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Ooh, it's not easy at all. Func<T> represents a generic delegate and not an expression. If there's any way you could do so (due to optimizations and other things done by the compiler, some data might be thrown away, so it might be impossible to could get the original expression back), it'd be disassembling the IL on the fly and inferring the expression (which is by no means easy). Treating lambda expressions as data (Expression<Func<T>>) is a magic done by the compiler (basically the compiler builds an expression tree in code instead of compiling it to IL).

Related fact

This is why languages that push lambdas to the extreme (like Lisp) are interpreted languages. In those languages, code and data are essentially the same thing (even at run time), but our Core 2 Duo chip cannot understand that form of code, so we have to emulate such a machine by building an interpreter on top of it that understands it (the choice made by Lisp like languages) or sacrificing the power (code will no longer be exactly equal to data) to some extent (the choice made by C#). In C#, the compiler gives the illusion of treating code as data by allowing lambdas to be interpreted as code (Func<T>) and data (Expression<Func<T>>) at compile time.
show/hide this revision's text 4 added 187 characters in body

Ooh, it's not easy at all. Func<T> represents a generic delegate and not an expression. If there's any way you could do so (due to optimizations and other things done by the compiler, some data might be thrown away, so it might be impossible to could get the original expression back), it'd be disassembling the IL on the fly and inferring the expression (which is by no means easy). Treating lambda expressions as data (Expression<Func<T>>) is a magic done by the compiler (basically the compiler builds an expression tree in code instead of compiling it to IL).

Related fact

This is why languages that push lambdas to the extreme (like Lisp) are interpreted languages. In those languages, code is essentially and data are essentially the same thing, but our Core 2 Duo chip cannot understand that form of code, so we have to emulate such a machine by building an interpreter on top of it that understands this kind of code it (the choice made by Lisp like languages) or sacrificing the power (code will no longer be exactly equal to data) to some extent (the choice made by C#). In C#, the compiler gives the illusion of treating code as data by allowing lambdas to be interpreted as code (Func<T>) and data (Expression<Func<T>>) at compile time.
show/hide this revision's text 3 added 491 characters in body

Ooh, it's not easy at all. Func<T> represents a generic delegate and not an expression. If there's any way you could do so (due to optimizations and other things done by the compiler, some data might be thrown away, so it might be impossible to could get the original expression back), it'd be disassembling the IL on the fly and inferring the expression (which is by no means easy). Treating lambda expressions as data (Expression<Func<T>>) is a magic done by the compiler (basically the compiler builds an expression tree in code instead of compiling it to IL).

Related fact

This is why languages that push lambdas to the extreme (like Lisp) are interpreted languages. In those languages, code is essentially data, but our Core 2 Duo chip cannot understand that form of code, so we have to emulate such a machine by building an interpreter on top of it that understands this kind of code (the choice made by Lisp like languages) or sacrificing the power (code will no longer be exactly equal to data) to some extent (the choice made by C#).
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