oprofile-0.9.7/opjitconv/jitsymbol.c - nest-learning-thermostat/5.1.1/oprofile - Git at Google

 /**
  * @file jitsymbol.c
  * Handle symbols found in jitted code dump
  *
  * @remark Copyright 2007 OProfile authors
  * @remark Read the file COPYING
  *
  * @author Jens Wilke
  * @Modifications Maynard Johnson
  * @Modifications Philippe Elie
  * @Modifications Daniel Hansel
  *
  * Copyright IBM Corporation 2007
  *
  */

 #include "opjitconv.h"
 #include "opd_printf.h"
 #include "op_libiberty.h"
 #include "op_types.h"

 #include <stddef.h>
 #include <stdlib.h>
 #include <stdint.h>
 #include <stdio.h>
 #include <string.h>
 #include <unistd.h>
 #include <limits.h>

 typedef int (*compare_symbol)(void const *, void const *);


 /* count the entries in the jitentry_list */
 static u32 count_entries(void)
 {
 	struct jitentry const * entry;
 	u32 cnt = 0;
 	for (entry = jitentry_list; entry; entry = entry->next)
 		cnt++;
 	return cnt;
 }


 static void fill_entry_array(struct jitentry * entries[])
 {
 	int i = 0;
 	struct jitentry * entry;
 	for (entry = jitentry_list; entry; entry = entry->next)
 		entries[i++] = entry;
 }


 /* create an array pointing to the jitentry structures which is sorted
  * according to the comparator rule given by parameter compar
  */
 static struct jitentry ** create_sorted_array(compare_symbol compare)
 {
 	struct jitentry ** array =
 		xmalloc(sizeof(struct jitentry *) * entry_count);
 	fill_entry_array(array);
 	qsort(array, entry_count, sizeof(struct jitentry *), compare);
 	return array;
 }


 /* comparator method for qsort which sorts jitentries by symbol_name */
 static int cmp_symbolname(void const * a, void const * b)
 {
 	struct jitentry * a0 = *(struct jitentry **) a;
 	struct jitentry * b0 = *(struct jitentry **) b;
 	return strcmp(a0->symbol_name, b0->symbol_name);
 }


 /* comparator method for qsort which sorts jitentries by address */
 static int cmp_address(void const * a, void const * b)
 {
 	struct jitentry * a0 = *(struct jitentry **) a;
 	struct jitentry * b0 = *(struct jitentry **) b;
 	if (a0->vma < b0->vma)
 		return -1;
 	if (a0->vma == b0->vma)
 		return 0;
 	return 1;
 }


 /* resort address_ascending array */
 static void resort_address(void)
 {
 	u32 i;

 	qsort(entries_address_ascending, entry_count,
 	      sizeof(struct jitentry *), cmp_address);

 	// lower entry_count if entries are invalidated
 	for (i = 0; i < entry_count; ++i) {
 		if (entries_address_ascending[i]->vma)
 			break;
 	}

 	if (i) {
 		entry_count -= i;
 		memmove(&entries_address_ascending[0],
 			&entries_address_ascending[i],
 			sizeof(struct jitentry *) * entry_count);
 	}
 }


 /* Copy address_ascending array to entries_symbols_ascending and resort it.  */
 static void resort_symbol(void)
 {
 	memcpy(entries_symbols_ascending, entries_address_ascending,
 	       sizeof(struct jitentry *) * entry_count);
 	qsort(entries_symbols_ascending, entry_count,
 	      sizeof(struct jitentry *), cmp_symbolname);
 }

 /* allocate, populate and sort the jitentry arrays */
 void create_arrays(void)
 {
 	max_entry_count = entry_count = count_entries();
 	entries_symbols_ascending = create_sorted_array(cmp_symbolname);
 	entries_address_ascending = create_sorted_array(cmp_address);
 }


 /* add a new create jitentry to the array. mallocs new arrays if space is
  * needed */
 static void insert_entry(struct jitentry * entry)
 {
 	if (entry_count == max_entry_count) {
 		if (max_entry_count < UINT32_MAX - 18)
 			max_entry_count += 18;
 		else if (max_entry_count < UINT32_MAX)
 			max_entry_count += 1;
 		else {
 			fprintf(stderr, "Amount of JIT dump file entries is too large.\n");
 			exit(EXIT_FAILURE);
 		}
 		entries_symbols_ascending = (struct jitentry **)
 			xrealloc(entries_symbols_ascending,
 				 sizeof(struct jitentry *) * max_entry_count);
 		entries_address_ascending = (struct jitentry **)
 			xrealloc(entries_address_ascending,
 				 sizeof(struct jitentry *) * max_entry_count);
 	}
 	entries_address_ascending[entry_count++] = entry;
 }


 /* add a suffix to the name to differenciate it */
 static char * replacement_name(char * s, int i)
 {
 	int cnt = 1;
 	int j = i;
 	char * res;

 	while ((j = j/10))
 		cnt++;
 	cnt += 2 + strlen(s);
 	res = xmalloc(cnt);
 	snprintf(res, cnt, "%s~%i", s, i);
 	return res;
 }


 /*
  * Mark the entry so it is not included in the ELF file. We do this by
  * writing a 0 address as magic vma and sorting
  * it out later
  */
 static void invalidate_entry(struct jitentry * e)
 {
 	verbprintf(debug, "invalidate_entry: addr=%llx, name=%s\n",
 		   e->vma, e->symbol_name);
 	e->vma = 0;
 }


 /*
  * Invalidate all symbols that are not alive at sampling start time.
  */
 static void invalidate_earlybirds(unsigned long long start_time)
 {
 	u32 i;
 	int flag;
 	struct jitentry * a;

 	flag = 0;
 	for (i = 0; i < entry_count; i++) {
 		a = entries_address_ascending[i];
 		if (a->life_end < start_time) {
 			invalidate_entry(a);
 			flag = 1;
 		}
 	}
 	if (flag) {
 		resort_address();
 		resort_symbol();
 	}
 }


 /* select the symbol with the longest life time in the index range */
 static int select_one(int start_idx, int end_idx)
 {
 	int i;
 	int candidate = OP_JIT_CONV_FAIL;
 	unsigned long long lifetime = 0;
 	unsigned long long x;
 	struct jitentry const * e;

 	for (i = start_idx; i <= end_idx; i++) {
 		e = entries_address_ascending[i];
 		x = e->life_end - e->life_start;
 		if (candidate == -1 || x > lifetime) {
 			candidate = i;
 			lifetime = x;
 		}
 	}
 	return candidate;
 }


 /*
  * We decided to keep one entry in favor of the other. Instead of dropping
  * the overlapping entry we split or truncate it to not overlap any more.
  *
  * Looking on the address regions, we may have the following situation:
  *
  *  split:     |------------|
  *  keep:          |---|
  *
  * The split entry may be splitted in a left part and a right part. E.g.:
  *
  *  split0/1:  |--|     |---|
  *  keep:          |---|
  *
  * However, both parts may or may not exist.
  */
 static void split_entry(struct jitentry * split, struct jitentry const * keep)
 {
 	unsigned long long start_addr_keep = keep->vma;
 	unsigned long long end_addr_keep = keep->vma + keep->code_size;
 	unsigned long long end_addr_split = split->vma + split->code_size;
 	unsigned long long start_addr_split = split->vma;

 	// do we need a right part?
 	if (end_addr_split > end_addr_keep) {
 		struct jitentry * new_entry =
 			xcalloc(1, sizeof(struct jitentry));
 		char * s = NULL;

 		/* Check for max. length to avoid possible integer overflow. */
 		if (strlen(split->symbol_name) > SIZE_MAX - 3) {
 			fprintf(stderr, "Length of symbol name is too large.\n");
 			exit(EXIT_FAILURE);
 		} else {
 			s = xmalloc(strlen(split->symbol_name) + 3);
 			strcpy(s, split->symbol_name);
 			strcat(s, "#1");
 		}

 		new_entry->vma = end_addr_keep;
 		new_entry->code_size = end_addr_split - end_addr_keep;
 		new_entry->symbol_name = s;
 		new_entry->sym_name_malloced = 1;
 		new_entry->life_start = split->life_start;
 		new_entry->life_end = split->life_end;
 		// the right part does not have an associated code, because we
 		// don't know whether the split part begins at an opcode
 		new_entry->code = NULL;
 		verbprintf(debug, "split right (new) name=%s, start=%llx,"
 			   " end=%llx\n", new_entry->symbol_name,
 			   new_entry->vma,
 			   new_entry->vma + new_entry->code_size);
 		insert_entry(new_entry);
 	}
 	// do we need a left part?
 	if (start_addr_split < start_addr_keep) {
 		char * s = NULL;

 		/* Check for max. length to avoid possible integer overflow. */
 		if (strlen(split->symbol_name) > SIZE_MAX - 3) {
 			fprintf(stderr, "Length of symbol name is too large.\n");
 			exit(EXIT_FAILURE);
 		} else {
 			s = xmalloc(strlen(split->symbol_name) + 3);
 			strcpy(s, split->symbol_name);
 			strcat(s, "#0");
 		}

 		split->code_size = start_addr_keep - start_addr_split;
 		if (split->sym_name_malloced)
 			free(split->symbol_name);
 		split->symbol_name = s;
 		split->sym_name_malloced = 1;
 		verbprintf(debug, "split left name=%s, start=%llx, end=%llx\n",
 			   split->symbol_name, split->vma,
 			   split->vma + split->code_size);
 	} else {
 		invalidate_entry(split);
 	}
 }


 /*
  * Scans through the index range and splits/truncates entries that overlap
  * with the one indexed by keep_idx. Returns the total lifetime of the symbols
  * found to overlap.
  * Returns ULONG_MAX on error.
  */
 static unsigned long long eliminate_overlaps(int start_idx, int end_idx,
 					 int keep_idx)
 {
 	unsigned long long retval;
 	struct jitentry const * keep = entries_address_ascending[keep_idx];
 	struct jitentry * e;
 	unsigned long long start_addr_keep = keep->vma;
 	unsigned long long end_addr_keep = keep->vma + keep->code_size;
 	unsigned long long start_addr_entry, end_addr_entry;
 	int i;
 	unsigned long long min_start = keep->life_start;
 	unsigned long long max_end = keep->life_end;

 	for (i = start_idx; i <= end_idx; i++) {
 		if (i == keep_idx)
 			continue;
 		e = entries_address_ascending[i];
 		start_addr_entry = e->vma;
 		end_addr_entry = e->vma + e->code_size;
 		if (debug) {
 			if (!(start_addr_entry <= end_addr_entry)) {
 				verbprintf(debug, "assert failed:"
 					   " start_addr_entry <="
 					   " end_addr_entry\n");
 				retval = ULONG_MAX;
 				goto out;
 			}
 			if (!(start_addr_keep <= end_addr_keep)) {
 				verbprintf(debug, "assert failed: "
 					   "start_addr_keep <="
 					   " end_addr_keep\n");
 				retval = ULONG_MAX;
 				goto out;
 			}
 		}
 		if (start_addr_entry < end_addr_keep &&
 		    end_addr_entry > start_addr_keep) {
 			if (e->life_start < min_start)
 				min_start = e->life_start;
 			if (e->life_end > max_end)
 				max_end = e->life_end;
 			split_entry(e, keep);
 		}
 	}
 	retval = max_end - min_start;
 out:
 	return retval;
 }


 /*
  * Within the index range (into the array entries_address_ascending), find the
  * symbol with the maximal lifetime and split/truncate all symbols that overlap
  * with it (i.e. that there won't be any overlaps anymore).
  */
 static int handle_overlap_region(int start_idx, int end_idx)
 {
 	int rc = OP_JIT_CONV_OK;
 	int idx;
 	struct jitentry * e;
 	int cnt;
 	char * name;
 	int i, j;
 	unsigned long long totaltime;

 	if (debug) {
 		for (i = start_idx; i <= end_idx; i++) {
 			e = entries_address_ascending[i];
 			verbprintf(debug, "overlap idx=%i, name=%s, "
 				   "start=%llx, end=%llx, life_start=%lli, "
 				   "life_end=%lli, lifetime=%lli\n",
 				   i, e->symbol_name, e->vma,
 				   e->vma + e->code_size, e->life_start,
 				   e->life_end, e->life_end - e->life_start);
 		}
 	}
 	idx = select_one(start_idx, end_idx);
 	totaltime = eliminate_overlaps(start_idx, end_idx, idx);
 	if (totaltime == ULONG_MAX) {
 		rc = OP_JIT_CONV_FAIL;
 		goto out;
 	}
 	e = entries_address_ascending[idx];

 	cnt = 1;
 	j = (e->life_end - e->life_start) * 100 / totaltime;
 	while ((j = j/10))
 		cnt++;

 	// Mark symbol name with a %% to indicate the overlap.
 	cnt += strlen(e->symbol_name) + 2 + 1;
 	name = xmalloc(cnt);
 	snprintf(name, cnt, "%s%%%llu", e->symbol_name,
 		 (e->life_end - e->life_start) * 100 / totaltime);
 	if (e->sym_name_malloced)
 		free(e->symbol_name);
 	e->symbol_name = name;
 	e->sym_name_malloced = 1;
 	verbprintf(debug, "selected idx=%i, name=%s\n", idx, e->symbol_name);
 out:
 	return rc;
 }


 /*
  * one scan through the symbols to find overlaps.
  * return 1 if an overlap is found. this is repeated until no more overlap
  * is there.
  * Process: There may be more than two overlapping symbols with each other.
  * The index range of symbols found to overlap are passed to
  * handle_overlap_region.
  */
 static int scan_overlaps(void)
 {
 	int i, j;
 	unsigned long long end_addr, end_addr2;
 	struct jitentry const * a;
 	int flag = 0;
 	// entry_count can be incremented by split_entry() during the loop,
 	// save the inital value as loop count
 	int loop_count = entry_count;

 	verbprintf(debug,"count=%i, scan overlaps...\n", entry_count);
 	i = 0;
 	end_addr = 0;
 	for (j = 1; j < loop_count; j++) {
 		/**
 		 * Take a symbol [i] and look for the next symbol(s) [j] that are overlapping
 		 * symbol [i]. If a symbol [j] is found that is not overlapping symbol [i] the
 		 * symbols [i]..[j-1] are handled to be not overlapping anymore.
 		 * See descriptions of handle_overlap_region() and eliminate_overlaps() for
 		 * further details of this handling.
 		 * E.g. possible cases to be handled could be:
 		 *
 		 *   sym1 |-----------|
 		 *   sym2     |---|
 		 *
 		 *   sym1 |--------|
 		 *   sym2     |--------|
 		 *
 		 *   sym1 |--------|
 		 *   sym2     |-------|
 		 *   sym3        |---------|
 		 *
 		 * But in the following case
 		 *
 		 *   sym1 |--------|
 		 *   sym2      |-------------|
 		 *   sym3              |----------|
 		 *
 		 * sym3 would not overlap with sym1. Therefore handle_overlap_regio() would
 		 * only be called for sym1 up to sym2.
 		 */
 		a = entries_address_ascending[j - 1];
 		end_addr2 = a->vma + a->code_size;
 		if (end_addr2 > end_addr)
 			end_addr = end_addr2;
 		a = entries_address_ascending[j];
 		if (end_addr <= a->vma) {
 			if (i != j - 1) {
 				if (handle_overlap_region(i, j - 1) ==
 				    OP_JIT_CONV_FAIL) {
 					flag = OP_JIT_CONV_FAIL;
 					goto out;
 				}
 				flag = 1;
 			}
 			i = j;
 		}
 	}
 	if (i != j - 1) {
 		if (handle_overlap_region(i, j - 1) == OP_JIT_CONV_FAIL)
 			flag = OP_JIT_CONV_FAIL;
 		else
 			flag = 1;
 	}
 out:
 	return flag;
 }


 /* search for symbols that have overlapping address ranges and decide for
  * one */
 int resolve_overlaps(unsigned long long start_time)
 {
 	int rc = OP_JIT_CONV_OK;
 	int cnt = 0;

 	invalidate_earlybirds(start_time);
 	while ((rc = scan_overlaps()) && rc != OP_JIT_CONV_FAIL) {
 		resort_address();
 		if (cnt == 0) {
 			verbprintf(debug, "WARNING: overlaps detected. "
 				   "Removing overlapping JIT methods\n");
 		}
 		cnt++;
 	}
 	if (cnt > 0 && rc != OP_JIT_CONV_FAIL)
 		resort_symbol();
 	return rc;
 }


 /*
  * scan through the sorted array and replace identical symbol names by unique
  * ones by adding a counter value.
  */
 void disambiguate_symbol_names(void)
 {
 	u32 j;
 	int cnt, rep_cnt;
 	struct jitentry * a;
 	struct jitentry * b;

 	rep_cnt = 0;
 	for (j = 1; j < entry_count; j++) {
 		a = entries_symbols_ascending[j - 1];
 		cnt = 1;
 		do {
 			b = entries_symbols_ascending[j];
 			if (strcmp(a->symbol_name, b->symbol_name) == 0) {
 				if (b->sym_name_malloced)
 					free(b->symbol_name);
 				b->symbol_name =
 					replacement_name(a->symbol_name, cnt);
 				b->sym_name_malloced = 1;
 				j++;
 				cnt++;
 				rep_cnt++;
 			} else {
 				break;
 			}
 		} while (j < entry_count);
 	}
 	/* recurse to avoid that the added suffix also creates a collision */
 	if (rep_cnt) {
 		qsort(entries_symbols_ascending, entry_count,
 		      sizeof(struct jitentry *), cmp_symbolname);
 		disambiguate_symbol_names();
 	}
 }
	/**
	* @file jitsymbol.c
	* Handle symbols found in jitted code dump
	*
	* @remark Copyright 2007 OProfile authors
	* @remark Read the file COPYING
	*
	* @author Jens Wilke
	* @Modifications Maynard Johnson
	* @Modifications Philippe Elie
	* @Modifications Daniel Hansel
	*
	* Copyright IBM Corporation 2007
	*
	*/

	#include "opjitconv.h"
	#include "opd_printf.h"
	#include "op_libiberty.h"
	#include "op_types.h"

	#include <stddef.h>
	#include <stdlib.h>
	#include <stdint.h>
	#include <stdio.h>
	#include <string.h>
	#include <unistd.h>
	#include <limits.h>

	typedef int (compare_symbol)(void const , void const *);


	/* count the entries in the jitentry_list */
	static u32 count_entries(void)
	{
	struct jitentry const * entry;
	u32 cnt = 0;
	for (entry = jitentry_list; entry; entry = entry->next)
	cnt++;
	return cnt;
	}


	static void fill_entry_array(struct jitentry * entries[])
	{
	int i = 0;
	struct jitentry * entry;
	for (entry = jitentry_list; entry; entry = entry->next)
	entries[i++] = entry;
	}


	/* create an array pointing to the jitentry structures which is sorted
	* according to the comparator rule given by parameter compar
	*/
	static struct jitentry ** create_sorted_array(compare_symbol compare)
	{
	struct jitentry ** array =
	xmalloc(sizeof(struct jitentry ) entry_count);
	fill_entry_array(array);
	qsort(array, entry_count, sizeof(struct jitentry *), compare);
	return array;
	}


	/* comparator method for qsort which sorts jitentries by symbol_name */
	static int cmp_symbolname(void const * a, void const * b)
	{
	struct jitentry * a0 = (struct jitentry *) a;
	struct jitentry * b0 = (struct jitentry *) b;
	return strcmp(a0->symbol_name, b0->symbol_name);
	}


	/* comparator method for qsort which sorts jitentries by address */
	static int cmp_address(void const * a, void const * b)
	{
	struct jitentry * a0 = (struct jitentry *) a;
	struct jitentry * b0 = (struct jitentry *) b;
	if (a0->vma < b0->vma)
	return -1;
	if (a0->vma == b0->vma)
	return 0;
	return 1;
	}


	/* resort address_ascending array */
	static void resort_address(void)
	{
	u32 i;

	qsort(entries_address_ascending, entry_count,
	sizeof(struct jitentry *), cmp_address);

	// lower entry_count if entries are invalidated
	for (i = 0; i < entry_count; ++i) {
	if (entries_address_ascending[i]->vma)
	break;
	}

	if (i) {
	entry_count -= i;
	memmove(&entries_address_ascending[0],
	&entries_address_ascending[i],
	sizeof(struct jitentry ) entry_count);
	}
	}


	/* Copy address_ascending array to entries_symbols_ascending and resort it. */
	static void resort_symbol(void)
	{
	memcpy(entries_symbols_ascending, entries_address_ascending,
	sizeof(struct jitentry ) entry_count);
	qsort(entries_symbols_ascending, entry_count,
	sizeof(struct jitentry *), cmp_symbolname);
	}

	/* allocate, populate and sort the jitentry arrays */
	void create_arrays(void)
	{
	max_entry_count = entry_count = count_entries();
	entries_symbols_ascending = create_sorted_array(cmp_symbolname);
	entries_address_ascending = create_sorted_array(cmp_address);
	}


	/* add a new create jitentry to the array. mallocs new arrays if space is
	* needed */
	static void insert_entry(struct jitentry * entry)
	{
	if (entry_count == max_entry_count) {
	if (max_entry_count < UINT32_MAX - 18)
	max_entry_count += 18;
	else if (max_entry_count < UINT32_MAX)
	max_entry_count += 1;
	else {
	fprintf(stderr, "Amount of JIT dump file entries is too large.\n");
	exit(EXIT_FAILURE);
	}
	entries_symbols_ascending = (struct jitentry **)
	xrealloc(entries_symbols_ascending,
	sizeof(struct jitentry ) max_entry_count);
	entries_address_ascending = (struct jitentry **)
	xrealloc(entries_address_ascending,
	sizeof(struct jitentry ) max_entry_count);
	}
	entries_address_ascending[entry_count++] = entry;
	}


	/* add a suffix to the name to differenciate it */
	static char * replacement_name(char * s, int i)
	{
	int cnt = 1;
	int j = i;
	char * res;

	while ((j = j/10))
	cnt++;
	cnt += 2 + strlen(s);
	res = xmalloc(cnt);
	snprintf(res, cnt, "%s~%i", s, i);
	return res;
	}


	/*
	* Mark the entry so it is not included in the ELF file. We do this by
	* writing a 0 address as magic vma and sorting
	* it out later
	*/
	static void invalidate_entry(struct jitentry * e)
	{
	verbprintf(debug, "invalidate_entry: addr=%llx, name=%s\n",
	e->vma, e->symbol_name);
	e->vma = 0;
	}


	/*
	* Invalidate all symbols that are not alive at sampling start time.
	*/
	static void invalidate_earlybirds(unsigned long long start_time)
	{
	u32 i;
	int flag;
	struct jitentry * a;

	flag = 0;
	for (i = 0; i < entry_count; i++) {
	a = entries_address_ascending[i];
	if (a->life_end < start_time) {
	invalidate_entry(a);
	flag = 1;
	}
	}
	if (flag) {
	resort_address();
	resort_symbol();
	}
	}


	/* select the symbol with the longest life time in the index range */
	static int select_one(int start_idx, int end_idx)
	{
	int i;
	int candidate = OP_JIT_CONV_FAIL;
	unsigned long long lifetime = 0;
	unsigned long long x;
	struct jitentry const * e;

	for (i = start_idx; i <= end_idx; i++) {
	e = entries_address_ascending[i];
	x = e->life_end - e->life_start;
	if (candidate == -1 \|\| x > lifetime) {
	candidate = i;
	lifetime = x;
	}
	}
	return candidate;
	}


	/*
	* We decided to keep one entry in favor of the other. Instead of dropping
	* the overlapping entry we split or truncate it to not overlap any more.
	*
	* Looking on the address regions, we may have the following situation:
	*
	* split: \|------------\|
	* keep: \|---\|
	*
	* The split entry may be splitted in a left part and a right part. E.g.:
	*
	* split0/1: \|--\| \|---\|
	* keep: \|---\|
	*
	* However, both parts may or may not exist.
	*/
	static void split_entry(struct jitentry * split, struct jitentry const * keep)
	{
	unsigned long long start_addr_keep = keep->vma;
	unsigned long long end_addr_keep = keep->vma + keep->code_size;
	unsigned long long end_addr_split = split->vma + split->code_size;
	unsigned long long start_addr_split = split->vma;

	// do we need a right part?
	if (end_addr_split > end_addr_keep) {
	struct jitentry * new_entry =
	xcalloc(1, sizeof(struct jitentry));
	char * s = NULL;

	/* Check for max. length to avoid possible integer overflow. */
	if (strlen(split->symbol_name) > SIZE_MAX - 3) {
	fprintf(stderr, "Length of symbol name is too large.\n");
	exit(EXIT_FAILURE);
	} else {
	s = xmalloc(strlen(split->symbol_name) + 3);
	strcpy(s, split->symbol_name);
	strcat(s, "#1");
	}

	new_entry->vma = end_addr_keep;
	new_entry->code_size = end_addr_split - end_addr_keep;
	new_entry->symbol_name = s;
	new_entry->sym_name_malloced = 1;
	new_entry->life_start = split->life_start;
	new_entry->life_end = split->life_end;
	// the right part does not have an associated code, because we
	// don't know whether the split part begins at an opcode
	new_entry->code = NULL;
	verbprintf(debug, "split right (new) name=%s, start=%llx,"
	" end=%llx\n", new_entry->symbol_name,
	new_entry->vma,
	new_entry->vma + new_entry->code_size);
	insert_entry(new_entry);
	}
	// do we need a left part?
	if (start_addr_split < start_addr_keep) {
	char * s = NULL;

	/* Check for max. length to avoid possible integer overflow. */
	if (strlen(split->symbol_name) > SIZE_MAX - 3) {
	fprintf(stderr, "Length of symbol name is too large.\n");
	exit(EXIT_FAILURE);
	} else {
	s = xmalloc(strlen(split->symbol_name) + 3);
	strcpy(s, split->symbol_name);
	strcat(s, "#0");
	}

	split->code_size = start_addr_keep - start_addr_split;
	if (split->sym_name_malloced)
	free(split->symbol_name);
	split->symbol_name = s;
	split->sym_name_malloced = 1;
	verbprintf(debug, "split left name=%s, start=%llx, end=%llx\n",
	split->symbol_name, split->vma,
	split->vma + split->code_size);
	} else {
	invalidate_entry(split);
	}
	}


	/*
	* Scans through the index range and splits/truncates entries that overlap
	* with the one indexed by keep_idx. Returns the total lifetime of the symbols
	* found to overlap.
	* Returns ULONG_MAX on error.
	*/
	static unsigned long long eliminate_overlaps(int start_idx, int end_idx,
	int keep_idx)
	{
	unsigned long long retval;
	struct jitentry const * keep = entries_address_ascending[keep_idx];
	struct jitentry * e;
	unsigned long long start_addr_keep = keep->vma;
	unsigned long long end_addr_keep = keep->vma + keep->code_size;
	unsigned long long start_addr_entry, end_addr_entry;
	int i;
	unsigned long long min_start = keep->life_start;
	unsigned long long max_end = keep->life_end;

	for (i = start_idx; i <= end_idx; i++) {
	if (i == keep_idx)
	continue;
	e = entries_address_ascending[i];
	start_addr_entry = e->vma;
	end_addr_entry = e->vma + e->code_size;
	if (debug) {
	if (!(start_addr_entry <= end_addr_entry)) {
	verbprintf(debug, "assert failed:"
	" start_addr_entry <="
	" end_addr_entry\n");
	retval = ULONG_MAX;
	goto out;
	}
	if (!(start_addr_keep <= end_addr_keep)) {
	verbprintf(debug, "assert failed: "
	"start_addr_keep <="
	" end_addr_keep\n");
	retval = ULONG_MAX;
	goto out;
	}
	}
	if (start_addr_entry < end_addr_keep &&
	end_addr_entry > start_addr_keep) {
	if (e->life_start < min_start)
	min_start = e->life_start;
	if (e->life_end > max_end)
	max_end = e->life_end;
	split_entry(e, keep);
	}
	}
	retval = max_end - min_start;
	out:
	return retval;
	}


	/*
	* Within the index range (into the array entries_address_ascending), find the
	* symbol with the maximal lifetime and split/truncate all symbols that overlap
	* with it (i.e. that there won't be any overlaps anymore).
	*/
	static int handle_overlap_region(int start_idx, int end_idx)
	{
	int rc = OP_JIT_CONV_OK;
	int idx;
	struct jitentry * e;
	int cnt;
	char * name;
	int i, j;
	unsigned long long totaltime;

	if (debug) {
	for (i = start_idx; i <= end_idx; i++) {
	e = entries_address_ascending[i];
	verbprintf(debug, "overlap idx=%i, name=%s, "
	"start=%llx, end=%llx, life_start=%lli, "
	"life_end=%lli, lifetime=%lli\n",
	i, e->symbol_name, e->vma,
	e->vma + e->code_size, e->life_start,
	e->life_end, e->life_end - e->life_start);
	}
	}
	idx = select_one(start_idx, end_idx);
	totaltime = eliminate_overlaps(start_idx, end_idx, idx);
	if (totaltime == ULONG_MAX) {
	rc = OP_JIT_CONV_FAIL;
	goto out;
	}
	e = entries_address_ascending[idx];

	cnt = 1;
	j = (e->life_end - e->life_start) * 100 / totaltime;
	while ((j = j/10))
	cnt++;

	// Mark symbol name with a %% to indicate the overlap.
	cnt += strlen(e->symbol_name) + 2 + 1;
	name = xmalloc(cnt);
	snprintf(name, cnt, "%s%%%llu", e->symbol_name,
	(e->life_end - e->life_start) * 100 / totaltime);
	if (e->sym_name_malloced)
	free(e->symbol_name);
	e->symbol_name = name;
	e->sym_name_malloced = 1;
	verbprintf(debug, "selected idx=%i, name=%s\n", idx, e->symbol_name);
	out:
	return rc;
	}


	/*
	* one scan through the symbols to find overlaps.
	* return 1 if an overlap is found. this is repeated until no more overlap
	* is there.
	* Process: There may be more than two overlapping symbols with each other.
	* The index range of symbols found to overlap are passed to
	* handle_overlap_region.
	*/
	static int scan_overlaps(void)
	{
	int i, j;
	unsigned long long end_addr, end_addr2;
	struct jitentry const * a;
	int flag = 0;
	// entry_count can be incremented by split_entry() during the loop,
	// save the inital value as loop count
	int loop_count = entry_count;

	verbprintf(debug,"count=%i, scan overlaps...\n", entry_count);
	i = 0;
	end_addr = 0;
	for (j = 1; j < loop_count; j++) {
	/**
	* Take a symbol [i] and look for the next symbol(s) [j] that are overlapping
	* symbol [i]. If a symbol [j] is found that is not overlapping symbol [i] the
	* symbols [i]..[j-1] are handled to be not overlapping anymore.
	* See descriptions of handle_overlap_region() and eliminate_overlaps() for
	* further details of this handling.
	* E.g. possible cases to be handled could be:
	*
	* sym1 \|-----------\|
	* sym2 \|---\|
	*
	* sym1 \|--------\|
	* sym2 \|--------\|
	*
	* sym1 \|--------\|
	* sym2 \|-------\|
	* sym3 \|---------\|
	*
	* But in the following case
	*
	* sym1 \|--------\|
	* sym2 \|-------------\|
	* sym3 \|----------\|
	*
	* sym3 would not overlap with sym1. Therefore handle_overlap_regio() would
	* only be called for sym1 up to sym2.
	*/
	a = entries_address_ascending[j - 1];
	end_addr2 = a->vma + a->code_size;
	if (end_addr2 > end_addr)
	end_addr = end_addr2;
	a = entries_address_ascending[j];
	if (end_addr <= a->vma) {
	if (i != j - 1) {
	if (handle_overlap_region(i, j - 1) ==
	OP_JIT_CONV_FAIL) {
	flag = OP_JIT_CONV_FAIL;
	goto out;
	}
	flag = 1;
	}
	i = j;
	}
	}
	if (i != j - 1) {
	if (handle_overlap_region(i, j - 1) == OP_JIT_CONV_FAIL)
	flag = OP_JIT_CONV_FAIL;
	else
	flag = 1;
	}
	out:
	return flag;
	}


	/* search for symbols that have overlapping address ranges and decide for
	* one */
	int resolve_overlaps(unsigned long long start_time)
	{
	int rc = OP_JIT_CONV_OK;
	int cnt = 0;

	invalidate_earlybirds(start_time);
	while ((rc = scan_overlaps()) && rc != OP_JIT_CONV_FAIL) {
	resort_address();
	if (cnt == 0) {
	verbprintf(debug, "WARNING: overlaps detected. "
	"Removing overlapping JIT methods\n");
	}
	cnt++;
	}
	if (cnt > 0 && rc != OP_JIT_CONV_FAIL)
	resort_symbol();
	return rc;
	}


	/*
	* scan through the sorted array and replace identical symbol names by unique
	* ones by adding a counter value.
	*/
	void disambiguate_symbol_names(void)
	{
	u32 j;
	int cnt, rep_cnt;
	struct jitentry * a;
	struct jitentry * b;

	rep_cnt = 0;
	for (j = 1; j < entry_count; j++) {
	a = entries_symbols_ascending[j - 1];
	cnt = 1;
	do {
	b = entries_symbols_ascending[j];
	if (strcmp(a->symbol_name, b->symbol_name) == 0) {
	if (b->sym_name_malloced)
	free(b->symbol_name);
	b->symbol_name =
	replacement_name(a->symbol_name, cnt);
	b->sym_name_malloced = 1;
	j++;
	cnt++;
	rep_cnt++;
	} else {
	break;
	}
	} while (j < entry_count);
	}
	/* recurse to avoid that the added suffix also creates a collision */
	if (rep_cnt) {
	qsort(entries_symbols_ascending, entry_count,
	sizeof(struct jitentry *), cmp_symbolname);
	disambiguate_symbol_names();
	}
	}