12

I'm trying to figure out a way to structure my data so that it is model bindable. My Issue is that I have to create a query filter which can represent multiple expressions in data.

For example:

x => (x.someProperty == true && x.someOtherProperty == false) || x.UserId == 2

x => (x.someProperty && x.anotherProperty) || (x.userId == 3 && x.userIsActive)

I've created this structure which represents all of the expressions fine my Issue is how can I make this so it's property Model Bindable

public enum FilterCondition
{
    Equals,
}

public enum ExpressionCombine
{
    And = 0,
    Or
}

public interface IFilterResolver<T>
{
    Expression<Func<T, bool>> ResolveExpression();
}

public class QueryTreeNode<T> : IFilterResolver<T>
{
    public string PropertyName { get; set; }
    public FilterCondition FilterCondition { get; set; }
    public string Value { get; set; }
    public bool isNegated { get; set; }

    public Expression<Func<T, bool>> ResolveExpression()
    {
        return this.BuildSimpleFilter();
    }
}

//TODO: rename this class
public class QueryTreeBranch<T> : IFilterResolver<T>
{
    public QueryTreeBranch(IFilterResolver<T> left, IFilterResolver<T> right, ExpressionCombine combinor)
    {
        this.Left = left;
        this.Right = right;
        this.Combinor = combinor;
    }

    public IFilterResolver<T> Left { get; set; }
    public IFilterResolver<T> Right { get; set; }
    public ExpressionCombine Combinor { get; set; }

    public Expression<Func<T, bool>> ResolveExpression()
    {
        var leftExpression = Left.ResolveExpression();
        var rightExpression = Right.ResolveExpression();

        return leftExpression.Combine(rightExpression, Combinor);
    }
}

My left an right members just need to be able to be resolved to an IResolvable, but the model binder only binds to concrete types. I know I can write a custom model binder but I'd prefer to just have a structure that works.

I know I can pass json as a solutions but as a requirement I can't

Is there a way I can refine this structure so that it can still represent all simple expression while being Model Bindable? or is there an easy way I can apply this structure so that it works with the model binder?

EDIT Just in case anyone is wondering, my expression builder has a whitelist of member expressions that it it filters on. The dynamic filtering work I just looking for a way to bind this structure naturally so that my Controller can take in a QueryTreeBranch or take in a structure which accurately represent the same data.

public class FilterController
{
     [HttpGet]
     [ReadRoute("")]
     public Entity[]  GetList(QueryTreeBranch<Entity> queryRoot)
     {
         //queryRoot no bind :/
     }
}

Currently the IFilterResolver has 2 implementations which need to be chosen dynamically based on the data passed

I'm looking for a solution closest to out of the box WebApi / MVC framework. Preferable one that does NOT require me to adapt the input to another structure in order generate my expression

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  • Do you have a fixed set of expressions, query filters, that can be used or is it completely dynamic? – aaronR Sep 7 '17 at 16:30
  • 2
    Can you provide a not working example of what you wanted this to do? – bruno.almeida Sep 7 '17 at 16:36
  • @aaronR I'm whitelisting my access normally with member expression I'll update the question in a second – johnny 5 Sep 7 '17 at 18:30
  • @Nkosi eventually this will be a light weight OData, but I'm allowing the client to pass in simple filters and whitelisting my access, so you can dynamically filter entities. I.E { propertyName: "Id", filterCondition: "equals", value: "3" } – johnny 5 Sep 7 '17 at 18:54
  • @Nkosi I need to support simple binary expression and or etc – johnny 5 Sep 7 '17 at 18:55
6
+50

At first glance, you can split filtering logic on DTO, which contains an expression tree independent on entity type, and a type-dependent generator of Expression<Func<T, bool>>. Thus we can avoid making DTO generic and polymorphic, which causes the difficulties.

One can notice, that you used polymorphism (2 implementations) for IFilterResolver<T> because you want to say, that every node of the filtering tree is either a leaf or a branch (this is also called disjoint union).

Model

Ok, if this certain implementation causes proplems, let's try another one:

public class QueryTreeNode
{
    public NodeType Type { get; set; }
    public QueryTreeBranch Branch { get; set; }
    public QueryTreeLeaf Leaf { get; set; }
}

public enum NodeType
{
    Branch, Leaf
}

Of course, you will need validation for such model.

So the node is either a branch or a leaf (I slightly simplified the leaf here):

public class QueryTreeBranch
{
    public QueryTreeNode Left { get; set; }
    public QueryTreeNode Right { get; set; }
    public ExpressionCombine Combinor { get; set; }
}

public class QueryTreeLeaf
{
    public string PropertyName { get; set; }
    public string Value { get; set; }
}

public enum ExpressionCombine
{
    And = 0, Or
}

DTOs above are not so convenient to create from code, so one can use following class to generate those objects:

public static class QueryTreeHelper
{
    public static QueryTreeNode Leaf(string property, int value)
    {
        return new QueryTreeNode
        {
            Type = NodeType.Leaf,
            Leaf = new QueryTreeLeaf
            {
                PropertyName = property,
                Value = value.ToString()
            }
        };
    }

    public static QueryTreeNode Branch(QueryTreeNode left, QueryTreeNode right)
    {
        return new QueryTreeNode
        {
            Type = NodeType.Branch,
            Branch = new QueryTreeBranch
            {
                Left = left,
                Right = right
            }
        };
    }
}

View

There should be no problems with binding such a model (ASP.Net MVC is okay with recursive models, see this question). E.g. following dummy views (place them in \Views\Shared\EditorTemplates folder).

For branch:

@model WebApplication1.Models.QueryTreeBranch

<h4>Branch</h4>
<div style="border-left-style: dotted">
    @{
        <div>@Html.EditorFor(x => x.Left)</div>
        <div>@Html.EditorFor(x => x.Right)</div>
    }
</div>

For leaf:

@model WebApplication1.Models.QueryTreeLeaf

<div>
    @{
        <div>@Html.LabelFor(x => x.PropertyName)</div>
        <div>@Html.EditorFor(x => x.PropertyName)</div>
        <div>@Html.LabelFor(x => x.Value)</div>
        <div>@Html.EditorFor(x => x.Value)</div>
    }
</div>

For node:

@model WebApplication1.Models.QueryTreeNode

<div style="margin-left: 15px">
    @{
        if (Model.Type == WebApplication1.Models.NodeType.Branch)
        {
            <div>@Html.EditorFor(x => x.Branch)</div>
        }
        else
        {
            <div>@Html.EditorFor(x => x.Leaf)</div>
        }
    }
</div>

Sample usage:

@using (Html.BeginForm("Post"))
{
    <div>@Html.EditorForModel()</div>
}

Controller

Finally, you can implement an expression generator taking filtering DTO and a type of T, e.g. from string:

public class SomeRepository
{
    public TEntity[] GetAllEntities<TEntity>()
    {
        // Somehow select a collection of entities of given type TEntity
    }

    public TEntity[] GetEntities<TEntity>(QueryTreeNode queryRoot)
    {
        return GetAllEntities<TEntity>()
            .Where(BuildExpression<TEntity>(queryRoot));
    }

    Expression<Func<TEntity, bool>> BuildExpression<TEntity>(QueryTreeNode queryRoot)
    {
        // Expression building logic
    }
}

Then you call it from controller:

using static WebApplication1.Models.QueryTreeHelper;

public class FilterController
{
    [HttpGet]
    [ReadRoute("")]
    public Entity[]  GetList(QueryTreeNode queryRoot, string entityType)
    {
        var type = Assembly.GetExecutingAssembly().GetType(entityType);
        var entities = someRepository.GetType()
            .GetMethod("GetEntities")
            .MakeGenericMethod(type)
            .Invoke(dbContext, queryRoot);
    }

    // A sample tree to test the view
    [HttpGet]
    public ActionResult Sample()
    {
        return View(
            Branch(
                Branch(
                    Leaf("a", 1),
                    Branch(
                        Leaf("d", 4),
                        Leaf("b", 2))),
                Leaf("c", 3)));
    }
}

UPDATE:

As discussed in comments, it's better to have a single model class:

public class QueryTreeNode
{
    // Branch data (should be null for leaf)
    public QueryTreeNode LeftBranch { get; set; }
    public QueryTreeNode RightBranch { get; set; }

    // Leaf data (should be null for branch)
    public string PropertyName { get; set; }
    public string Value { get; set; }
}

...and a single editor template:

@model WebApplication1.Models.QueryTreeNode

<div style="margin-left: 15px">
    @{
        if (Model.PropertyName == null)
        {
            <h4>Branch</h4>
            <div style="border-left-style: dotted">
                <div>@Html.EditorFor(x => x.LeftBranch)</div>
                <div>@Html.EditorFor(x => x.RightBranch)</div>
            </div>
        }
        else
        {
            <div>
                <div>@Html.LabelFor(x => x.PropertyName)</div>
                <div>@Html.EditorFor(x => x.PropertyName)</div>
                <div>@Html.LabelFor(x => x.Value)</div>
                <div>@Html.EditorFor(x => x.Value)</div>
            </div>
        }
    }
</div>

Again this way requires a lot of validation.

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  • +1 this is definitely valid and should work, I just don't like that 1, you have an entity which defines 2 object but only 1 is valid at a time, and now I have to use 3 models, when there probably is a way we can do it with 1 – johnny 5 Sep 8 '17 at 18:00
  • @johnny5 I agree. Unfortunately, C# seems to have no pretty way to define disjoint union - that's the main problem here. As I wrote, my implementation is a tradeoff to make the model binder happy. – stop-cran Sep 8 '17 at 18:53
  • @johnny5 I think it's possible to have only 1 model object here, see update in the answer. – stop-cran Sep 11 '17 at 6:14
  • I was hoping to magically find a cleaner way to do this but this looks like the only way 'thanks – johnny 5 Sep 14 '17 at 15:36
0

You should use a custom data binder for your generic class.

See this previous question that had a similar need in a previous version using web forms and the Microsoft documentation.

You're other option is to pass a serialized version of the class.

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  • The trouble isn't the generics it's binding an interface with 2 implementations that should be resolved based on the data – johnny 5 Sep 8 '17 at 15:10
  • What is the second implementation? – aaronR Sep 8 '17 at 15:12
  • Isn't that one implementation that is the same but rather used on two properties? – aaronR Sep 8 '17 at 15:19
  • IFilterResolver can be a QueryTreeNode or QueryTreeBranch, its class should be slected based off of the data provided – johnny 5 Sep 8 '17 at 15:44
0

I've created an interface binder that works off of the standard ComplexTypeModelBinder

//Redefine IModelBinder so that when the ModelBinderProvider Casts it to an 
//IModelBinder it uses our new BindModelAsync
public class InterfaceBinder : ComplexTypeModelBinder, IModelBinder
{
    protected TypeResolverOptions _options;
    //protected Dictionary<Type, ModelMetadata> _modelMetadataMap;
    protected IDictionary<ModelMetadata, IModelBinder> _propertyMap;
    protected ModelBinderProviderContext _binderProviderContext;

    protected InterfaceBinder(TypeResolverOptions options, ModelBinderProviderContext binderProviderContext, IDictionary<ModelMetadata, IModelBinder> propertyMap) : base(propertyMap)
    {
        this._options = options;
        //this._modelMetadataMap = modelMetadataMap;
        this._propertyMap = propertyMap;
        this._binderProviderContext = binderProviderContext;
    }

    public InterfaceBinder(TypeResolverOptions options, ModelBinderProviderContext binderProviderContext) :
        this(options, binderProviderContext, new Dictionary<ModelMetadata, IModelBinder>())
    {
    }

    public new Task BindModelAsync(ModelBindingContext bindingContext)
    {
        var propertyNames = bindingContext.HttpContext.Request.Query
            .Select(x => x.Key.Trim());

        var modelName = bindingContext.ModelName;
        if (false == string.IsNullOrEmpty(modelName))
        {
            modelName = modelName + ".";
            propertyNames = propertyNames
                .Where(x => x.StartsWith(modelName, StringComparison.OrdinalIgnoreCase))
                .Select(x => x.Remove(0, modelName.Length));
        }

        //split always returns original object if empty
        propertyNames = propertyNames.Select(p => p.Split('.')[0]);
        var type = ResolveTypeFromCommonProperties(propertyNames, bindingContext.ModelType);

        ModelBindingResult result;
        ModelStateDictionary modelState;
        object model;
        using (var scope = CreateNestedBindingScope(bindingContext, type))
        {
             base.BindModelAsync(bindingContext);
            result = bindingContext.Result;
            modelState = bindingContext.ModelState;
            model = bindingContext.Model;
        }

        bindingContext.ModelState = modelState;
        bindingContext.Result = result;
        bindingContext.Model = model;

        return Task.FromResult(0);
    }

    protected override object CreateModel(ModelBindingContext bindingContext)
    {
        return Activator.CreateInstance(bindingContext.ModelType);
    }

    protected NestedScope CreateNestedBindingScope(ModelBindingContext bindingContext, Type type)
    {
        var modelMetadata = this._binderProviderContext.MetadataProvider.GetMetadataForType(type);

        //TODO: don't create this everytime this should be cached
        this._propertyMap.Clear();
        for (var i = 0; i < modelMetadata.Properties.Count; i++)
        {
            var property = modelMetadata.Properties[i];
            var binder = this._binderProviderContext.CreateBinder(property);
            this._propertyMap.Add(property, binder);
        }

        return bindingContext.EnterNestedScope(modelMetadata, bindingContext.ModelName, bindingContext.ModelName, null);
    }

    protected Type ResolveTypeFromCommonProperties(IEnumerable<string> propertyNames, Type interfaceType)
    {
        var types = this.ConcreteTypesFromInterface(interfaceType);

        //Find the type with the most matching properties, with the least unassigned properties
        var expectedType = types.OrderByDescending(x => x.GetProperties().Select(p => p.Name).Intersect(propertyNames).Count())
            .ThenBy(x => x.GetProperties().Length).FirstOrDefault();

        expectedType = interfaceType.CopyGenericParameters(expectedType);

        if (null == expectedType)
        {
            throw new Exception("No suitable type found for models");
        }

        return expectedType;
    }

    public List<Type> ConcreteTypesFromInterface(Type interfaceType)
    {
        var interfaceTypeInfo = interfaceType.GetTypeInfo();
        if (interfaceTypeInfo.IsGenericType && (false == interfaceTypeInfo.IsGenericTypeDefinition))
        {
            interfaceType = interfaceTypeInfo.GetGenericTypeDefinition();
        }

        this._options.TypeResolverMap.TryGetValue(interfaceType, out var types);
        return types ?? new List<Type>();
    }
}

Then you need a Model Binding Provider:

public class InterfaceBinderProvider : IModelBinderProvider
{
    TypeResolverOptions _options;

    public InterfaceBinderProvider(TypeResolverOptions options)
    {
        this._options = options;
    }
    public IModelBinder GetBinder(ModelBinderProviderContext context)
    {
        if (!context.Metadata.IsCollectionType &&
            (context.Metadata.ModelType.GetTypeInfo().IsInterface ||
             context.Metadata.ModelType.GetTypeInfo().IsAbstract) &&
            (context.BindingInfo.BindingSource == null ||
            !context.BindingInfo.BindingSource
            .CanAcceptDataFrom(BindingSource.Services)))
        {
            return new InterfaceBinder(this._options, context);
        }

        return null;
    }
}

and then you inject the binder into your services:

var interfaceBinderOptions = new TypeResolverOptions();

interfaceBinderOptions.TypeResolverMap.Add(typeof(IFilterResolver<>), 
    new List<Type> { typeof(QueryTreeNode<>), typeof(QueryTreeBranch<>) });
var interfaceProvider = new InterfaceBinderProvider(interfaceBinderOptions);

services.AddSingleton(typeof(TypeResolverOptions), interfaceBinderOptions);

services.AddMvc(config => {
    config.ModelBinderProviders.Insert(0, interfaceProvider);
});

Then you have your controllers setup like so

public MessageDTO Get(IFilterResolver<Message> foo)
{
    //now you can resolve expression etc...
}
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