/*
  This file is part of drd, a data race detector.

  Copyright (C) 2006-2008 Bart Van Assche
  bart.vanassche@gmail.com

  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 "drd_clientreq.h"
#include "drd_cond.h"
#include "drd_mutex.h"
#include "drd_semaphore.h"
#include "drd_suppression.h"      // drd_start_suppression()
#include "drd_thread.h"
#include "drd_track.h"
#include "drd_rwlock.h"
#include "pub_tool_basics.h"      // Bool
#include "pub_tool_debuginfo.h"   // VG_(describe_IP)()
#include "pub_tool_libcassert.h"
#include "pub_tool_libcassert.h"  // tl_assert()
#include "pub_tool_libcprint.h"   // VG_(message)()
#include "pub_tool_machine.h"     // VG_(get_SP)()
#include "pub_tool_threadstate.h"
#include "pub_tool_tooliface.h"   // VG_(needs_...)()


static void drd_spin_init_or_unlock(const Addr spinlock)
{
  struct mutex_info* mutex_p = mutex_get(spinlock);
  if (mutex_p)
  {
    mutex_unlock(spinlock, mutex_type_spinlock);
  }
  else
  {
    mutex_init(spinlock, mutex_type_spinlock);
  }
}

static void drd_pre_cond_wait(const Addr cond,
                              const Addr mutex, const MutexT mutex_type)
{
  mutex_unlock(mutex, mutex_type);
  cond_pre_wait(cond, mutex);
}

static void drd_post_cond_wait(const Addr cond,
                               const Addr mutex,
                               const Bool took_lock)
{
  cond_post_wait(cond);
  mutex_post_lock(mutex, took_lock, True);
}

static void drd_pre_cond_signal(const Addr cond)
{
  cond_pre_signal(cond);
}

static void drd_pre_cond_broadcast(const Addr cond)
{
  cond_pre_broadcast(cond);
}

/** Walk the stack up to the highest stack frame, and return the stack pointer
 *  of the highest stack frame. It is assumed that there are no more than
 *  ten stack frames above the current frame. This should be no problem
 *  since this function is either called indirectly from the _init() function
 *  in vgpreload_exp-drd-*.so or from the thread wrapper for a newly created
 *  thread. See also drd_pthread_intercepts.c.
 */
static Addr highest_used_stack_address(const ThreadId vg_tid)
{
    UInt nframes;
    const UInt n_ips = 10;
    UInt i;
    Addr ips[n_ips], sps[n_ips];
    Addr husa;

    nframes = VG_(get_StackTrace)(vg_tid, ips, n_ips, sps, 0, 0);
    tl_assert(1 <= nframes && nframes <= n_ips);

    /* A hack to work around VG_(get_StackTrace)()'s behavior that sometimes */
    /* the topmost stackframes it returns are bogus (this occurs sometimes   */
    /* at least on amd64, ppc32 and ppc64).                                  */

    husa = sps[0];

    tl_assert(VG_(thread_get_stack_max)(vg_tid)
              - VG_(thread_get_stack_size)(vg_tid) <= husa
              && husa < VG_(thread_get_stack_max)(vg_tid));

    for (i = 1; i < nframes; i++)
    {
      if (sps[i] == 0)
        break;
      if (husa < sps[i] && sps[i] < VG_(thread_get_stack_max)(vg_tid))
        husa = sps[i];
    }

    tl_assert(VG_(thread_get_stack_max)(vg_tid)
              - VG_(thread_get_stack_size)(vg_tid) <= husa
              && husa < VG_(thread_get_stack_max)(vg_tid));

    return husa;
}

static Bool drd_handle_client_request(ThreadId vg_tid, UWord* arg, UWord* ret)
{
  UWord result = 0;
  const DrdThreadId drd_tid = thread_get_running_tid();

  tl_assert(vg_tid == VG_(get_running_tid()));
  tl_assert(VgThreadIdToDrdThreadId(vg_tid) == drd_tid);

  switch (arg[0])
  {
  case VG_USERREQ__DRD_GET_VALGRIND_THREAD_ID:
    result = vg_tid;
    break;

  case VG_USERREQ__DRD_GET_DRD_THREAD_ID:
    result = drd_tid;
    break;

  case VG_USERREQ__DRD_START_SUPPRESSION:
    drd_start_suppression(arg[1], arg[1] + arg[2], "client");
    break;

  case VG_USERREQ__DRD_FINISH_SUPPRESSION:
    drd_finish_suppression(arg[1], arg[1] + arg[2]);
    break;

  case VG_USERREQ__DRD_SUPPRESS_CURRENT_STACK:
  {
    const Addr topmost_sp = highest_used_stack_address(vg_tid);
#if 0
    UInt nframes;
    const UInt n_ips = 20;
    Addr ips[n_ips], sps[n_ips], fps[n_ips];
    Char desc[128];
    unsigned i;

    nframes = VG_(get_StackTrace)(vg_tid, ips, n_ips, sps, fps, 0);

    VG_(message)(Vg_DebugMsg, "thread %d/%d", vg_tid, drd_tid);
    for (i = 0; i < nframes; i++)
    {
      VG_(describe_IP)(ips[i], desc, sizeof(desc));
      VG_(message)(Vg_DebugMsg, "[%2d] sp 0x%09lx fp 0x%09lx ip %s",
                   i, sps[i], fps[i], desc);
    }
#endif
    thread_set_stack_startup(drd_tid, VG_(get_SP)(vg_tid));
    drd_start_suppression(topmost_sp, VG_(thread_get_stack_max)(vg_tid),
                          "stack top");
    break;
  }

  case VG_USERREQ__DRD_START_NEW_SEGMENT:
    thread_new_segment(PtThreadIdToDrdThreadId(arg[1]));
    break;

  case VG_USERREQ__DRD_START_TRACE_ADDR:
    drd_start_tracing_address_range(arg[1], arg[1] + arg[2]);
    break;

  case VG_USERREQ__DRD_STOP_TRACE_ADDR:
    drd_stop_tracing_address_range(arg[1], arg[1] + arg[2]);
    break;

  case VG_USERREQ__DRD_STOP_RECORDING:
    thread_stop_recording(drd_tid);
    break;

  case VG_USERREQ__DRD_START_RECORDING:
    thread_start_recording(drd_tid);
    break;

  case VG_USERREQ__SET_PTHREADID:
    // pthread_self() returns 0 for programs not linked with libpthread.so.
    if (arg[1] != INVALID_POSIX_THREADID)
      thread_set_pthreadid(drd_tid, arg[1]);
    break;

  case VG_USERREQ__SET_JOINABLE:
    thread_set_joinable(PtThreadIdToDrdThreadId(arg[1]), (Bool)arg[2]);
    break;

  case VG_USERREQ__POST_THREAD_JOIN:
    tl_assert(arg[1]);
    drd_post_thread_join(drd_tid,
                         PtThreadIdToDrdThreadId(arg[1]));
    break;

  case VG_USERREQ__PRE_THREAD_CANCEL:
    tl_assert(arg[1]);
    drd_pre_thread_cancel(drd_tid, PtThreadIdToDrdThreadId(arg[1]));
    break;

  case VG_USERREQ__POST_THREAD_CANCEL:
    tl_assert(arg[1]);
    drd_post_thread_cancel(drd_tid, PtThreadIdToDrdThreadId(arg[1]), arg[2]);
    break;

  case VG_USERREQ__PRE_MUTEX_INIT:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_pre_mutex_init(arg[1], arg[2]);
    break;

  case VG_USERREQ__POST_MUTEX_INIT:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_MUTEX_DESTROY:
    thread_enter_synchr(drd_tid);
    break;

  case VG_USERREQ__POST_MUTEX_DESTROY:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_post_mutex_destroy(arg[1], arg[2]);
    break;

  case VG_USERREQ__PRE_MUTEX_LOCK:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_pre_mutex_lock(arg[1], arg[2], arg[3]);
    break;

  case VG_USERREQ__POST_MUTEX_LOCK:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_post_mutex_lock(arg[1], arg[2]);
    break;

  case VG_USERREQ__PRE_MUTEX_UNLOCK:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_pre_mutex_unlock(arg[1], arg[2]);
    break;

  case VG_USERREQ__POST_MUTEX_UNLOCK:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_SPIN_INIT_OR_UNLOCK:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_spin_init_or_unlock(arg[1]);
    break;

  case VG_USERREQ__POST_SPIN_INIT_OR_UNLOCK:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_COND_INIT:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_pre_cond_init(arg[1]);
    break;

  case VG_USERREQ__POST_COND_INIT:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_COND_DESTROY:
    thread_enter_synchr(drd_tid);
    break;

  case VG_USERREQ__POST_COND_DESTROY:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_post_cond_destroy(arg[1]);
    break;

  case VG_USERREQ__PRE_COND_WAIT:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_pre_cond_wait(arg[1], arg[2], arg[3]);
    break;

  case VG_USERREQ__POST_COND_WAIT:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_post_cond_wait(arg[1], arg[2], arg[3]);
    break;

  case VG_USERREQ__PRE_COND_SIGNAL:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_pre_cond_signal(arg[1]);
    break;

  case VG_USERREQ__POST_COND_SIGNAL:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_COND_BROADCAST:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_pre_cond_broadcast(arg[1]);
    break;

  case VG_USERREQ__POST_COND_BROADCAST:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_SEM_INIT:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_semaphore_init(arg[1], arg[2], arg[3]);
    break;

  case VG_USERREQ__POST_SEM_INIT:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_SEM_DESTROY:
    thread_enter_synchr(drd_tid);
    break;

  case VG_USERREQ__POST_SEM_DESTROY:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_semaphore_destroy(arg[1]);
    break;

  case VG_USERREQ__PRE_SEM_WAIT:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_semaphore_pre_wait(drd_tid, arg[1]);
    break;

  case VG_USERREQ__POST_SEM_WAIT:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_semaphore_post_wait(drd_tid, arg[1], arg[2]);
    break;

  case VG_USERREQ__PRE_SEM_POST:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_semaphore_pre_post(drd_tid, arg[1]);
    break;

  case VG_USERREQ__POST_SEM_POST:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_semaphore_post_post(drd_tid, arg[1], arg[2]);
    break;

  case VG_USERREQ__PRE_BARRIER_INIT:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_barrier_init(arg[1], arg[2], arg[3], arg[4]);
    break;

  case VG_USERREQ__POST_BARRIER_INIT:
    thread_leave_synchr(drd_tid);
    break;

  case VG_USERREQ__PRE_BARRIER_DESTROY:
    thread_enter_synchr(drd_tid);
    break;

  case VG_USERREQ__POST_BARRIER_DESTROY:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_barrier_destroy(arg[1], arg[2]);
    break;

  case VG_USERREQ__PRE_BARRIER_WAIT:
    if (thread_enter_synchr(drd_tid) == 0)
      drd_barrier_pre_wait(drd_tid, arg[1], arg[2]);
    break;

  case VG_USERREQ__POST_BARRIER_WAIT:
    if (thread_leave_synchr(drd_tid) == 0)
      drd_barrier_post_wait(drd_tid, arg[1], arg[2], arg[3]);
    break;

  case VG_USERREQ__PRE_RWLOCK_INIT:
    rwlock_pre_init(arg[1]);
    break;

  case VG_USERREQ__POST_RWLOCK_DESTROY:
    rwlock_post_destroy(arg[1]);
    break;

  case VG_USERREQ__PRE_RWLOCK_RDLOCK:
    if (thread_enter_synchr(drd_tid) == 0)
      rwlock_pre_rdlock(arg[1]);
    break;

  case VG_USERREQ__POST_RWLOCK_RDLOCK:
    if (thread_leave_synchr(drd_tid) == 0)
      rwlock_post_rdlock(arg[1], arg[2]);
    break;

  case VG_USERREQ__PRE_RWLOCK_WRLOCK:
    if (thread_enter_synchr(drd_tid) == 0)
      rwlock_pre_wrlock(arg[1]);
    break;

  case VG_USERREQ__POST_RWLOCK_WRLOCK:
    if (thread_leave_synchr(drd_tid) == 0)
      rwlock_post_wrlock(arg[1], arg[2]);
    break;

  case VG_USERREQ__PRE_RWLOCK_UNLOCK:
    if (thread_enter_synchr(drd_tid) == 0)
      rwlock_pre_unlock(arg[1]);
    break;
      
  case VG_USERREQ__POST_RWLOCK_UNLOCK:
    thread_leave_synchr(drd_tid);
    break;

  default:
    VG_(message)(Vg_DebugMsg, "Unrecognized client request 0x%lx 0x%lx",
                 arg[0], arg[1]);
    tl_assert(0);
    return False;
  }

  *ret = result;
  return True;
}

void drd_clientreq_init(void)
{
  VG_(needs_client_requests)(drd_handle_client_request);
}