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Blame SOURCES/0108-Make-pmtimer-tsc-calibration-not-take-51-seconds-to-.patch

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From 0000000000000000000000000000000000000000 Mon Sep 17 00:00:00 2001
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From: Peter Jones <pjones@redhat.com>
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Date: Tue, 7 Nov 2017 17:12:17 -0500
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Subject: [PATCH] Make pmtimer tsc calibration not take 51 seconds to fail.
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On my laptop running at 2.4GHz, if I run a VM where tsc calibration
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using pmtimer will fail presuming a broken pmtimer, it takes ~51 seconds
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to do so (as measured with the stopwatch on my phone), with a tsc delta
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of 0x1cd1c85300, or around 125 billion cycles.
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If instead of trying to wait for 5-200ms to show up on the pmtimer, we try
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to wait for 5-200us, it decides it's broken in ~0x2626aa0 TSCs, aka ~2.4
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million cycles, or more or less instantly.
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Additionally, this reading the pmtimer was returning 0xffffffff anyway,
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and that's obviously an invalid return.  I've added a check for that and
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0 so we don't bother waiting for the test if what we're seeing is dead
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pins with no response at all.
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If "debug" is includes "pmtimer", you will see one of the following
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three outcomes.  If pmtimer gives all 0 or all 1 bits, you will see:
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 1
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 2
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 3
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 4
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 5
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 6
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 7
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 8
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 9
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kern/i386/tsc_pmtimer.c:77: pmtimer: 0xffffff bad_reads: 10
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kern/i386/tsc_pmtimer.c:78: timer is broken; giving up.
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This outcome was tested using qemu+kvm with UEFI (OVMF) firmware and
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these options: -machine pc-q35-2.10 -cpu Broadwell-noTSX
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If pmtimer gives any other bit patterns but is not actually marching
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forward fast enough to use for clock calibration, you will see:
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kern/i386/tsc_pmtimer.c:121: pmtimer delta is 0x0 (1904 iterations)
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kern/i386/tsc_pmtimer.c:124: tsc delta is implausible: 0x2626aa0
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This outcome was tested using grub compiled with GRUB_PMTIMER_IGNORE_BAD_READS
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defined (so as not to trip the bad read test) using qemu+kvm with UEFI
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(OVMF) firmware, and these options: -machine pc-q35-2.10 -cpu Broadwell-noTSX
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If pmtimer actually works, you'll see something like:
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kern/i386/tsc_pmtimer.c:121: pmtimer delta is 0x0 (1904 iterations)
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kern/i386/tsc_pmtimer.c:124: tsc delta is implausible: 0x2626aa0
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This outcome was tested using qemu+kvm with UEFI (OVMF) firmware, and
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these options: -machine pc-i440fx-2.4 -cpu Broadwell-noTSX
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I've also tested this outcome on a real Intel Xeon E3-1275v3 on an Intel
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Server Board S1200V3RPS using the SDV.RP.B8 "Release" build here:
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https://firmware.intel.com/sites/default/files/UEFIDevKit_S1200RP_vB8.zip
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Signed-off-by: Peter Jones <pjones@redhat.com>
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---
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 grub-core/kern/i386/tsc_pmtimer.c | 109 +++++++++++++++++++++++++++++++-------
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 1 file changed, 89 insertions(+), 20 deletions(-)
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diff --git a/grub-core/kern/i386/tsc_pmtimer.c b/grub-core/kern/i386/tsc_pmtimer.c
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index c9c36169978..ca15c3aacd7 100644
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--- a/grub-core/kern/i386/tsc_pmtimer.c
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+++ b/grub-core/kern/i386/tsc_pmtimer.c
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@@ -28,40 +28,101 @@
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 #include <grub/acpi.h>
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 #include <grub/cpu/io.h>
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+/*
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+ * Define GRUB_PMTIMER_IGNORE_BAD_READS if you're trying to test a timer that's
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+ * present but doesn't keep time well.
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+ */
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+// #define GRUB_PMTIMER_IGNORE_BAD_READS
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+
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 grub_uint64_t
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 grub_pmtimer_wait_count_tsc (grub_port_t pmtimer,
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 			     grub_uint16_t num_pm_ticks)
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 {
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   grub_uint32_t start;
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-  grub_uint32_t last;
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-  grub_uint32_t cur, end;
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+  grub_uint64_t cur, end;
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   grub_uint64_t start_tsc;
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   grub_uint64_t end_tsc;
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-  int num_iter = 0;
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+  unsigned int num_iter = 0;
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+#ifndef GRUB_PMTIMER_IGNORE_BAD_READS
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+  int bad_reads = 0;
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+#endif
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-  start = grub_inl (pmtimer) & 0xffffff;
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-  last = start;
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+  /*
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+   * Some timers are 24-bit and some are 32-bit, but it doesn't make much
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+   * difference to us.  Caring which one we have isn't really worth it since
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+   * the low-order digits will give us enough data to calibrate TSC.  So just
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+   * mask the top-order byte off.
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+   */
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+  cur = start = grub_inl (pmtimer) & 0xffffffUL;
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   end = start + num_pm_ticks;
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   start_tsc = grub_get_tsc ();
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   while (1)
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     {
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-      cur = grub_inl (pmtimer) & 0xffffff;
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-      if (cur < last)
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-	cur |= 0x1000000;
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-      num_iter++;
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+      cur &= 0xffffffffff000000ULL;
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+      cur |= grub_inl (pmtimer) & 0xffffffUL;
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+
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+      end_tsc = grub_get_tsc();
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+
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+#ifndef GRUB_PMTIMER_IGNORE_BAD_READS
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+      /*
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+       * If we get 10 reads in a row that are obviously dead pins, there's no
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+       * reason to do this thousands of times.
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+       */
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+      if (cur == 0xffffffUL || cur == 0)
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+	{
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+	  bad_reads++;
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+	  grub_dprintf ("pmtimer",
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+			"pmtimer: 0x%"PRIxGRUB_UINT64_T" bad_reads: %d\n",
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+			cur, bad_reads);
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+	  grub_dprintf ("pmtimer", "timer is broken; giving up.\n");
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+
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+	  if (bad_reads == 10)
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+	    return 0;
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+	}
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+#endif
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+
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+      if (cur < start)
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+	cur += 0x1000000;
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+
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       if (cur >= end)
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 	{
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-	  end_tsc = grub_get_tsc ();
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+	  grub_dprintf ("pmtimer", "pmtimer delta is 0x%"PRIxGRUB_UINT64_T"\n",
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+			cur - start);
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+	  grub_dprintf ("pmtimer", "tsc delta is 0x%"PRIxGRUB_UINT64_T"\n",
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+			end_tsc - start_tsc);
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 	  return end_tsc - start_tsc;
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 	}
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-      /* Check for broken PM timer.
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-	 50000000 TSCs is between 5 ms (10GHz) and 200 ms (250 MHz)
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-	 if after this time we still don't have 1 ms on pmtimer, then
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-	 pmtimer is broken.
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+
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+      /*
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+       * Check for broken PM timer.  1ms at 10GHz should be 1E+7 TSCs; at
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+       * 250MHz it should be 2.5E6.  So if after 4E+7 TSCs on a 10GHz machine,
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+       * we should have seen pmtimer show 4ms of change (i.e. cur =~
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+       * start+14320); on a 250MHz machine that should be 16ms (start+57280).
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+       * If after this a time we still don't have 1ms on pmtimer, then pmtimer
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+       * is broken.
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+       *
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+       * Likewise, if our code is perfectly efficient and introduces no delays
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+       * whatsoever, on a 10GHz system we should see a TSC delta of 3580 in
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+       * ~3580 iterations.  On a 250MHz machine that should be ~900 iterations.
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+       *
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+       * With those factors in mind, there are two limits here.  There's a hard
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+       * limit here at 8x our desired pm timer delta, picked as an arbitrarily
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+       * large value that's still not a lot of time to humans, because if we
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+       * get that far this is either an implausibly fast machine or the pmtimer
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+       * is not running.  And there's another limit on 4x our 10GHz tsc delta
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+       * without seeing cur converge on our target value.
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        */
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-      if ((num_iter & 0xffffff) == 0 && grub_get_tsc () - start_tsc > 5000000) {
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-	return 0;
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-      }
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+      if ((++num_iter > (grub_uint32_t)num_pm_ticks << 3UL) ||
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+	  end_tsc - start_tsc > 40000000)
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+	{
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+	  grub_dprintf ("pmtimer",
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+			"pmtimer delta is 0x%"PRIxGRUB_UINT64_T" (%u iterations)\n",
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+			cur - start, num_iter);
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+	  grub_dprintf ("pmtimer",
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+			"tsc delta is implausible: 0x%"PRIxGRUB_UINT64_T"\n",
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+			end_tsc - start_tsc);
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+	  return 0;
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+	}
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     }
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 }
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@@ -74,12 +135,20 @@ grub_tsc_calibrate_from_pmtimer (void)
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   fadt = grub_acpi_find_fadt ();
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   if (!fadt)
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-    return 0;
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+    {
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+      grub_dprintf ("pmtimer", "No FADT found; not using pmtimer.\n");
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+      return 0;
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+    }
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   pmtimer = fadt->pmtimer;
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   if (!pmtimer)
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-    return 0;
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+    {
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+      grub_dprintf ("pmtimer", "FADT does not specify pmtimer; skipping.\n");
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+      return 0;
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+    }
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-  /* It's 3.579545 MHz clock. Wait 1 ms.  */
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+  /*
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+   * It's 3.579545 MHz clock. Wait 1 ms.
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+   */
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   tsc_diff = grub_pmtimer_wait_count_tsc (pmtimer, 3580);
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   if (tsc_diff == 0)
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     return 0;