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/* Test that explicit_bzero block clears are not optimized out.
   Copyright (C) 2016-2020 Free Software Foundation, Inc.
   This file is part of the GNU C Library.

   The GNU C Library is free software; you can redistribute it and/or
   modify it under the terms of the GNU Lesser General Public
   License as published by the Free Software Foundation; either
   version 2.1 of the License, or (at your option) any later version.

   The GNU C Library 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
   Lesser General Public License for more details.

   You should have received a copy of the GNU Lesser General Public
   License along with the GNU C Library; if not, see
   <https://www.gnu.org/licenses/>.  */

/* This test is conceptually based on a test designed by Matthew
   Dempsky for the OpenBSD regression suite:
   <openbsd>/src/regress/lib/libc/explicit_bzero/explicit_bzero.c.
   The basic idea is, we have a function that contains a
   block-clearing operation (not necessarily explicit_bzero), after
   which the block is dead, in the compiler-jargon sense.  Execute
   that function while running on a user-allocated alternative
   stack. Then we have another pointer to the memory region affected
   by the block clear -- namely, the original allocation for the
   alternative stack -- and can find out whether it actually happened.

   The OpenBSD test uses sigaltstack and SIGUSR1 to get onto an
   alternative stack.  This causes a number of awkward problems; some
   operating systems (e.g. Solaris and OSX) wipe the signal stack upon
   returning to the normal stack, there's no way to be sure that other
   processes running on the same system will not interfere, and the
   signal stack is very small so it's not safe to call printf there.
   This implementation instead uses the <ucontext.h> coroutine
   interface.  The coroutine stack is still too small to safely use
   printf, but we know the OS won't erase it, so we can do all the
   checks and printing from the normal stack.  */

#include "crypt-port.h"

#ifndef HAVE_UCONTEXT_H
/* We can't do this test if we don't have the ucontext API.  */
int main(void)
{
  return 77;
}
#else

#include <stdio.h>
#include <stdlib.h>
#include <ucontext.h>

#ifdef HAVE_VALGRIND_VALGRIND_H
# include <valgrind/valgrind.h>
# include <valgrind/memcheck.h>
#else
# define VALGRIND_STACK_REGISTER(start, end) do {} while (0)
# define VALGRIND_MAKE_MEM_DEFINED(addr, len) do {} while (0)
#endif

/* A byte pattern that is unlikely to occur by chance: the first 16
   prime numbers (OEIS A000040).  */
static const unsigned char test_pattern[16] =
{
  2, 3, 5, 7,  11, 13, 17, 19,  23, 29, 31, 37,  41, 43, 47, 53
};

/* Immediately after each subtest returns, we call swapcontext to get
   back onto the main stack.  That call might itself overwrite the
   test pattern, so we fill a modest-sized buffer with copies of it
   and check whether any of them survived.  */

#define PATTERN_SIZE (sizeof test_pattern)
#define PATTERN_REPS 32
#define TEST_BUFFER_SIZE (PATTERN_SIZE * PATTERN_REPS)

/* There are three subtests, two of which are sanity checks.
   Each test follows this sequence:

     main                      coroutine
     ----                      --------
     advance cur_subtest
     swap
                               call setup function
                                 prepare test buffer
                                 swap
     verify that buffer
     was filled in
     swap
                                 possibly clear buffer
                                 return
                               swap
     check buffer again,
     according to test
     expectation

   In the "no_clear" case, we don't do anything to the test buffer
   between preparing it and letting it go out of scope, and we expect
   to find it.  This confirms that the test buffer does get filled in
   and we can find it from the stack buffer.  In the "ordinary_clear"
   case, we clear it using memset.  Depending on the target, the
   compiler may not be able to apply dead store elimination to the
   memset call, so the test does not fail if the memset is not
   eliminated.  Finally, the "explicit_clear" case uses explicit_bzero
   and expects _not_ to find the test buffer, which is the real
   test.  */

static ucontext_t uc_main, uc_co;

static NO_INLINE int
use_test_buffer (unsigned char *buf)
{
  unsigned int sum = 0;

  for (unsigned int i = 0; i < PATTERN_REPS; i++)
    sum += buf[i * PATTERN_SIZE];

  return (sum == 2 * PATTERN_REPS) ? 0 : 1;
}

/* Always check the test buffer immediately after filling it; this
   makes externally visible side effects depend on the buffer existing
   and having been filled in.  */
static inline void
prepare_test_buffer (unsigned char *buf)
{
  for (unsigned int i = 0; i < PATTERN_REPS; i++)
    memcpy (buf + i*PATTERN_SIZE, test_pattern, PATTERN_SIZE);

  if (swapcontext (&uc_co, &uc_main))
    abort ();

  /* Force the compiler to really copy the pattern to buf.  */
  if (use_test_buffer (buf))
    abort ();
}

static void
setup_no_clear (void)
{
  unsigned char buf[TEST_BUFFER_SIZE];
  prepare_test_buffer (buf);
}

static void
setup_ordinary_clear (void)
{
  unsigned char buf[TEST_BUFFER_SIZE];
  prepare_test_buffer (buf);
  memset (buf, 0, TEST_BUFFER_SIZE);
}

static void
setup_explicit_clear (void)
{
  unsigned char buf[TEST_BUFFER_SIZE];
  prepare_test_buffer (buf);
  explicit_bzero (buf, TEST_BUFFER_SIZE);
}

enum test_expectation
{
  EXPECT_NONE = 1,
  EXPECT_SOME,
  EXPECT_ALL,
  NO_EXPECTATIONS,
  ARRAY_END = 0
};
struct subtest
{
  void (*setup_subtest) (void);
  const char *label;
  enum test_expectation expected;
};
static const struct subtest *cur_subtest;

static const struct subtest subtests[] =
{
  { setup_no_clear,       "no clear",       EXPECT_SOME     },
  /* The memset may happen or not, depending on compiler
     optimizations.  */
  { setup_ordinary_clear, "ordinary clear", NO_EXPECTATIONS },
  { setup_explicit_clear, "explicit clear", EXPECT_NONE     },
  { 0,                    0,                ARRAY_END       }
};

static void
test_coroutine (void)
{
  while (cur_subtest->setup_subtest)
    {
      cur_subtest->setup_subtest ();
      if (swapcontext (&uc_co, &uc_main))
        abort ();
    }
}

/* All the code above this point runs on the coroutine stack.
   All the code below this point runs on the main stack.  */

static int test_status;
static unsigned char *co_stack_buffer;
static size_t co_stack_size;

static unsigned int
count_test_patterns (unsigned char *buf, size_t bufsiz)
{
  VALGRIND_MAKE_MEM_DEFINED (buf, bufsiz);
  unsigned char *first = memmem (buf, bufsiz, test_pattern, PATTERN_SIZE);
  if (!first)
    return 0;
  unsigned int cnt = 0;
  for (unsigned int i = 0; i < PATTERN_REPS; i++)
    {
      unsigned char *p = first + i*PATTERN_SIZE;
      if (p + PATTERN_SIZE - buf > (ptrdiff_t)bufsiz)
        break;
      if (memcmp (p, test_pattern, PATTERN_SIZE) == 0)
        cnt++;
    }
  return cnt;
}

static void
check_test_buffer (enum test_expectation expected,
                   const char *label, const char *stage)
{
  unsigned int cnt = count_test_patterns (co_stack_buffer, co_stack_size);
  switch (expected)
    {
    case EXPECT_NONE:
      if (cnt == 0)
        printf ("PASS: %s/%s: expected 0 got %u\n", label, stage, cnt);
      else
        {
          printf ("FAIL: %s/%s: expected 0 got %u\n", label, stage, cnt);
          test_status = 1;
        }
      break;

    case EXPECT_SOME:
      if (cnt > 0)
        printf ("PASS: %s/%s: expected some got %u\n", label, stage, cnt);
      else
        {
          printf ("FAIL: %s/%s: expected some got 0\n", label, stage);
          test_status = 1;
        }
      break;

    case EXPECT_ALL:
      if (cnt == PATTERN_REPS)
        printf ("PASS: %s/%s: expected %d got %u\n", label, stage,
                PATTERN_REPS, cnt);
      else
        {
          printf ("FAIL: %s/%s: expected %d got %u\n", label, stage,
                  PATTERN_REPS, cnt);
          test_status = 1;
        }
      break;

    case NO_EXPECTATIONS:
      printf ("INFO: %s/%s: found %u patterns%s\n", label, stage, cnt,
              cnt == 0 ? " (memset not eliminated)" : "");
      break;

    default:
      printf ("ERROR: %s/%s: invalid value for 'expected' = %d\n",
              label, stage, (int)expected);
      test_status = 1;
    }
}

static void
test_loop (void)
{
  cur_subtest = subtests;
  while (cur_subtest->setup_subtest)
    {
      if (swapcontext (&uc_main, &uc_co))
        abort ();
      check_test_buffer (EXPECT_ALL, cur_subtest->label, "prepare");
      if (swapcontext (&uc_main, &uc_co))
        abort ();
      check_test_buffer (cur_subtest->expected, cur_subtest->label, "test");
      cur_subtest++;
    }
  /* Terminate the coroutine.  */
  if (swapcontext (&uc_main, &uc_co))
    abort ();
}

int
main (void)
{
  size_t page_alignment = sizeof (void *);
  long page_alignment_l = sysconf (_SC_PAGESIZE);
  if (page_alignment_l > (long) sizeof (void *))
    page_alignment = (size_t) page_alignment_l;

  co_stack_size = (size_t) SIGSTKSZ + (size_t) TEST_BUFFER_SIZE;
  if (co_stack_size < page_alignment * 4)
    co_stack_size = page_alignment * 4;

  void *p;
  int err = posix_memalign (&p, page_alignment, co_stack_size);
  if (err || !p)
    {
      printf ("ERROR: allocating alt stack: %s\n", strerror (err));
      return 2;
    }
  co_stack_buffer = p;
  memset (co_stack_buffer, 0, co_stack_size);
  VALGRIND_STACK_REGISTER (co_stack_buffer, co_stack_buffer + co_stack_size);

  if (getcontext (&uc_co))
    {
      printf ("ERROR: allocating coroutine context: %s\n", strerror (err));
      return 2;
    }
  uc_co.uc_stack.ss_sp   = co_stack_buffer;
  uc_co.uc_stack.ss_size = co_stack_size;
  uc_co.uc_link          = &uc_main;
  makecontext (&uc_co, test_coroutine, 0);

  test_loop ();
  return test_status;
}

#endif /* have ucontext.h */