Cyclone (programming language)

The Cyclone programming language was intended to be a safe dialect of the C language.[2] It avoids buffer overflows and other vulnerabilities that are possible in C programs by design, without losing the power and convenience of C as a tool for system programming. It is no longer supported by its original developers, with the reference tooling not supporting 64-bit platforms. The Rust language is mentioned by the original developers for having integrated many of the same ideas Cyclone had.[3]

Cyclone
Designed byAT&T Labs
DeveloperCornell University
First appeared2002; 22 years ago (2002)
Stable release
1.0 / May 8, 2006; 18 years ago (2006-05-08)
Websitecyclone.thelanguage.org
Influenced by
C
Influenced
Rust, Project Verona

Cyclone development was started as a joint project of Trevor Jim from AT&T Labs Research and Greg Morrisett's group at Cornell University in 2001. Version 1.0 was released on May 8, 2006.[4]

Language features

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Cyclone attempts to avoid some of the common pitfalls of C, while still maintaining its look and performance. To this end, Cyclone places the following limits on programs:

To maintain the tool set that C programmers are used to, Cyclone provides the following extensions:

  • Never-NULL pointers do not require NULL checks
  • "Fat" pointers support pointer arithmetic with run-time bounds checking
  • Growable regions support a form of safe manual memory management
  • Garbage collection for heap-allocated values
  • Tagged unions support type-varying arguments
  • Injections help automate the use of tagged unions for programmers
  • Polymorphism replaces some uses of void *
  • varargs are implemented as fat pointers
  • Exceptions replace some uses of setjmp and longjmp

For a better high-level introduction to Cyclone, the reasoning behind Cyclone and the source of these lists, see this paper.

Cyclone looks, in general, much like C, but it should be viewed as a C-like language.

Pointer types

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Cyclone implements three kinds of pointer:

The purpose of introducing these new pointer types is to avoid common problems when using pointers. Take for instance a function, called foo that takes a pointer to an int:

 int foo(int *);

Although the person who wrote the function foo could have inserted NULL checks, let us assume that for performance reasons they did not. Calling foo(NULL); will result in undefined behavior (typically, although not necessarily, a SIGSEGV signal being sent to the application). To avoid such problems, Cyclone introduces the @ pointer type, which can never be NULL. Thus, the "safe" version of foo would be:

 int foo(int @);

This tells the Cyclone compiler that the argument to foo should never be NULL, avoiding the aforementioned undefined behavior. The simple change of * to @ saves the programmer from having to write NULL checks and the operating system from having to trap NULL pointer dereferences. This extra limit, however, can be a rather large stumbling block for most C programmers, who are used to being able to manipulate their pointers directly with arithmetic. Although this is desirable, it can lead to buffer overflows and other "off-by-one"-style mistakes. To avoid this, the ? pointer type is delimited by a known bound, the size of the array. Although this adds overhead due to the extra information stored about the pointer, it improves safety and security. Take for instance a simple (and naïve) strlen function, written in C:

 int strlen(const char *s)
 {
     int i = 0;
     if (s == NULL)
        return 0;
     while (s[i] != '\0') {
        i++;
     }
     return i;
 }

This function assumes that the string being passed in is terminated by '\0'. However, what would happen if char buf[6] = {'h','e','l','l','o','!'}; were passed to this string? This is perfectly legal in C, yet would cause strlen to iterate through memory not necessarily associated with the string s. There are functions, such as strnlen which can be used to avoid such problems, but these functions are not standard with every implementation of ANSI C. The Cyclone version of strlen is not so different from the C version:

 int strlen(const char ? s)
 {
    int i, n = s.size;
    if (s == NULL)
       return 0;
    for (i = 0; i < n; i++, s++)
       if (*s == '\0')
          return i;
    return n;
 }

Here, strlen bounds itself by the length of the array passed to it, thus not going over the actual length. Each of the kinds of pointer type can be safely cast to each of the others, and arrays and strings are automatically cast to ? by the compiler. (Casting from ? to * invokes a bounds check, and casting from ? to @ invokes both a NULL check and a bounds check. Casting from * to ? results in no checks whatsoever; the resulting ? pointer has a size of 1.)

Dangling pointers and region analysis

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Consider the following code, in C:

 char *itoa(int i)
 {
    char buf[20];
    sprintf(buf,"%d",i);
    return buf;
 }

The function itoa allocates an array of chars buf on the stack and returns a pointer to the start of buf. However, the memory used on the stack for buf is deallocated when the function returns, so the returned value cannot be used safely outside of the function. While GNU Compiler Collection and other compilers will warn about such code, the following will typically compile without warnings:

 char *itoa(int i)
 {
    char buf[20], *z;
    sprintf(buf,"%d",i);
    z = buf;
    return z;
 }

GNU Compiler Collection can produce warnings for such code as a side-effect of option -O2 or -O3, but there are no guarantees that all such errors will be detected. Cyclone does regional analysis of each segment of code, preventing dangling pointers, such as the one returned from this version of itoa. All of the local variables in a given scope are considered to be part of the same region, separate from the heap or any other local region. Thus, when analyzing itoa, the Cyclone compiler would see that z is a pointer into the local stack, and would report an error.

See also

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References

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  1. ^ "Open Access Cyclone (programming language) Journals · OA.mg". oa.mg. Archived from the original on 30 October 2022. Retrieved 30 October 2022.
  2. ^ Jim, Trevor; Morrisett, J. Greg; Grossman, Dan; Hicks, Michael W.; Cheney, James; Wang, Yanling (10 June 2002). "Cyclone: A Safe Dialect of C". Proceedings of the General Track of the Annual Conference on USENIX Annual Technical Conference. ATEC '02. USA: USENIX Association: 275–288. doi:10.5555/647057.713871 (inactive 1 November 2024). ISBN 978-1-880446-00-3.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link) CS1 maint: ignored DOI errors (link)
  3. ^ "Cyclone". cyclone.thelanguage.org. Archived from the original on 21 May 2006. Retrieved 11 December 2023.
  4. ^ "Cyclone". Cornell University. Archived from the original on 15 October 2022. Retrieved 30 October 2022.
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