<Type, Type> env )
    // We only really do something if the type 
    // passed in is a (constructed) generic type.
    if (t.IsGenericType)
        var targs = t.GetGenericArguments();
        for(int i = 0; i < targs.Length; i++)
            targs[i] = Substitute(targs[i], env); // recursive call
        t = t.GetGenericTypeDefinition();
        t = t.MakeGenericType(targs);
    // see if the type is in the environment and sub if it is.
    return env.ContainsKey(t) ? env[t] : t;
  • Great solution! I gave this answer a 500-point bonus in lieu of the deserved recognition.
    – Rex M
    Mar 26, 2013 at 15:19
  • @RexM For what it's worth I'm not seeing how this is more effective at selecting a specific generic overload of a method than the approach I answered with, and it's definitely a lot more code. The answer I posted also doesn't require any runtime recursion. Mar 27, 2013 at 9:36
  • @ChrisMoschini for more complex situations than the original question, wherein we need to acquire the MethodInfo and only some of the generic parameters are known at that time, this provides an excellent usage story for the consuming developer. The volume of code is easy to incapsulate and cover with unit tests.
    – Rex M
    Mar 27, 2013 at 13:48
  • @RexM Can you provide an example? Maybe that belongs as a separate question. Both approaches do fine with knowing only part of the generic arguments in acquiring the MethodInfo object - I'll update my answer to illustrate. I suspect that short of being unsure of the name of the method at compile-time, this method is less performant without providing additional benefit. Mar 27, 2013 at 17:42
  • 1
    @ChrisMoschini OH, my sincere apologies! I was under the impression that yours was the accepted answer :(
    – atanamir
    Apr 4, 2013 at 0:34

Another solution that you might find useful - it is possible to get a MethodInfo based on Expression.Call that already has a logic for overload resolution.

For example, in case you need to get some specific Enumerable.Where method that could be accomplished using the following code:

var mi = Expression.Call(typeof (Enumerable), "Where", new Type[] {typeof (int)},
            Expression.Default(typeof (IEnumerable<int>)), Expression.Default(typeof (Func<int, int, bool>))).Method;

Third argument in the example - describes types of generic arguments, and all other arguments - types of parameters.

In the same way it is possible to get even non static object generic methods.You need to change only first argument from typeof (YourClass) to Expression.Default(typeof (YourClass)).

Actually, I have used that approach in my plugin for .NET Reflection API. You may check how it works here


Chris Moschini's answer is good when you know the method name in compile time. Antamir's answer works if we get method name in runtime, but is quite an overkill.

I am using another way, for which I got inspiration using reflector from .NET function Expression.Call, which selects correct generic method from a string.

public static MethodInfo GetGenericMethod(Type declaringType, string methodName, Type[] typeArgs, params Type[] argTypes) {
    foreach (var m in from m in declaringType.GetMethods()
                        where m.Name == methodName
                            && typeArgs.Length == m.GetGenericArguments().Length
                            && argTypes.Length == m.GetParameters().Length
                        select m.MakeGenericMethod(typeArgs)) {
        if (m.GetParameters().Select((p, i) => p.ParameterType == argTypes[i]).All(x => x == true))
            return m;

    return null;


var m = ReflectionUtils.GetGenericMethod(typeof(Queryable), "Where", new[] { typeof(Person) }, typeof(IQueryable<Person>), typeof(Expression<Func<Person, bool>>));

If you need only generic method definition or simply do not know the type T at the time, you can use some bogus types and then strip the generic's information:

var m = ReflectionUtils.GetGenericMethod(typeof(Queryable), "Where", new[] { typeof(object) }, typeof(IQueryable<object>), typeof(Expression<Func<object, bool>>));
m = m.GetGenericMethodDefinition();

Let the compiler do it for you:

var fakeExp = (Expression<Func<IQueryable<int>, IQueryable<int>>>)(q => q.Where((x, idx) => x> 2));
var mi = ((MethodCallExpression)fakeExp.Body).Method.GetGenericMethodDefinition();

for the Where with index, or simply leave out the second parameter in the Where expression for the one without


In additional to @MBoros's answer.

You can avoid writing complex generic arguments using this helper method:

public static MethodInfo GetMethodByExpression<Tin, Tout>(Expression<Func<IQueryable<Tin>, IQueryable<Tout>>> expr)  
    return (expr.Body as MethodCallExpression).Method;  


var where = GetMethodByExpression<int, int>(q => q.Where((x, idx) => x > 2));  


var select = GetMethodByExpression<Person, string>(q => q.Select(x => x.Name));  
var firstGenericParam = Type.MakeGenericMethodParameter(0);
var firstParam = typeof(IQueryable<>).MakeGenericType(firstGenericParam);
var funcType = typeof(Func<,>).MakeGenericType(firstGenericParam, typeof(bool));
//var funcType = typeof(Func<,,>).MakeGenericType(firstGenericParam, typeof(int), typeof(bool)); //for second version 
var secondParam = typeof(Expression<>).MakeGenericType(funcType);
var method = typeof(Queryable).GetMethod(nameof(Queryable.Where), new Type[] { firstParam, secondParam });
  • 1
    While your answer may solve the question, including an explanation of how and why this solves the problem would really help to improve the quality of your post, and probably result in more up-votes. Remember that you are answering the question for readers in the future, not just the person asking now. You can edit your answer to add explanations and give an indication of what limitations and assumptions apply. - From Review Mar 1, 2021 at 15:16
  • 1
    Not sure why this was voted down as this is (imho) the only answer that really an answers the question. The other answers maybe have more explanation... but dont answer the question about how to select the right one, besides searching your self with linq and such. Thanks @Илья Любашов, this helped a lot.
    – SvenL
    May 29, 2022 at 8:44

Use DynamicMethods.GenericMethodInvokerMethod, GetMethod is not enough to use with generics


I made a little helper func:

Func<Type, string, Type[], Type[], MethodInfo> getMethod = (t, n, genargs, args) =>
        var methods =
            from m in t.GetMethods()
            where m.Name == n && m.GetGenericArguments().Length == genargs.Length
            let mg = m.IsGenericMethodDefinition ? m.MakeGenericMethod(genargs) : m
            where mg.GetParameters().Select(p => p.ParameterType).SequenceEqual(args)
            select mg

        return methods.Single();

Works for simple non-generics:

var m_movenext = getMethod(typeof(IEnumerator), nameof(IEnumerator.MoveNext), Type.EmptyTypes, Type.EmptyTypes);

Like for complicated generics:

var t_source = typeof(fillin1);
var t_target = typeof(fillin2);
var m_SelectMany = getMethod(
           new[] { 
           new[] {
               typeof(Func<,>).MakeGenericType(t_source, typeof(IEnumerable<>).MakeGenericType(t_target)) 

I have a similar issue and I thought I would post my solution here. I'm trying to call several functions:

bool k1 = p.Bar<Klass1>()
bool k2 = p.Bar<Klass2>()
bool k3 = p.Bar<Klass3>()

My solution:

public static TAction RemapGenericMember<TAction>(object parent, Type target, TAction func) where TAction : Delegate { 
    var genericMethod = func?.Method?.GetGenericMethodDefinition()?.MakeGenericMethod(target);
    if (genericMethod.IsNull()) {
        throw new Exception($"Failed to build generic call for '{func.Method.Name}' with generic type '{target.Name}' for parent '{parent.GetType()}'");
    return (TAction)genericMethod.CreateDelegate(typeof(TAction), parent);

And now I can call:

foreach(var type in supportedTypes) {
   InvokeGenericMember<Action<bool>>(p, type, Foo<object>)(true);
   bool x = InvokeGenericMember<Function<bool>>(p, type, Bar<object>)();

Antamir's answer was very useful for me, but it has a bug in that it doesn't validate that the number of parameters on the method found matches the number of types passed in when you provide a mix of generic and concrete types.

For example, if you ran:


it can't differentiate between two methods:

MyMethod<T>(T arg1)
MyMethod<T>(T arg1, bool arg2)

The two calls to:

var p = method.GetParameters();   

should be changed to:

var p = method.GetParameters();   
if (p.Length != parameters.Length)
    correct = false;

Also, both of the existing 'break' lines should be 'continue'.


I found out the easiest way to use iQuerable expressions while calling method using reflection. Please see below code:

You can use the IQuerable expression as per requirement.

var attributeName = "CarName";
var attributeValue = "Honda Accord";

carList.FirstOrDefault(e => e.GetType().GetProperty(attributeName).GetValue(e, null) as string== attributeValue);

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