Short answer: NO. There is no equivalent. They left it out. Too bad. Joke's on you.
There are some near-equivalent work-arounds, all based on the program examining itself. None is rational, elegant, or sturdy.
Some solutions pick up the compile date+time from "AssemblyVersion", a structure of four UInt16 fields ("Major Version", "Minor Version", "Build Number", and "Revision") that are not guaranteed to contain the date and time at all, much less in a specific format. If you set AssemblyVersion to "a.b.*" (and no one changes it), then the compiler overrides it to a.b.c.d, where c == days and d*2 == seconds since Jan. 1, 2000 at 00:00 (local time, but disregards daylight saving time), at the moment it parses AssemblyInfo.cs. These get compiled into the program, where they can be accessed via System.Reflection.Assembly.GetExecutingAssembly().GetName().Version .
Other solutions have the executable file reach into the file system to pick up its "last-modified" date+time from its own metadata, which is easily changed or damaged by transfer via FAT, CDFS, or FTP with DST or time-zone changes, lazy FTP servers that discard metadata outright, or file utilities that change metadata on request. Pathetic.
Where is the compile-time constant (or constants), maybe called #NOW (or #YEAR, #MONTH, #DAY, etc.), that can be used in expressions or assigned to a const or a readonly? CodeWarrior C, GCC, MS C, and MS C++ give the standard predefined macros
__TIME__ , which can be used like compile-time string constants. It seems like a glaring omission from C#, driving everyone to waste person-years asking about and setting up work-arounds. New language, new code, pathetic rickety design. C# doesn't have macros. C#'s #define only has "defined" or "undefined". SO WHAT? I see no excuse for deleting significant compile-time constants. How about putting it into C#'s fake pro-processor?
17 years into "Simple Managed C" / "C-like Object Oriented Language", CIL, and CLR, and this is what it is? A million ways to write code that doesn't do what it says (implementation of threading)? Libraries that expose every flaw of "the underlying method"? You have to target one (or both) of two separate virtual machines: a 32-bit VM for 32-bit hardware (or emulator) and a 64-bit VM for 64-bit hardware (only) - what's virtual about that? Java compiles once, for only one virtual machine, which of course has separate implementations for each platform (32 or 64).