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I'm having some doubts on how to correctly use the \valid annotation on structs.

struct someStruct{
    int size1;
    int size2;
    char *str1;
    char *str2;

A correct predicate to verify memory safety of the struct would be:

    predicate validStruct(struct someStruct *p) =
       \valid(p) && 
       \valid(p->str1+(0..((p->size1)-1))) && 


    predicate validStruct(struct someStruct *p) =
       // 16 bytes: 2 int * 4 bytes + 2 pointers* 4 bytes.
       // Although may depend on implementation and system arch
       \valid(p+(0..15) &&   
       \valid(p->str1+(0..((p->size1)-1))) && 

The first example assumes that \valid(p) (where p is a pointer to a structure) ensures memory safety on the structure it points to, whereas the second I must specify the range (taking into account the size of the memory fields) manually

Looking at the Stack example in ACSL by Example (page 125). They adopt the first example. However in many places \valid(some_string+(0..strlen(some_string))) is used to ensure memory safety on those specific memory locations.


In response to the answer given. A correct memory safety predicate for this (taken from stdio.h)

struct _IO_file {
    int _IO_fileno;     /* Underlying file descriptor */
    _Bool _IO_eof;      /* End of file flag */
    _Bool _IO_error;    /* Error flag */
typedef struct _IO_file FILE;

struct _IO_file_pvt {
    struct _IO_file pub;    /* Data exported to inlines */
    struct _IO_file_pvt *prev, *next;
    char *buf;      /* Buffer */
    char *data;     /* Location of input data in buffer */
    unsigned int ibytes;    /* Input data bytes in buffer */
    unsigned int obytes;    /* Output data bytes in buffer */
    unsigned int bufsiz;    /* Total size of buffer */
    enum _IO_bufmode bufmode; /* Type of buffering */

would be, for ex:


predicate valid_FILE(FILE *f) = 
    \valid(f) && f->_IO_fileno >= 0;

predicate valid_IO_file_pvt(struct _IO_file_pvt *f) = 
    // buffer offset
    && f->buf == (char *)f + ((sizeof(*f) + 4*sizeof(void *) - 1)
                                        & ~(4*sizeof(void *) - 1))
    // 16K
    && f->bufsiz == 16384
    && 0 <= f->ibytes <= f->bufsiz
    && 0 <= f->obytes <= f->bufsiz
    && valid_FILE(&(f->pub))
    && (f->next != \null ==> \valid(f->next))
    && (f->prev != \null ==> \valid(f->prev))
    // 16384 + 32 (ungetc_slop)
    && \valid(f->buf+(0..(f->bufsiz+32-1)))
    // data points to address in valid buffer region
    && f->buf <= f->data < (f->buf + f->bufsiz + 32)
share|improve this question
Regarding your valid_IO_file_pvt predicate, I guess that the line f->buf == (char *)f + ((sizeof(*f) + 4*sizeof(void *) - 1) & ~(4*sizeof(void *) - 1)) is meant to say that the buffer is adjacent to f itself, modulo alignment constraints. There are two issues here. First, I don't think that there is a Frama-C plugin that can take advantage of it. Second, the size of void * is undefined (gcc set it to 1, but not all compilers do). – Virgile Apr 3 '13 at 8:35
sizeof void *is 4 or 8 bytes on 32 bit or 64 bit machines, respectively. – Cristiano Sousa Apr 3 '13 at 23:23
Yes of course, sorry. I should have paid more attention to that little * after void... – Virgile Apr 4 '13 at 7:00
up vote 3 down vote accepted

Solution 1 is clearly the good one, as it abstracts over the memory layout chosen by your compiler, and by Cil within Frama-C.

Solution 2 is in fact incorrect as written. Your range p+(0..15) must be understood using pointer arithmetics on objects of type struct someStruct, and you are in fact requesting that p points to an area where 16 * sizeof(struct someStruct) bytes are valid.

A correct reformulation of solution 2, for standard memory layouts, would have been


In fact, the ACSL reference manual explicitly mentions the following equivalence page 56. (I have removed labels for clarity.)

\valid(p) <==> \valid(((char*)p)+(0..sizeof(*p))

For strings, the cast (char*)p becomes superfluous, as strings are already pointers to char. Thus, writing valid(p+(0..strlen(p)) requires that p points to a memory are where strlen(p)+1 bytes are valid -- but only because p has type char*, and sizeof(char)=1.

share|improve this answer
I still do not understand why i can do the second approach on strings but not on structs – Cristiano Sousa Mar 29 '13 at 20:46
Solution 2 works on C strings because they are in fact pointers to char. I have added a paragraph to explain this better. Hopefully this should clear things up. Notice that the file share/libc/__fc_string_axiomatic.h defines a predicate \valid_string that is a (often useful) shortcut to the definition used in ACSL by Example. – byako Mar 29 '13 at 21:16
Ok, i didn't look closely to the citation from the ACSL reference manual. I've edited my question with a more objective example. – Cristiano Sousa Mar 29 '13 at 22:32
Is this the same for the \separated clause? ie (on the first example): \separated(p, p->str1+(0..((p->size1)-1))) to guarantee that memory for the string does not overlap with the structure itself – Cristiano Sousa Mar 29 '13 at 23:48
Your formalizations of valid_FILE and valid_IO_file_pvt seem good. A few remarks, which I hope might be helpful: - it would be more general to define your predicates directly on the struct type, instead of on "pointer to struct": with your current formalization, you can express properties on \result - I suggest you drop the property f->buf == , which only holds for one implementation, and that you use a \separated clause instead – byako Apr 1 '13 at 21:05

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