coregrind/m_machine.c - fp2-dev/platform/external/valgrind - Gitiles


 /*--------------------------------------------------------------------*/
 /*--- Machine-related stuff.                           m_machine.c ---*/
 /*--------------------------------------------------------------------*/

 /*
    This file is part of Valgrind, a dynamic binary instrumentation
    framework.

    Copyright (C) 2000-2005 Julian Seward
       jseward@acm.org

    This program is free software; you can redistribute it and/or
    modify it under the terms of the GNU General Public License as
    published by the Free Software Foundation; either version 2 of the
    License, or (at your option) any later version.

    This program is distributed in the hope that it will be useful, but
    WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
    General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program; if not, write to the Free Software
    Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
    02111-1307, USA.

    The GNU General Public License is contained in the file COPYING.
 */

 #include "pub_core_basics.h"
 #include "pub_core_threadstate.h"
 #include "pub_core_libcassert.h"
 #include "pub_core_libcbase.h"
 #include "pub_core_machine.h"

 #define INSTR_PTR(regs)    ((regs).vex.VG_INSTR_PTR)
 #define STACK_PTR(regs)    ((regs).vex.VG_STACK_PTR)
 #define FRAME_PTR(regs)    ((regs).vex.VG_FRAME_PTR)

 Addr VG_(get_SP) ( ThreadId tid )
 {
    return STACK_PTR( VG_(threads)[tid].arch );
 }

 Addr VG_(get_IP) ( ThreadId tid )
 {
    return INSTR_PTR( VG_(threads)[tid].arch );
 }

 Addr VG_(get_FP) ( ThreadId tid )
 {
    return FRAME_PTR( VG_(threads)[tid].arch );
 }

 Addr VG_(get_LR) ( ThreadId tid )
 {
 #  if defined(VGA_ppc32)
    return VG_(threads)[tid].arch.vex.guest_LR;
 #  elif defined(VGA_x86) || defined(VGA_amd64)
    return 0;
 #  else
 #    error "Unknown arch"
 #  endif
 }

 void VG_(set_SP) ( ThreadId tid, Addr sp )
 {
    STACK_PTR( VG_(threads)[tid].arch ) = sp;
 }

 void VG_(set_IP) ( ThreadId tid, Addr ip )
 {
    INSTR_PTR( VG_(threads)[tid].arch ) = ip;
 }


 void VG_(get_shadow_regs_area) ( ThreadId tid, OffT offset, SizeT size,
                                  UChar* area )
 {
    ThreadState* tst;

    vg_assert(VG_(is_valid_tid)(tid));
    tst = & VG_(threads)[tid];

    // Bounds check
    vg_assert(0 <= offset && offset < sizeof(VexGuestArchState));
    vg_assert(offset + size <= sizeof(VexGuestArchState));

    VG_(memcpy)( area, (void*)(((Addr)&(tst->arch.vex_shadow)) + offset), size);
 }

 void VG_(set_shadow_regs_area) ( ThreadId tid, OffT offset, SizeT size,
                                  const UChar* area )
 {
    ThreadState* tst;

    vg_assert(VG_(is_valid_tid)(tid));
    tst = & VG_(threads)[tid];

    // Bounds check
    vg_assert(0 <= offset && offset < sizeof(VexGuestArchState));
    vg_assert(offset + size <= sizeof(VexGuestArchState));

    VG_(memcpy)( (void*)(((Addr)(&tst->arch.vex_shadow)) + offset), area, size);
 }


 static void apply_to_GPs_of_tid(VexGuestArchState* vex, void (*f)(Addr))
 {
 #if defined(VGA_x86)
    (*f)(vex->guest_EAX);
    (*f)(vex->guest_ECX);
    (*f)(vex->guest_EDX);
    (*f)(vex->guest_EBX);
    (*f)(vex->guest_ESI);
    (*f)(vex->guest_EDI);
    (*f)(vex->guest_ESP);
    (*f)(vex->guest_EBP);
 #elif defined(VGA_amd64)
    (*f)(vex->guest_RAX);
    (*f)(vex->guest_RCX);
    (*f)(vex->guest_RDX);
    (*f)(vex->guest_RBX);
    (*f)(vex->guest_RSI);
    (*f)(vex->guest_RDI);
    (*f)(vex->guest_RSP);
    (*f)(vex->guest_RBP);
    (*f)(vex->guest_R8);
    (*f)(vex->guest_R9);
    (*f)(vex->guest_R10);
    (*f)(vex->guest_R11);
    (*f)(vex->guest_R12);
    (*f)(vex->guest_R13);
    (*f)(vex->guest_R14);
    (*f)(vex->guest_R15);
 #elif defined(VGA_ppc32)
    /* XXX ask tool about validity? */
    (*f)(vex->guest_GPR0);
    (*f)(vex->guest_GPR1);
    (*f)(vex->guest_GPR2);
    (*f)(vex->guest_GPR3);
    (*f)(vex->guest_GPR4);
    (*f)(vex->guest_GPR5);
    (*f)(vex->guest_GPR6);
    (*f)(vex->guest_GPR7);
    (*f)(vex->guest_GPR8);
    (*f)(vex->guest_GPR9);
    (*f)(vex->guest_GPR10);
    (*f)(vex->guest_GPR11);
    (*f)(vex->guest_GPR12);
    (*f)(vex->guest_GPR13);
    (*f)(vex->guest_GPR14);
    (*f)(vex->guest_GPR15);
    (*f)(vex->guest_GPR16);
    (*f)(vex->guest_GPR17);
    (*f)(vex->guest_GPR18);
    (*f)(vex->guest_GPR19);
    (*f)(vex->guest_GPR20);
    (*f)(vex->guest_GPR21);
    (*f)(vex->guest_GPR22);
    (*f)(vex->guest_GPR23);
    (*f)(vex->guest_GPR24);
    (*f)(vex->guest_GPR25);
    (*f)(vex->guest_GPR26);
    (*f)(vex->guest_GPR27);
    (*f)(vex->guest_GPR28);
    (*f)(vex->guest_GPR29);
    (*f)(vex->guest_GPR30);
    (*f)(vex->guest_GPR31);
    (*f)(vex->guest_CTR);
    (*f)(vex->guest_LR);

 #else
 #  error Unknown arch
 #endif
 }


 void VG_(apply_to_GP_regs)(void (*f)(UWord))
 {
    ThreadId tid;

    for (tid = 1; tid < VG_N_THREADS; tid++) {
       if (VG_(is_valid_tid)(tid)) {
          ThreadState* tst = VG_(get_ThreadState)(tid);
          apply_to_GPs_of_tid(&(tst->arch.vex), f);
       }
    }
 }

 static ThreadId thread_stack_iter = VG_INVALID_THREADID;

 void VG_(thread_stack_reset_iter)(void)
 {
    thread_stack_iter = 1;
 }

 Bool VG_(thread_stack_next)(ThreadId* tid, Addr* stack_min, Addr* stack_max)
 {
    ThreadId i;
    for (i = thread_stack_iter; i < VG_N_THREADS; i++) {
       if (VG_(threads)[i].status != VgTs_Empty) {
          *tid       = i;
          *stack_min = VG_(get_SP)(i);
          *stack_max = VG_(threads)[i].client_stack_highest_word;
          thread_stack_iter = i + 1;
          return True;
       }
    }
    return False;
 }

 //////////////////////////////////////////////////////////////////
 // Architecture specifics

 // PPC: what is the cache line size (for dcbz etc) ?  This info is
 // harvested on Linux at startup from the AT_SYSINFO entries.  0 means
 // not-yet-set.
 #if defined(VGA_ppc32)
 Int VG_(cache_line_size_ppc32) = 0;
 #endif

 // X86: set to 1 if the host is able to do {ld,st}mxcsr (load/store
 // the SSE control/status register.  For most modern CPUs this will be
 // 1.  It is set to 1, if possible, by m_translate.getArchAndArchInfo.
 // The value is read by m_dispatch.dispatch-x86.S, which is why it
 // is an Int rather than a Bool.
 //
 // Ugly hack: this has to start as 0 and be set to 1 in the normal
 // case, rather than the other way round, because the dispatch
 // loop needs it, and it runs before the first translation is
 // made.  Yet it is the act of making that first translation which
 // causes getArchAndArchInfo to set this value to its final value.
 // So it is necessary to start this value off at 0 as only that
 // guarantees that the dispatch loop will not SIGILL on its first
 // attempt.
 #if defined(VGA_x86)
 Int VG_(have_mxcsr_x86) = 0;
 #endif


 /*--------------------------------------------------------------------*/
 /*--- end                                                          ---*/
 /*--------------------------------------------------------------------*/

	/--------------------------------------------------------------------/
	/--- Machine-related stuff. m_machine.c ---/
	/--------------------------------------------------------------------/

	/*
	This file is part of Valgrind, a dynamic binary instrumentation
	framework.

	Copyright (C) 2000-2005 Julian Seward
	jseward@acm.org

	This program is free software; you can redistribute it and/or
	modify it under the terms of the GNU General Public License as
	published by the Free Software Foundation; either version 2 of the
	License, or (at your option) any later version.

	This program is distributed in the hope that it will be useful, but
	WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program; if not, write to the Free Software
	Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
	02111-1307, USA.

	The GNU General Public License is contained in the file COPYING.
	*/

	#include "pub_core_basics.h"
	#include "pub_core_threadstate.h"
	#include "pub_core_libcassert.h"
	#include "pub_core_libcbase.h"
	#include "pub_core_machine.h"

	#define INSTR_PTR(regs) ((regs).vex.VG_INSTR_PTR)
	#define STACK_PTR(regs) ((regs).vex.VG_STACK_PTR)
	#define FRAME_PTR(regs) ((regs).vex.VG_FRAME_PTR)

	Addr VG_(get_SP) ( ThreadId tid )
	{
	return STACK_PTR( VG_(threads)[tid].arch );
	}

	Addr VG_(get_IP) ( ThreadId tid )
	{
	return INSTR_PTR( VG_(threads)[tid].arch );
	}

	Addr VG_(get_FP) ( ThreadId tid )
	{
	return FRAME_PTR( VG_(threads)[tid].arch );
	}

	Addr VG_(get_LR) ( ThreadId tid )
	{
	# if defined(VGA_ppc32)
	return VG_(threads)[tid].arch.vex.guest_LR;
	# elif defined(VGA_x86) \|\| defined(VGA_amd64)
	return 0;
	# else
	# error "Unknown arch"
	# endif
	}

	void VG_(set_SP) ( ThreadId tid, Addr sp )
	{
	STACK_PTR( VG_(threads)[tid].arch ) = sp;
	}

	void VG_(set_IP) ( ThreadId tid, Addr ip )
	{
	INSTR_PTR( VG_(threads)[tid].arch ) = ip;
	}


	void VG_(get_shadow_regs_area) ( ThreadId tid, OffT offset, SizeT size,
	UChar* area )
	{
	ThreadState* tst;

	vg_assert(VG_(is_valid_tid)(tid));
	tst = & VG_(threads)[tid];

	// Bounds check
	vg_assert(0 <= offset && offset < sizeof(VexGuestArchState));
	vg_assert(offset + size <= sizeof(VexGuestArchState));

	VG_(memcpy)( area, (void*)(((Addr)&(tst->arch.vex_shadow)) + offset), size);
	}

	void VG_(set_shadow_regs_area) ( ThreadId tid, OffT offset, SizeT size,
	const UChar* area )
	{
	ThreadState* tst;

	vg_assert(VG_(is_valid_tid)(tid));
	tst = & VG_(threads)[tid];

	// Bounds check
	vg_assert(0 <= offset && offset < sizeof(VexGuestArchState));
	vg_assert(offset + size <= sizeof(VexGuestArchState));

	VG_(memcpy)( (void*)(((Addr)(&tst->arch.vex_shadow)) + offset), area, size);
	}


	static void apply_to_GPs_of_tid(VexGuestArchState* vex, void (*f)(Addr))
	{
	#if defined(VGA_x86)
	(*f)(vex->guest_EAX);
	(*f)(vex->guest_ECX);
	(*f)(vex->guest_EDX);
	(*f)(vex->guest_EBX);
	(*f)(vex->guest_ESI);
	(*f)(vex->guest_EDI);
	(*f)(vex->guest_ESP);
	(*f)(vex->guest_EBP);
	#elif defined(VGA_amd64)
	(*f)(vex->guest_RAX);
	(*f)(vex->guest_RCX);
	(*f)(vex->guest_RDX);
	(*f)(vex->guest_RBX);
	(*f)(vex->guest_RSI);
	(*f)(vex->guest_RDI);
	(*f)(vex->guest_RSP);
	(*f)(vex->guest_RBP);
	(*f)(vex->guest_R8);
	(*f)(vex->guest_R9);
	(*f)(vex->guest_R10);
	(*f)(vex->guest_R11);
	(*f)(vex->guest_R12);
	(*f)(vex->guest_R13);
	(*f)(vex->guest_R14);
	(*f)(vex->guest_R15);
	#elif defined(VGA_ppc32)
	/* XXX ask tool about validity? */
	(*f)(vex->guest_GPR0);
	(*f)(vex->guest_GPR1);
	(*f)(vex->guest_GPR2);
	(*f)(vex->guest_GPR3);
	(*f)(vex->guest_GPR4);
	(*f)(vex->guest_GPR5);
	(*f)(vex->guest_GPR6);
	(*f)(vex->guest_GPR7);
	(*f)(vex->guest_GPR8);
	(*f)(vex->guest_GPR9);
	(*f)(vex->guest_GPR10);
	(*f)(vex->guest_GPR11);
	(*f)(vex->guest_GPR12);
	(*f)(vex->guest_GPR13);
	(*f)(vex->guest_GPR14);
	(*f)(vex->guest_GPR15);
	(*f)(vex->guest_GPR16);
	(*f)(vex->guest_GPR17);
	(*f)(vex->guest_GPR18);
	(*f)(vex->guest_GPR19);
	(*f)(vex->guest_GPR20);
	(*f)(vex->guest_GPR21);
	(*f)(vex->guest_GPR22);
	(*f)(vex->guest_GPR23);
	(*f)(vex->guest_GPR24);
	(*f)(vex->guest_GPR25);
	(*f)(vex->guest_GPR26);
	(*f)(vex->guest_GPR27);
	(*f)(vex->guest_GPR28);
	(*f)(vex->guest_GPR29);
	(*f)(vex->guest_GPR30);
	(*f)(vex->guest_GPR31);
	(*f)(vex->guest_CTR);
	(*f)(vex->guest_LR);

	#else
	# error Unknown arch
	#endif
	}


	void VG_(apply_to_GP_regs)(void (*f)(UWord))
	{
	ThreadId tid;

	for (tid = 1; tid < VG_N_THREADS; tid++) {
	if (VG_(is_valid_tid)(tid)) {
	ThreadState* tst = VG_(get_ThreadState)(tid);
	apply_to_GPs_of_tid(&(tst->arch.vex), f);
	}
	}
	}

	static ThreadId thread_stack_iter = VG_INVALID_THREADID;

	void VG_(thread_stack_reset_iter)(void)
	{
	thread_stack_iter = 1;
	}

	Bool VG_(thread_stack_next)(ThreadId* tid, Addr* stack_min, Addr* stack_max)
	{
	ThreadId i;
	for (i = thread_stack_iter; i < VG_N_THREADS; i++) {
	if (VG_(threads)[i].status != VgTs_Empty) {
	*tid = i;
	*stack_min = VG_(get_SP)(i);
	*stack_max = VG_(threads)[i].client_stack_highest_word;
	thread_stack_iter = i + 1;
	return True;
	}
	}
	return False;
	}

	//////////////////////////////////////////////////////////////////
	// Architecture specifics

	// PPC: what is the cache line size (for dcbz etc) ? This info is
	// harvested on Linux at startup from the AT_SYSINFO entries. 0 means
	// not-yet-set.
	#if defined(VGA_ppc32)
	Int VG_(cache_line_size_ppc32) = 0;
	#endif

	// X86: set to 1 if the host is able to do {ld,st}mxcsr (load/store
	// the SSE control/status register. For most modern CPUs this will be
	// 1. It is set to 1, if possible, by m_translate.getArchAndArchInfo.
	// The value is read by m_dispatch.dispatch-x86.S, which is why it
	// is an Int rather than a Bool.
	//
	// Ugly hack: this has to start as 0 and be set to 1 in the normal
	// case, rather than the other way round, because the dispatch
	// loop needs it, and it runs before the first translation is
	// made. Yet it is the act of making that first translation which
	// causes getArchAndArchInfo to set this value to its final value.
	// So it is necessary to start this value off at 0 as only that
	// guarantees that the dispatch loop will not SIGILL on its first
	// attempt.
	#if defined(VGA_x86)
	Int VG_(have_mxcsr_x86) = 0;
	#endif


	/--------------------------------------------------------------------/
	/--- end ---/
	/--------------------------------------------------------------------/