Exception Implementation in the Mono Runtime Dietmar Maurer (dietmar@ximian.com) (C) 2001 Ximian, Inc. Exception implementation (jit): =============================== Stack unwinding: ================ We record the code address (start_address, size) of all methods. That way it is possible to map an instruction pointer (IP) to the method information needed for unwinding the stack: We also save a Last Managed Frame (LMF) structure at each call from managed to unmanaged code. That way we can recover from exceptions inside unmanaged code. void handle_exception ((struct sigcontext *ctx, gpointer obj) { if (ctx->bp < mono_end_of_stack) { /* unhandled exception */ abort (); } info = mono_jit_info_table_find (mono_jit_info_table, ctx->ip); if (info) { // we are inside managed code if (ch = find_catch_handler ()) execute_catch_handler (ch, ctx, obj); execute_all_finally_handler (); // restore register, including IP and Frame pointer ctx = restore_caller_saved_registers_from_ctx (ji, ctx); // continue unwinding handle_exception (ctx, obj); } else { lmf = get_last_managed_frame (); // restore register, including IP and Frame pointer ctx = restore_caller_saved_registers_from_lmf (ji, lmf); // continue unwinding handle_exception (ctx, obj); } } Code generation: ================ leave: is simply translated into a branch to the target. If the leave instruction is inside a finally block (but not inside another handler) we call the finally handler before we branch to the target. finally/endfinally, filter/endfilter: is translated into subroutine ending with a "return" statement. The subroutine does not save EBP, because we need access to the local variables of the enclosing method. Its is possible that instructions inside those handlers modify the stack pointer, thus we save the stack pointer at the start of the handler, and restore it at the end. We have to use a "call" instruction to execute such finally handlers. This makes it also possible to execute them inside the stack unwinding code. The exception object for filters is passed in a local variable (cfg->exvar). throw: we first save all regs into a sigcontext struct and then call the stack unwinding code. catch handler: catch hanlders are always called from the stack unwinding code. The exception object is passed in a local variable (cfg->exvar). gcc support for Exceptions ========================== gcc supports exceptions in files compiled with the -fexception option. gcc generates DWARF exceptions tables in that case, so it is possible to unwind the stack. The method to read those exception tables is contained in libgcc.a, and in newer versions of glibc (glibc 2.2.5 for example), and it is called __frame_state_for(). Another usable glibc function is backtrace_symbols() which returns the function name corresponding to a code address. We dynamically check if those features are available using g_module_symbol(), and we use them only when available. If not available we use the LMF as fallback. Using gcc exception information prevents us from saving the LMF at each native call, so this is a way to speed up native calls. This is especially valuable for internal calls, because we can make sure that all internal calls are compiled with -fexceptions (we compile the whole mono runtime with that option). All native function are able to call function without exception tables, and so we are unable to restore all caller saved registers if an exception is raised in such function. Well, its possible if the previous function already saves all registers. So we only omit the the LMF if a function has an exception table able to restore all caller saved registers. One problem is that gcc almost never saves all caller saved registers, because it is just unnecessary in normal situations. But there is a trick forcing gcc to save all register, we just need to call __builtin_unwind_init() at the beginning of a function. That way gcc generates code to save all caller saved register on the stack.