I haven't been able to test this, but it seems that it ought to work. There's no square-root at the end, but the order should be the same either way.

```
public static IOrderedQueryable<T> EuclideanDistanceOrder<T>(this IQueryable<T> query, IEnumerable<Expression<Func<T, double>>> expressions)
{
var parameter = Expression.Parameter(typeof(T), "item");
var seed = Expression.Lambda<Func<T, double>>(Expression.Constant((double)0), parameter);
return query.OrderBy(expressions.Aggregate(seed, GetAggregateExpression));
}
private static Expression<Func<T, double>> GetAggregateExpression<T>(Expression<Func<T, double>> sum, Expression<Func<T, double>> item)
{
var parameter = Expression.Parameter(typeof(T), "item");
return Expression.Lambda<Func<T, double>>(Expression.Add(Expression.Invoke(sum, parameter), Expression.Power(Expression.Invoke(item, parameter), Expression.Constant((double)2))), parameter);
}
```

**Edit:**

Since you can't use `Expression.Invoke()`

, you'll need to inline the bodies of the Expressions passed into `EuclideanDistanceOrder`

. There doesn't seem to be any "nice" way to do this, so I've written a `Replace`

method to do it. I've only implemented `Replace`

for some of the more common `Expression`

types, hopefully this will be enough to cover your usage, but you may need to implement it for other `Expression`

types.

```
public static IOrderedQueryable<T> EuclideanDistanceOrder<T>(this IQueryable<T> query, IEnumerable<Expression<Func<T, double>>> expressions)
{
var parameter = Expression.Parameter(typeof(T), "item");
var seed = Expression.Constant((double)0);
var agg = expressions.Aggregate((Expression)seed, (s, item) => Expression.Add(s, Expression.Power(Replace(item.Body, item.Parameters[0], parameter), Expression.Constant((double)2))));
return query.OrderBy(Expression.Lambda<Func<T, double>>(agg, parameter));
}
private static Expression Replace(Expression expression, ParameterExpression original, ParameterExpression replacement)
{
if (expression is BinaryExpression)
{
var binaryExpression = (BinaryExpression)expression;
return Expression.MakeBinary(expression.NodeType, Replace(binaryExpression.Left, original, replacement), Replace(binaryExpression.Right, original, replacement), binaryExpression.IsLiftedToNull, binaryExpression.Method, binaryExpression.Conversion);
}
if (expression is ConditionalExpression)
{
var conditionalExpression = (ConditionalExpression)expression;
return Expression.Condition(Replace(conditionalExpression.Test, original, replacement), Replace(conditionalExpression.IfTrue, original, replacement), Replace(conditionalExpression.IfFalse, original, replacement), conditionalExpression.Type);
}
if (expression is ConstantExpression)
{
return expression;
}
if (expression is MemberExpression)
{
var memberExpression = (MemberExpression)expression;
return Expression.MakeMemberAccess(Replace(memberExpression.Expression, original, replacement), memberExpression.Member);
}
if (expression is ParameterExpression)
{
var parameterExpression = (ParameterExpression)expression;
return parameterExpression == original ? replacement : parameterExpression;
}
if (expression is UnaryExpression)
{
var unaryExpression = (UnaryExpression)expression;
return Expression.MakeUnary(unaryExpression.NodeType, Replace(unaryExpression.Operand, original, replacement), unaryExpression.Type, unaryExpression.Method);
}
throw new Exception(string.Format("Unsupported expression type: {0}", expression.NodeType));
}
```

So if for example, our input expressions are:

```
p => p.X1 - p.X2
p => p.Y1 - p.Y2
```

The original implementation would've constructed:

```
i => 0 + expressions[0](i) ^ 2 + expressions[1](i) ^ 2
```

The new implementation takes the original expression, and replaces the input parameter (`p`

in the above) with the parameter that will be passed to the final lambda (`i`

), and uses the body of the expression directly in the output:

```
i => 0 + (i.X1 - i.X2) ^ 2 + (i.Y1 - i.Y2) ^ 2
```