Hi, This is the 4th version of the patch.
It based on the following proposal: https://gcc.gnu.org/pipermail/gcc-patches/2023-November/635884.html Represent the missing dependence for the "counted_by" attribute and its consumers ******The summary of the proposal is: * Add a new internal function ".ACCESS_WITH_SIZE" to carry the size information for every reference to a FAM field; * In C FE, Replace every reference to a FAM field whose TYPE has the "counted_by" attribute with the new internal function ".ACCESS_WITH_SIZE"; * In every consumer of the size information, for example, BDOS or array bound sanitizer, query the size information or ACCESS_MODE information from the new internal function; * When expansing to RTL, replace the internal function with the actual reference to the FAM field; * Some adjustment to ipa alias analysis, and other SSA passes to mitigate the impact to the optimizer and code generation. ******The new internal function .ACCESS_WITH_SIZE (REF_TO_OBJ, REF_TO_SIZE, CLASS_OF_SIZE, SIZE_OF_SIZE, ACCESS_MODE, INDEX) INTERNAL_FN (ACCESS_WITH_SIZE, ECF_LEAF | ECF_NOTHROW, NULL) which returns the "REF_TO_OBJ" same as the 1st argument; Both the return type and the type of the first argument of this function have been converted from the incomplete array type to the corresponding pointer type. Please see the following link for why: https://gcc.gnu.org/pipermail/gcc-patches/2023-November/638793.html https://gcc.gnu.org/pipermail/gcc-patches/2023-December/639605.html 1st argument "REF_TO_OBJ": The reference to the object; 2nd argument "REF_TO_SIZE": The reference to the size of the object, 3rd argument "CLASS_OF_SIZE": The size referenced by the REF_TO_SIZE represents 0: unknown; 1: the number of the elements of the object type; 2: the number of bytes; 4th argument "PRECISION_OF_SIZE": The precision of the integer that REF_TO_SIZE points; 5th argument "ACCESS_MODE": -1: Unknown access semantics 0: none 1: read_only 2: write_only 3: read_write 6th argument "INDEX": the INDEX for the original array reference. -1: Unknown NOTE: The 6th Argument is added for bound sanitizer instrumentation. ****** The Patch sets included: 1. Provide counted_by attribute to flexible array member field; which includes: * "counted_by" attribute documentation; * C FE handling of the new attribute; syntax checking, error reporting; * testing cases; 2. Convert "counted_by" attribute to/from .ACCESS_WITH_SIZE. which includes: * The definition of the new internal function .ACCESS_WITH_SIZE in internal-fn.def. * C FE converts every reference to a FAM with "counted_by" attribute to a call to the internal function .ACCESS_WITH_SIZE. (build_component_ref in c_typeck.cc) This includes the case when the object is statically allocated and initialized. In order to make this working, we should update initializer_constant_valid_p_1 and output_constant in varasm.cc to include calls to .ACCESS_WITH_SIZE. However, for the reference inside "offsetof", ignore the "counted_by" attribute since it's not useful at all. (c_parser_postfix_expression in c/c-parser.cc) * Convert every call to .ACCESS_WITH_SIZE to its first argument. (expand_ACCESS_WITH_SIZE in internal-fn.cc) * adjust alias analysis to exclude the new internal from clobbering anything. (ref_maybe_used_by_call_p_1 and call_may_clobber_ref_p_1 in tree-ssa-alias.cc) * adjust dead code elimination to eliminate the call to .ACCESS_WITH_SIZE when it's LHS is eliminated as dead code. (eliminate_unnecessary_stmts in tree-ssa-dce.cc) * Provide the utility routines to check the call is .ACCESS_WITH_SIZE and get the reference from the call to .ACCESS_WITH_SIZE. (is_access_with_size_p and get_ref_from_access_with_size in tree.cc) * testing cases. (for offsetof, static initialization, generation of calls to .ACCESS_WITH_SIZE, code runs correctly after calls to .ACCESS_WITH_SIZE are converted back) 3. Use the .ACCESS_WITH_SIZE in builtin object size (sub-object only) which includes: * use the size info of the .ACCESS_WITH_SIZE for sub-object. * testing cases. 4 Use the .ACCESS_WITH_SIZE in bound sanitizer Since the result type of the call to .ACCESS_WITH_SIZE is a pointer to the element type. The original array_ref is converted to an indirect_ref, which introduced two issues for the instrumenation of bound sanitizer: A. The index for the original array_ref was mixed into the offset expression for the new indirect_ref. In order to make the instrumentation for the bound sanitizer easier, one more argument for the function .ACCESS_WITH_SIZE is added to record this original index for the array_ref. then later during bound instrumentation, get the index from the additional argument from the call to the function .ACCESS_WITH_SIZE. B. In the current bound sanitizer, no instrumentation will be inserted for an indirect_ref. In order to add instrumentation for an indirect_ref with a call to .ACCESS_WITH_SIZE, we should specially handle the indirect_ref with a call to .ACCESS_WITH_SIZE, and get the index and bound info from the arguments of the call. which includes: * Record the index to the 6th argument of the call to .ACCESS_WITH_SIZE. * Instrument indirect_ref with call to .ACCESS_WITH_SIZE for bound sanitizer. * testing cases. (additional testing cases for dynamic array support) ******Remaining works: 5 Improve __bdos to use the counted_by info in whole-object size for the structure with FAM. 6 Emit warnings when the user breaks the requirments for the new counted_by attribute compilation time: -Wcounted-by run time: -fsanitizer=counted-by * The initialization to the size field should be done before the first reference to the FAM field. * the array has at least # of elements specified by the size field all the time during the program. I have bootstrapped and regression tested on both x86 and aarch64, no issue. Let me know your comments. thanks. Qing
