Jonathan S. Shapiro
2008-May-14 13:27 UTC
[LLVMdev] malloc, magic, and embedded compilation
The discussion of malloc optimization from two (three?) weeks ago prompts me to be concerned about implications for kernel compilation. Basically, I have two questions: 1. The particular optimization that was done there was based on the compiler substituting an alternate implementation of malloc(). This may not be appropriate in kernel or deeply embedded systems. Is there a way for someone who is building that sort of system to enable/disable the builtin library magic selectively? I assume that LLVM can support compiling for a "freestanding" C library, and that this should disable everything of this sort, but it would be useful to be able to then selectively re-enable things like memcpy. 2. The particular optimization in that case was also based on knowledge that main() is not re-entrant, main() called f() once, f() called malloc() once, and therefore that call to malloc() could be partially evaluated at compile time. In kernels and such, main() is not the only entry point and this particular optimization can't be done safely without a whole-program view of all entry points. What options do we need to provide to deal with this sort of thing? shap
> 1. The particular optimization that was done there was based on the > compiler substituting an alternate implementation of malloc(). This may > not be appropriate in kernel or deeply embedded systems. Is there a way > for someone who is building that sort of system to enable/disable the > builtin library magic selectively?-ffreestanding> I assume that LLVM can support compiling for a "freestanding" C library, > and that this should disable everything of this sort, but it would be > useful to be able to then selectively re-enable things like memcpy. > > 2. The particular optimization in that case was also based on knowledge > that main() is not re-entrant, main() called f() once, f() called > malloc() once, and therefore that call to malloc() could be partially > evaluated at compile time. In kernels and such, main() is not the only > entry point and this particular optimization can't be done safely > without a whole-program view of all entry points. > > What options do we need to provide to deal with this sort of thing?I don't think the logic is based on "main", but on whether functions are marked "internal" or not. That said, GlobalOpt.cpp seems to reason based on the name "main" (most likely bogus, because of constructors/ destructors running before main). Ciao, Duncan.
Jonathan S. Shapiro
2008-May-14 14:45 UTC
[LLVMdev] malloc, magic, and embedded compilation
On Wed, 2008-05-14 at 16:15 +0200, Duncan Sands wrote:> I don't think the logic is based on "main", but on whether functions > are marked "internal" or not. That said, GlobalOpt.cpp seems to reason > based on the name "main" (most likely bogus, because of constructors/ > destructors running before main).Umm. That sounds like a test case that really wants to get written. Does the LLVM C front-end support the "init" attribute for C functions (which has similar effect)? shap
On May 14, 2008, at 7:15 AM, Duncan Sands wrote:>> 1. The particular optimization that was done there was based on the >> compiler substituting an alternate implementation of malloc(). This >> may >> not be appropriate in kernel or deeply embedded systems. Is there a >> way >> for someone who is building that sort of system to enable/disable the >> builtin library magic selectively? > > -ffreestandingThe flag to disable assumptions about library functions selectively is -fno-builtin, if that's actually what you want. -ffreestanding is not quite the same; it also disables special semantics for "main" and changes the predefinition of __STDC_HOSTED__.>> I assume that LLVM can support compiling for a "freestanding" C >> library, >> and that this should disable everything of this sort, but it would be >> useful to be able to then selectively re-enable things like memcpy. >> >> 2. The particular optimization in that case was also based on >> knowledge >> that main() is not re-entrant, main() called f() once, f() called >> malloc() once, and therefore that call to malloc() could be partially >> evaluated at compile time. In kernels and such, main() is not the >> only >> entry point and this particular optimization can't be done safely >> without a whole-program view of all entry points. >> >> What options do we need to provide to deal with this sort of thing? > > I don't think the logic is based on "main", but on whether functions > are marked "internal" or not. That said, GlobalOpt.cpp seems to > reason > based on the name "main" (most likely bogus, because of constructors/ > destructors running before main). > > Ciao, > > Duncan. > _______________________________________________ > LLVM Developers mailing list > LLVMdev at cs.uiuc.edu http://llvm.cs.uiuc.edu > http://lists.cs.uiuc.edu/mailman/listinfo/llvmdev
On Wed, May 14, 2008 at 8:27 AM, Jonathan S. Shapiro <shap at eros-os.com> wrote:> 1. The particular optimization that was done there was based on the > compiler substituting an alternate implementation of malloc(). This may > not be appropriate in kernel or deeply embedded systems. Is there a way > for someone who is building that sort of system to enable/disable the > builtin library magic selectively?After compiling a few kernels with llvm (with LTO), I haven't seen one yet that names any of it's allocators 'malloc', so in that case it's kind of a moot point. As for the matter of entry points, this isn't a problem either lots of things in a kernel (if properly marked 'used') don't get internalized, so you don't wind up with a bytecode that has a single entry point named 'main'. Oh, and main isn't a popular name for kernel entry anyway. Andrew
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