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So I'm working with an old data model, and I kind of have to work within what I've been handed.

When I perform a database query, the model returns data as a

List<Dictionary<string, object>>

Where for each dictionary, the key is the column name and the value is the column value. As you can imagine, working with this is a nightmare of foreach loops and type casting

I'm hoping to define some POCO viewmodels and then making something that uses LINQ/reflection, and an "assignment binding map" to go from hideous return value to my nice clean POCO. So I could define "maps" with the column names and lambdas to the properties on my POCO, similar to this...

var Map; // type???
Map.Add("Id", p => p.Id);
Map.Add("Code", p => p.Code);
Map.Add("Description", p => p.Description);
Map.Add("Active", p => p.Active);

Then convert like this...

List<Dictionary<string, object>> Results = MyModel.Query(...);
List<ProductViewModel> POCOs = new List<ProductViewModel>();

foreach (var Result in Results) // Foreach row
  ProductViewModel POCO = new ProductViewModel();

  foreach (var i in Result) // Foreach column in this row
    // This is where I need help.
    // i.Key is the string name of my column.
    // I can get the lambda for this property from my map using this column name.
    // For example, need to assign to POCO.Id using the lambda expression p => p.Id
    // Or, assign to POCO.Code using the lambda expression p => p.Code


return POCOs;

Can this be done using some sort of reflection, and if so, how?

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3 Answers 3

up vote 12 down vote accepted

Here is an approach using expression trees. First, define the API of the map:

public class PropertyMap<T> where T : new()
    public void Add(string sourceName, Expression<Func<T, object>> getProperty);

    public T CreateObject(IDictionary<string, object> values);

You would use it like this:

var map = new PropertyMap<ProductViewModel>();

map.Add("Id", p => p.Id);
map.Add("Code", p => p.Code);
map.Add("Description", p => p.Description);
map.Add("Active", p => p.Active);

var productViewModel = map.CreateObject(values);

To implement it, first you would declare a dictionary to associate names from the data source to properties:

private readonly IDictionary<string, PropertyInfo> _properties = new Dictionary<string, PropertyInfo>();

Next, you would implement the Add method in terms of that dictionary (all error handling left as an exercise for the reader):

public void Add(string sourceName, Expression<Func<T, object>> getProperty)
    _properties[sourceName] = (PropertyInfo) ((MemberExpression) getProperty.Body).Member;

Then, you would dynamically compile a method, using expression trees, which does the assignments (it sounds scarier than it is). The easiest way to visualize this process is to look at an example of what we're building. What we want is some code which does this:

new ProductViewModel
    Id = ...,
    Code = ...,
    Description = ...,
    Active = ...

But, we can't know that at compile-time because of the dynamic mappings. So, we'll build a function which is that exact code, but compiled at runtime. Expression trees are just runtime data that represents the same code you could write at compile-time.

First, we need to get a set of bindings (assignments) for the properties:

private IEnumerable<MemberBinding> GetPropertyBindings(IDictionary<string, object> values)
        from sourceName in _properties.Keys
        select Expression.Bind(_properties[sourceName], Expression.Constant(values[sourceName]));

What we're saying here is, for each property in the mapped properties, look up the value and make it a constant (for Id, this might be the value 7) and bind the corresponding property to it. This gives us the expression Id = 7. We repeat this for all of the properties, giving us all of the assignments.

Once we have those bindings, we can create the full member initialization, which includes the constructor call:

private MemberInitExpression GetMemberInit(IDictionary<string, object> values)
    return Expression.MemberInit(Expression.New(typeof(T)), GetPropertyBindings(values));

Because we specified where T : new() in the class declaration, we are guaranteed to have a parameterless constructor to call here. We pass in the property bindings we created before, giving us a data structure that represents the initialization expression we wanted to build.

So what do we do know? We have this data structure, but how do we call the code? To do that, we have to wrap that expression in a function that we can call, because the only thing you can actually invoke is a method. This means we are really building code that looks like this:

() => new ProductViewModel
    Id = ...,
    Code = ...,
    Description = ...,
    Active = ...

That is a parameterless function which, when invoked, will return the initialized object. This is also called a lambda expression. We can get the data structure for this like so:

private Func<T> GetInitializationFunction(IDictionary<string, object> values)
    var initializationLambda = Expression.Lambda<Func<T>>(GetMemberInit(values));

    return initializationLambda.Compile();

We create a lambda expression whose body is the member initialization, which is exactly the code we wrote above. We specify the delegate type Func<T> because it takes no parameters and returns an object of the mapped type.

Then, we compile it. This call generates a method with the signature Func<T> that we can call, and which has as its body the code we created as a data structure. This is a neat way of doing reflection without using reflection directly.

Finally, we implement the CreateObject method we defined earlier by creating the function and invoking it, giving us an instance of T (ProductViewModel here):

public T CreateObject(IDictionary<string, object> values)
    var initializationFunction = GetInitializationFunction(values);

    return initializationFunction();
share|improve this answer
Wow, thank you very much! How would this perform versus directly using reflection? I would guess that, once the expression is compiled, it's as fast as native code, right? –  Stevoman Nov 29 '11 at 15:45
@Baconcheese: That's correct - once you have that Func<T>, it is as if you had passed in a reference to a method you wrote yourself. There is also ample opportunity for caching here; for example, you might only generate the method the first time and after adding a mapping. Then, if you cache the PropertyMap<T> instance at the application level, you incur very little overhead. –  Bryan Watts Nov 29 '11 at 16:45

This seems like a perfect match for dynamic . You can create a dynamic class that has the properties based on the keys in the dictionary. Check the DynamicObject class.

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it's not a buzzword - it's a keyword. –  Erix Nov 28 '11 at 22:24

What you could do is to extract the property name from a linq expression of the kind p => p.Id using something like this

public static string GetPropertyName<T>(Expression<Func<T>> expression)
    MemberExpression body = (MemberExpression)expression.Body;
    return body.Member.Name;

..and then use plain old reflection to actually assign the value to the object instance. For instance create a method

private void Assign(object objInstance, Expression<Func<T>> propertyExpression, object value)
    string propertyNameToAssign = GetPropertyName(propertyExpression);

    //TODO use reflection to assign "value" to the property "propertyNameToAssign" of "objInstance"

(didn't compile the code; for the reflection part, there are numerous articles on the web. Hope this helps)

share|improve this answer
It seems C# 4.0 added something called Expression Trees, would those be useful for this, and if so what is their performance versus the Reflection you showed? –  Stevoman Nov 28 '11 at 22:12
I actually didn't work much with expression trees but as far as I know they're just a way imposing structure on some data, basically by encoding information in those so-called expression trees. Actually the GetPropertyName makes already some very basic use of such an expression. However, in the end you will need reflection to extract the actual value anyway (as far as I know). I'm currently looking into whether AutoMapper could be of use here, but I have my doubts. –  Juri Nov 28 '11 at 22:17

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