Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Lisp syntax represents AST as far as I know, but in high level format to allow human to easily read and modify, at the same time make it easy for the machine to process the source code as well.

For this reason, in Lisp, it is said that code is data and data is code, since code (s-epxression) is just AST, in essence. We can plug in more ASTs (which is our data, which is just lisp code) into other ASTs (lisp code) or independently to extend its functionality and manipulate it on the fly (runtime) without having to recompile the whole OS to integrate new code.In other languages, we have to recompile from to turn the human-language source code into valid AST before it is compiled into code.

Is this the reason for Lisp syntax to be designed like it is (represent an AST but is human readable, to satisfy both human and the machine) in the first place? To enable stronger (on the fly - runtime) as well as simpler (no recompile, faster) communication between man-machine?

I heard that the Lisp machine only has a single address space which holds all data. In operating system like Linux, the programmers only have virtual address space and pretend it to be the real physical address space and can do whatever they want. Data and code in Linux are separated regions, because effectively, data is data and data is code. In normal OS written in C (or C like language), it would be very messy if we only operate a single address space for the whole system and mixing data with code would be very messy.

In Lisp Machine, since code is data and data is code, is this the reason for this to have only a single address space (without the virtual layer)? Since we have GC and no pointer, should it be safe to operate on physical memory without breaking it (since having only 1 single space is a lot less complicated)?

EDIT: I ask this because it is said that one of the advantage of Lisp is single address space:

A safe language means a reliable environment without the need to separate tasks out into their own separate memory spaces.

The "clearly separated process" model characteristic of Unix has potent merits when dealing with software that might be unreliable to the point of being unsafe, as is the case with code written in C or C++ , where an invalid pointer access can "take down the system." MS-DOS and its heirs are very unreliable in that sense, where just about any program bug can take the whole system down; "Blue Screen of Death" and the likes.

If the whole system is constructed and coded in Lisp, the system is as reliable as the Lisp environment. Typically this is quite safe, as once you get to the standards-compliant layers, they are quite reliable, and don't offer direct pointer access that would allow the system to self-destruct.

Third Law of Sane Personal Computing

Volatile storage devices (i.e. RAM) shall serve exclusively as read/write cache for non-volatile storage devices. From the perspective of all software except for the operating system, the machine must present a single address space which can be considered non-volatile. No computer system obeys this law which takes longer to fully recover its state from a disruption of its power source than an electric lamp would.

Single address space, as it is stated, holds all the running processes in the same memory space. I am just curious why people insist that single address space is better. I relate it to the AST like syntax of Lisp, to try to explain how it fits the single space model.

share|improve this question
    
Data is never code, common misconception. –  leppie Jul 4 '12 at 6:46
    
Short answer is: macros. Having this kind of a syntax simplifies code generation in macros significantly, and it overweights all the possible downsides. And it all has nothing to do with the actual memory model. Compiled Lisp code has nothing to do with S-expressions anyway, just as compiled C code has nothing to do with all those curly braces. –  SK-logic Jul 4 '12 at 8:06
    
@SK-logic As for macro, I only learn the basic of it. Haven't tried much of it since it is supposed to be for advance Lispers. I often heard that Lisp syntax is compiler friendly, and I am referring to the Lisp machine which supports Lisp natively, so the syntax should have something to do with parentheses. –  Amumu Jul 4 '12 at 9:49
2  
@Amumu, Lisp machines would not "natively" interpret you S-expressions any way. They're only different from the other ISAs in their selection of the instructions and in a hardware garbage collector. You'll see the same in Java- or Ada-centric processors as well. There is no connection whatsoever with the syntax. Lisp syntax is compiler-friendly in that sense that it allows you to extend compiler easily (with the macros). It does not make much sense without the macros, since parsing is cheap and easy any way, it might become a problem only if you try to introduce some form of quasiquotation. –  SK-logic Jul 4 '12 at 10:35
1  
@Amumu, take a look at, say, LOOP macro in Common Lisp. Or, as another extreme, this complete language overhaul made on top of macros only: bit.ly/vqqvHU –  SK-logic Jul 4 '12 at 11:57

1 Answer 1

up vote 3 down vote accepted

Your question doesn't reflect reality very accurately, especially in the part about code/data separation in Linux and other OS'es. Actually, this separation is enforced not at the OS level, but by the compiler/program loader. At the OS level there are just memory pages that can have different protection bits set (like executable, read-only etc), and above this level different executable formats exist (like ELF in Linux) that specify restrictions on different parts of program memory.

Returning to Lisp, as far as I know, historically, the S-expression format was used by Lisp creators, because they wanted to concentrate on the semantics of the language, putting syntax aside for some time. There was a plan to eventually create some syntax for Lisp (see M-expressions), and there were some Lisp-based languages which had some more syntax, like Dylan. But, overall, the Lisp community had come to the consensus, that the benefits of S-expressions outweight their cons, so they had stuck.

Regarding code as data, this is not strictly bound to S-expressions, as other code can as well be treated as data. This whole approach is called meta-programming and is supported at different levels and with different mechanisms by many languages. Every language, that supports eval (Perl, JavaScript, Python) allows to treat code as data, just the representation is almost always a string, while in Lisp it is a tree, which is much much more convenient and facilitates advanced stuff, like macros.

share|improve this answer
    
It depends on how you views the OS level. Of course the OS operate memory using pages as its basic unit, but the memory layout is organized using the same model: one segment for code, one segment for data, one segment for bss, one for stack and one for heap. This is the same, except it's in physical space. –  Amumu Jul 4 '12 at 7:25
    
Initially, there were S expressions and M expressions. M expressions were intended to be used by the programmer, with a component translating them to the (internal) S expression format. The M expressions were deemed important, but slated for implementation "later" and that later never really arrived. –  Vatine Jul 4 '12 at 9:08
    
@Amumu those segments are defined by the program loader. Most of modern OSes use flat memory model, so the segments are not mapped to memory segments (in memory segmentation model sense), they are just mapped to pages in some way or the other, and the pages are marked appropriately. It is quite possible to create a different program loader, that will use the pages differently –  Vsevolod Dyomkin Jul 5 '12 at 7:51

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.