gcc/profile-count.c - gcc - Git at Google

 /* Profile counter container type.
    Copyright (C) 2017-2021 Free Software Foundation, Inc.
    Contributed by Jan Hubicka

 This file is part of GCC.

 GCC 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 3, or (at your option) any later
 version.

 GCC 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 GCC; see the file COPYING3.  If not see
 <http://www.gnu.org/licenses/>.  */

 #include "config.h"
 #include "system.h"
 #include "coretypes.h"
 #include "profile-count.h"
 #include "options.h"
 #include "tree.h"
 #include "basic-block.h"
 #include "function.h"
 #include "cfg.h"
 #include "gimple.h"
 #include "data-streamer.h"
 #include "cgraph.h"
 #include "wide-int.h"
 #include "sreal.h"

 /* Names from profile_quality enum values.  */

 const char *profile_quality_names[] =
 {
   "uninitialized",
   "guessed_local",
   "guessed_global0",
   "guessed_global0adjusted",
   "guessed",
   "afdo",
   "adjusted",
   "precise"
 };

 /* Get a string describing QUALITY.  */

 const char *
 profile_quality_as_string (enum profile_quality quality)
 {
   return profile_quality_names[quality];
 }

 /* Parse VALUE as profile quality and return true when a valid QUALITY.  */

 bool
 parse_profile_quality (const char *value, profile_quality *quality)
 {
   for (unsigned i = 0; i < ARRAY_SIZE (profile_quality_names); i++)
     if (strcmp (profile_quality_names[i], value) == 0)
       {
 	*quality = (profile_quality)i;
 	return true;
       }

   return false;
 }

 /* Display names from profile_quality enum values.  */

 const char *profile_quality_display_names[] =
 {
   NULL,
   "estimated locally",
   "estimated locally, globally 0",
   "estimated locally, globally 0 adjusted",
   "guessed",
   "auto FDO",
   "adjusted",
   "precise"
 };

 /* Dump THIS to F.  */

 void
 profile_count::dump (FILE *f) const
 {
   if (!initialized_p ())
     fprintf (f, "uninitialized");
   else
     fprintf (f, "%" PRId64 " (%s)", m_val,
 	     profile_quality_display_names[m_quality]);
 }

 /* Dump THIS to stderr.  */

 void
 profile_count::debug () const
 {
   dump (stderr);
   fprintf (stderr, "\n");
 }

 /* Return true if THIS differs from OTHER; tolerate small differences.  */

 bool
 profile_count::differs_from_p (profile_count other) const
 {
   gcc_checking_assert (compatible_p (other));
   if (!initialized_p () || !other.initialized_p ())
     return false;
   if ((uint64_t)m_val - (uint64_t)other.m_val < 100
       || (uint64_t)other.m_val - (uint64_t)m_val < 100)
     return false;
   if (!other.m_val)
     return true;
   int64_t ratio = (int64_t)m_val * 100 / other.m_val;
   return ratio < 99 || ratio > 101;
 }

 /* Stream THIS from IB.  */

 profile_count
 profile_count::stream_in (class lto_input_block *ib)
 {
   profile_count ret;
   ret.m_val = streamer_read_gcov_count (ib);
   ret.m_quality = (profile_quality) streamer_read_uhwi (ib);
   return ret;
 }

 /* Stream THIS to OB.  */

 void
 profile_count::stream_out (struct output_block *ob)
 {
   streamer_write_gcov_count (ob, m_val);
   streamer_write_uhwi (ob, m_quality);
 }

 /* Stream THIS to OB.  */

 void
 profile_count::stream_out (struct lto_output_stream *ob)
 {
   streamer_write_gcov_count_stream (ob, m_val);
   streamer_write_uhwi_stream (ob, m_quality);
 }

 /* Dump THIS to F.  */

 void
 profile_probability::dump (FILE *f) const
 {
   if (!initialized_p ())
     fprintf (f, "uninitialized");
   else
     {
       /* Make difference between 0.00 as a roundoff error and actual 0.
 	 Similarly for 1.  */
       if (m_val == 0)
         fprintf (f, "never");
       else if (m_val == max_probability)
         fprintf (f, "always");
       else
         fprintf (f, "%3.1f%%", (double)m_val * 100 / max_probability);
       if (m_quality == ADJUSTED)
 	fprintf (f, " (adjusted)");
       else if (m_quality == AFDO)
 	fprintf (f, " (auto FDO)");
       else if (m_quality == GUESSED)
 	fprintf (f, " (guessed)");
     }
 }

 /* Dump THIS to stderr.  */

 void
 profile_probability::debug () const
 {
   dump (stderr);
   fprintf (stderr, "\n");
 }

 /* Return true if THIS differs from OTHER; tolerate small differences.  */

 bool
 profile_probability::differs_from_p (profile_probability other) const
 {
   if (!initialized_p () || !other.initialized_p ())
     return false;
   if ((uint64_t)m_val - (uint64_t)other.m_val < max_probability / 1000
       || (uint64_t)other.m_val - (uint64_t)max_probability < 1000)
     return false;
   if (!other.m_val)
     return true;
   int64_t ratio = (int64_t)m_val * 100 / other.m_val;
   return ratio < 99 || ratio > 101;
 }

 /* Return true if THIS differs significantly from OTHER.  */

 bool
 profile_probability::differs_lot_from_p (profile_probability other) const
 {
   if (!initialized_p () || !other.initialized_p ())
     return false;
   uint32_t d = m_val > other.m_val ? m_val - other.m_val : other.m_val - m_val;
   return d > max_probability / 2;
 }

 /* Stream THIS from IB.  */

 profile_probability
 profile_probability::stream_in (class lto_input_block *ib)
 {
   profile_probability ret;
   ret.m_val = streamer_read_uhwi (ib);
   ret.m_quality = (profile_quality) streamer_read_uhwi (ib);
   return ret;
 }

 /* Stream THIS to OB.  */

 void
 profile_probability::stream_out (struct output_block *ob)
 {
   streamer_write_uhwi (ob, m_val);
   streamer_write_uhwi (ob, m_quality);
 }

 /* Stream THIS to OB.  */

 void
 profile_probability::stream_out (struct lto_output_stream *ob)
 {
   streamer_write_uhwi_stream (ob, m_val);
   streamer_write_uhwi_stream (ob, m_quality);
 }

 /* Compute RES=(a*b + c/2)/c capping and return false if overflow happened.  */

 bool
 slow_safe_scale_64bit (uint64_t a, uint64_t b, uint64_t c, uint64_t *res)
 {
   FIXED_WIDE_INT (128) tmp = a;
   wi::overflow_type overflow;
   tmp = wi::udiv_floor (wi::umul (tmp, b, &overflow) + (c / 2), c);
   gcc_checking_assert (!overflow);
   if (wi::fits_uhwi_p (tmp))
     {
       *res = tmp.to_uhwi ();
       return true;
     }
   *res = (uint64_t) -1;
   return false;
 }

 /* Return count as frequency within FUN scaled in range 0 to REG_FREQ_MAX
    Used for legacy code and should not be used anymore.  */

 int
 profile_count::to_frequency (struct function *fun) const
 {
   if (!initialized_p ())
     return BB_FREQ_MAX;
   if (*this == zero ())
     return 0;
   STATIC_ASSERT (REG_BR_PROB_BASE == BB_FREQ_MAX);
   gcc_assert (fun->cfg->count_max.initialized_p ());
   profile_probability prob = probability_in (fun->cfg->count_max);
   if (!prob.initialized_p ())
     return REG_BR_PROB_BASE;
   return prob.to_reg_br_prob_base ();
 }

 /* Return count as frequency within FUN scaled in range 0 to CGRAPH_FREQ_MAX
    where CGRAPH_FREQ_BASE means that count equals to entry block count.
    Used for legacy code and should not be used anymore.  */

 int
 profile_count::to_cgraph_frequency (profile_count entry_bb_count) const
 {
   if (!initialized_p () || !entry_bb_count.initialized_p ())
     return CGRAPH_FREQ_BASE;
   if (*this == zero ())
     return 0;
   gcc_checking_assert (entry_bb_count.initialized_p ());
   uint64_t scale;
   gcc_checking_assert (compatible_p (entry_bb_count));
   if (!safe_scale_64bit (!entry_bb_count.m_val ? m_val + 1 : m_val,
 			 CGRAPH_FREQ_BASE, MAX (1, entry_bb_count.m_val), &scale))
     return CGRAPH_FREQ_MAX;
   return MIN (scale, CGRAPH_FREQ_MAX);
 }

 /* Return THIS/IN as sreal value.  */

 sreal
 profile_count::to_sreal_scale (profile_count in, bool *known) const
 {
   if (!initialized_p () || !in.initialized_p ())
     {
       if (known)
 	*known = false;
       return 1;
     }
   if (known)
     *known = true;
   /* Watch for cases where one count is IPA and other is not.  */
   if (in.ipa ().initialized_p ())
     {
       gcc_checking_assert (ipa ().initialized_p ());
       /* If current count is inter-procedurally 0 and IN is inter-procedurally
 	 non-zero, return 0.  */
       if (in.ipa ().nonzero_p ()
 	  && !ipa().nonzero_p ())
 	return 0;
     }
   else
     /* We can handle correctly 0 IPA count within locally estimated
        profile, but otherwise we are lost and this should not happen.   */
     gcc_checking_assert (!ipa ().initialized_p () || !ipa ().nonzero_p ());
   if (*this == zero ())
     return 0;
   if (m_val == in.m_val)
     return 1;
   gcc_checking_assert (compatible_p (in));

   if (!in.m_val)
     {
       if (!m_val)
 	return 1;
       return m_val * 4;
     }
   return (sreal)m_val / (sreal)in.m_val;
 }

 /* We want to scale profile across function boundary from NUM to DEN.
    Take care of the side case when DEN is zeros.  We still want to behave
    sanely here which means
      - scale to profile_count::zero () if NUM is profile_count::zero
      - do not affect anything if NUM == DEN
      - preserve counter value but adjust quality in other cases.  */

 void
 profile_count::adjust_for_ipa_scaling (profile_count *num,
 				       profile_count *den)
 {
   /* Scaling is no-op if NUM and DEN are the same.  */
   if (*num == *den)
     return;
   /* Scaling to zero is always zero.  */
   if (*num == zero ())
     return;
   /* If den is non-zero we are safe.  */
   if (den->force_nonzero () == *den)
     return;
   /* Force both to non-zero so we do not push profiles to 0 when
      both num == 0 and den == 0.  */
   *den = den->force_nonzero ();
   *num = num->force_nonzero ();
 }

 /* THIS is a count of bb which is known to be executed IPA times.
    Combine this information into bb counter.  This means returning IPA
    if it is nonzero, not changing anything if IPA is uninitialized
    and if IPA is zero, turning THIS into corresponding local profile with
    global0.  */

 profile_count
 profile_count::combine_with_ipa_count (profile_count ipa)
 {
   if (!initialized_p ())
     return *this;
   ipa = ipa.ipa ();
   if (ipa.nonzero_p ())
     return ipa;
   if (!ipa.initialized_p () || *this == zero ())
     return *this;
   if (ipa == zero ())
     return this->global0 ();
   return this->global0adjusted ();
 }

 /* Sae as profile_count::combine_with_ipa_count but within function with count
    IPA2.  */
 profile_count
 profile_count::combine_with_ipa_count_within (profile_count ipa,
 					      profile_count ipa2)
 {
   profile_count ret;
   if (!initialized_p ())
     return *this;
   if (ipa2.ipa () == ipa2 && ipa.initialized_p ())
     ret = ipa;
   else
     ret = combine_with_ipa_count (ipa);
   gcc_checking_assert (ret.compatible_p (ipa2));
   return ret;
 }

 /* The profiling runtime uses gcov_type, which is usually 64bit integer.
    Conversions back and forth are used to read the coverage and get it
    into internal representation.  */

 profile_count
 profile_count::from_gcov_type (gcov_type v, profile_quality quality)
   {
     profile_count ret;
     gcc_checking_assert (v >= 0);
     if (dump_file && v >= (gcov_type)max_count)
       fprintf (dump_file,
 	       "Capping gcov count %" PRId64 " to max_count %" PRId64 "\n",
 	       (int64_t) v, (int64_t) max_count);
     ret.m_val = MIN (v, (gcov_type)max_count);
     ret.m_quality = quality;
     return ret;
   }

 /* COUNT1 times event happens with *THIS probability, COUNT2 times OTHER
    happens with COUNT2 probability.  Return probability that either *THIS or
    OTHER happens.  */

 profile_probability
 profile_probability::combine_with_count (profile_count count1,
 					 profile_probability other,
 					 profile_count count2) const
 {
   /* If probabilities are same, we are done.
      If counts are nonzero we can distribute accordingly. In remaining
      cases just average the values and hope for the best.  */
   if (*this == other || count1 == count2
       || (count2 == profile_count::zero ()
 	  && !(count1 == profile_count::zero ())))
     return *this;
   if (count1 == profile_count::zero () && !(count2 == profile_count::zero ()))
     return other;
   else if (count1.nonzero_p () || count2.nonzero_p ())
     return *this * count1.probability_in (count1 + count2)
 	   + other * count2.probability_in (count1 + count2);
   else
     return *this * even () + other * even ();
 }

 /* Return probability as sreal in range [0, 1].  */

 sreal
 profile_probability::to_sreal () const
 {
   gcc_checking_assert (initialized_p ());
   return ((sreal)m_val) >> (n_bits - 2);
 }
	/* Profile counter container type.
	Copyright (C) 2017-2021 Free Software Foundation, Inc.
	Contributed by Jan Hubicka

	This file is part of GCC.

	GCC 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 3, or (at your option) any later
	version.

	GCC 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 GCC; see the file COPYING3. If not see
	<http://www.gnu.org/licenses/>. */

	#include "config.h"
	#include "system.h"
	#include "coretypes.h"
	#include "profile-count.h"
	#include "options.h"
	#include "tree.h"
	#include "basic-block.h"
	#include "function.h"
	#include "cfg.h"
	#include "gimple.h"
	#include "data-streamer.h"
	#include "cgraph.h"
	#include "wide-int.h"
	#include "sreal.h"

	/* Names from profile_quality enum values. */

	const char *profile_quality_names[] =
	{
	"uninitialized",
	"guessed_local",
	"guessed_global0",
	"guessed_global0adjusted",
	"guessed",
	"afdo",
	"adjusted",
	"precise"
	};

	/* Get a string describing QUALITY. */

	const char *
	profile_quality_as_string (enum profile_quality quality)
	{
	return profile_quality_names[quality];
	}

	/* Parse VALUE as profile quality and return true when a valid QUALITY. */

	bool
	parse_profile_quality (const char value, profile_quality quality)
	{
	for (unsigned i = 0; i < ARRAY_SIZE (profile_quality_names); i++)
	if (strcmp (profile_quality_names[i], value) == 0)
	{
	*quality = (profile_quality)i;
	return true;
	}

	return false;
	}

	/* Display names from profile_quality enum values. */

	const char *profile_quality_display_names[] =
	{
	NULL,
	"estimated locally",
	"estimated locally, globally 0",
	"estimated locally, globally 0 adjusted",
	"guessed",
	"auto FDO",
	"adjusted",
	"precise"
	};

	/* Dump THIS to F. */

	void
	profile_count::dump (FILE *f) const
	{
	if (!initialized_p ())
	fprintf (f, "uninitialized");
	else
	fprintf (f, "%" PRId64 " (%s)", m_val,
	profile_quality_display_names[m_quality]);
	}

	/* Dump THIS to stderr. */

	void
	profile_count::debug () const
	{
	dump (stderr);
	fprintf (stderr, "\n");
	}

	/* Return true if THIS differs from OTHER; tolerate small differences. */

	bool
	profile_count::differs_from_p (profile_count other) const
	{
	gcc_checking_assert (compatible_p (other));
	if (!initialized_p () \|\| !other.initialized_p ())
	return false;
	if ((uint64_t)m_val - (uint64_t)other.m_val < 100
	\|\| (uint64_t)other.m_val - (uint64_t)m_val < 100)
	return false;
	if (!other.m_val)
	return true;
	int64_t ratio = (int64_t)m_val * 100 / other.m_val;
	return ratio < 99 \|\| ratio > 101;
	}

	/* Stream THIS from IB. */

	profile_count
	profile_count::stream_in (class lto_input_block *ib)
	{
	profile_count ret;
	ret.m_val = streamer_read_gcov_count (ib);
	ret.m_quality = (profile_quality) streamer_read_uhwi (ib);
	return ret;
	}

	/* Stream THIS to OB. */

	void
	profile_count::stream_out (struct output_block *ob)
	{
	streamer_write_gcov_count (ob, m_val);
	streamer_write_uhwi (ob, m_quality);
	}

	/* Stream THIS to OB. */

	void
	profile_count::stream_out (struct lto_output_stream *ob)
	{
	streamer_write_gcov_count_stream (ob, m_val);
	streamer_write_uhwi_stream (ob, m_quality);
	}

	/* Dump THIS to F. */

	void
	profile_probability::dump (FILE *f) const
	{
	if (!initialized_p ())
	fprintf (f, "uninitialized");
	else
	{
	/* Make difference between 0.00 as a roundoff error and actual 0.
	Similarly for 1. */
	if (m_val == 0)
	fprintf (f, "never");
	else if (m_val == max_probability)
	fprintf (f, "always");
	else
	fprintf (f, "%3.1f%%", (double)m_val * 100 / max_probability);
	if (m_quality == ADJUSTED)
	fprintf (f, " (adjusted)");
	else if (m_quality == AFDO)
	fprintf (f, " (auto FDO)");
	else if (m_quality == GUESSED)
	fprintf (f, " (guessed)");
	}
	}

	/* Dump THIS to stderr. */

	void
	profile_probability::debug () const
	{
	dump (stderr);
	fprintf (stderr, "\n");
	}

	/* Return true if THIS differs from OTHER; tolerate small differences. */

	bool
	profile_probability::differs_from_p (profile_probability other) const
	{
	if (!initialized_p () \|\| !other.initialized_p ())
	return false;
	if ((uint64_t)m_val - (uint64_t)other.m_val < max_probability / 1000
	\|\| (uint64_t)other.m_val - (uint64_t)max_probability < 1000)
	return false;
	if (!other.m_val)
	return true;
	int64_t ratio = (int64_t)m_val * 100 / other.m_val;
	return ratio < 99 \|\| ratio > 101;
	}

	/* Return true if THIS differs significantly from OTHER. */

	bool
	profile_probability::differs_lot_from_p (profile_probability other) const
	{
	if (!initialized_p () \|\| !other.initialized_p ())
	return false;
	uint32_t d = m_val > other.m_val ? m_val - other.m_val : other.m_val - m_val;
	return d > max_probability / 2;
	}

	/* Stream THIS from IB. */

	profile_probability
	profile_probability::stream_in (class lto_input_block *ib)
	{
	profile_probability ret;
	ret.m_val = streamer_read_uhwi (ib);
	ret.m_quality = (profile_quality) streamer_read_uhwi (ib);
	return ret;
	}

	/* Stream THIS to OB. */

	void
	profile_probability::stream_out (struct output_block *ob)
	{
	streamer_write_uhwi (ob, m_val);
	streamer_write_uhwi (ob, m_quality);
	}

	/* Stream THIS to OB. */

	void
	profile_probability::stream_out (struct lto_output_stream *ob)
	{
	streamer_write_uhwi_stream (ob, m_val);
	streamer_write_uhwi_stream (ob, m_quality);
	}

	/* Compute RES=(ab + c/2)/c capping and return false if overflow happened. /

	bool
	slow_safe_scale_64bit (uint64_t a, uint64_t b, uint64_t c, uint64_t *res)
	{
	FIXED_WIDE_INT (128) tmp = a;
	wi::overflow_type overflow;
	tmp = wi::udiv_floor (wi::umul (tmp, b, &overflow) + (c / 2), c);
	gcc_checking_assert (!overflow);
	if (wi::fits_uhwi_p (tmp))
	{
	*res = tmp.to_uhwi ();
	return true;
	}
	*res = (uint64_t) -1;
	return false;
	}

	/* Return count as frequency within FUN scaled in range 0 to REG_FREQ_MAX
	Used for legacy code and should not be used anymore. */

	int
	profile_count::to_frequency (struct function *fun) const
	{
	if (!initialized_p ())
	return BB_FREQ_MAX;
	if (*this == zero ())
	return 0;
	STATIC_ASSERT (REG_BR_PROB_BASE == BB_FREQ_MAX);
	gcc_assert (fun->cfg->count_max.initialized_p ());
	profile_probability prob = probability_in (fun->cfg->count_max);
	if (!prob.initialized_p ())
	return REG_BR_PROB_BASE;
	return prob.to_reg_br_prob_base ();
	}

	/* Return count as frequency within FUN scaled in range 0 to CGRAPH_FREQ_MAX
	where CGRAPH_FREQ_BASE means that count equals to entry block count.
	Used for legacy code and should not be used anymore. */

	int
	profile_count::to_cgraph_frequency (profile_count entry_bb_count) const
	{
	if (!initialized_p () \|\| !entry_bb_count.initialized_p ())
	return CGRAPH_FREQ_BASE;
	if (*this == zero ())
	return 0;
	gcc_checking_assert (entry_bb_count.initialized_p ());
	uint64_t scale;
	gcc_checking_assert (compatible_p (entry_bb_count));
	if (!safe_scale_64bit (!entry_bb_count.m_val ? m_val + 1 : m_val,
	CGRAPH_FREQ_BASE, MAX (1, entry_bb_count.m_val), &scale))
	return CGRAPH_FREQ_MAX;
	return MIN (scale, CGRAPH_FREQ_MAX);
	}

	/* Return THIS/IN as sreal value. */

	sreal
	profile_count::to_sreal_scale (profile_count in, bool *known) const
	{
	if (!initialized_p () \|\| !in.initialized_p ())
	{
	if (known)
	*known = false;
	return 1;
	}
	if (known)
	*known = true;
	/* Watch for cases where one count is IPA and other is not. */
	if (in.ipa ().initialized_p ())
	{
	gcc_checking_assert (ipa ().initialized_p ());
	/* If current count is inter-procedurally 0 and IN is inter-procedurally
	non-zero, return 0. */
	if (in.ipa ().nonzero_p ()
	&& !ipa().nonzero_p ())
	return 0;
	}
	else
	/* We can handle correctly 0 IPA count within locally estimated
	profile, but otherwise we are lost and this should not happen. */
	gcc_checking_assert (!ipa ().initialized_p () \|\| !ipa ().nonzero_p ());
	if (*this == zero ())
	return 0;
	if (m_val == in.m_val)
	return 1;
	gcc_checking_assert (compatible_p (in));

	if (!in.m_val)
	{
	if (!m_val)
	return 1;
	return m_val * 4;
	}
	return (sreal)m_val / (sreal)in.m_val;
	}

	/* We want to scale profile across function boundary from NUM to DEN.
	Take care of the side case when DEN is zeros. We still want to behave
	sanely here which means
	- scale to profile_count::zero () if NUM is profile_count::zero
	- do not affect anything if NUM == DEN
	- preserve counter value but adjust quality in other cases. */

	void
	profile_count::adjust_for_ipa_scaling (profile_count *num,
	profile_count *den)
	{
	/* Scaling is no-op if NUM and DEN are the same. */
	if (num == den)
	return;
	/* Scaling to zero is always zero. */
	if (*num == zero ())
	return;
	/* If den is non-zero we are safe. */
	if (den->force_nonzero () == *den)
	return;
	/* Force both to non-zero so we do not push profiles to 0 when
	both num == 0 and den == 0. */
	*den = den->force_nonzero ();
	*num = num->force_nonzero ();
	}

	/* THIS is a count of bb which is known to be executed IPA times.
	Combine this information into bb counter. This means returning IPA
	if it is nonzero, not changing anything if IPA is uninitialized
	and if IPA is zero, turning THIS into corresponding local profile with
	global0. */

	profile_count
	profile_count::combine_with_ipa_count (profile_count ipa)
	{
	if (!initialized_p ())
	return *this;
	ipa = ipa.ipa ();
	if (ipa.nonzero_p ())
	return ipa;
	if (!ipa.initialized_p () \|\| *this == zero ())
	return *this;
	if (ipa == zero ())
	return this->global0 ();
	return this->global0adjusted ();
	}

	/* Sae as profile_count::combine_with_ipa_count but within function with count
	IPA2. */
	profile_count
	profile_count::combine_with_ipa_count_within (profile_count ipa,
	profile_count ipa2)
	{
	profile_count ret;
	if (!initialized_p ())
	return *this;
	if (ipa2.ipa () == ipa2 && ipa.initialized_p ())
	ret = ipa;
	else
	ret = combine_with_ipa_count (ipa);
	gcc_checking_assert (ret.compatible_p (ipa2));
	return ret;
	}

	/* The profiling runtime uses gcov_type, which is usually 64bit integer.
	Conversions back and forth are used to read the coverage and get it
	into internal representation. */

	profile_count
	profile_count::from_gcov_type (gcov_type v, profile_quality quality)
	{
	profile_count ret;
	gcc_checking_assert (v >= 0);
	if (dump_file && v >= (gcov_type)max_count)
	fprintf (dump_file,
	"Capping gcov count %" PRId64 " to max_count %" PRId64 "\n",
	(int64_t) v, (int64_t) max_count);
	ret.m_val = MIN (v, (gcov_type)max_count);
	ret.m_quality = quality;
	return ret;
	}

	/* COUNT1 times event happens with *THIS probability, COUNT2 times OTHER
	happens with COUNT2 probability. Return probability that either *THIS or
	OTHER happens. */

	profile_probability
	profile_probability::combine_with_count (profile_count count1,
	profile_probability other,
	profile_count count2) const
	{
	/* If probabilities are same, we are done.
	If counts are nonzero we can distribute accordingly. In remaining
	cases just average the values and hope for the best. */
	if (*this == other \|\| count1 == count2
	\|\| (count2 == profile_count::zero ()
	&& !(count1 == profile_count::zero ())))
	return *this;
	if (count1 == profile_count::zero () && !(count2 == profile_count::zero ()))
	return other;
	else if (count1.nonzero_p () \|\| count2.nonzero_p ())
	return this count1.probability_in (count1 + count2)
	+ other * count2.probability_in (count1 + count2);
	else
	return this even () + other * even ();
	}

	/* Return probability as sreal in range [0, 1]. */

	sreal
	profile_probability::to_sreal () const
	{
	gcc_checking_assert (initialized_p ());
	return ((sreal)m_val) >> (n_bits - 2);
	}