111
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1 /* Utility functions for reading gcda files into in-memory
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2 gcov_info structures and offline profile processing. */
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131
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3 /* Copyright (C) 2014-2018 Free Software Foundation, Inc.
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111
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4 Contributed by Rong Xu <xur@google.com>.
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5
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6 This file is part of GCC.
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7
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8 GCC is free software; you can redistribute it and/or modify it under
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9 the terms of the GNU General Public License as published by the Free
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10 Software Foundation; either version 3, or (at your option) any later
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11 version.
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12
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13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
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14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
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15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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16 for more details.
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17
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18 Under Section 7 of GPL version 3, you are granted additional
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19 permissions described in the GCC Runtime Library Exception, version
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20 3.1, as published by the Free Software Foundation.
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21
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22 You should have received a copy of the GNU General Public License and
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23 a copy of the GCC Runtime Library Exception along with this program;
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24 see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
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25 <http://www.gnu.org/licenses/>. */
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26
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27
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28 #define IN_GCOV_TOOL 1
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29
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30 #include "libgcov.h"
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31 #include "intl.h"
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32 #include "diagnostic.h"
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33 #include "version.h"
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34 #include "demangle.h"
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131
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35 #include "gcov-io.h"
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111
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36
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37 /* Borrowed from basic-block.h. */
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38 #define RDIV(X,Y) (((X) + (Y) / 2) / (Y))
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39
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40 extern gcov_position_t gcov_position();
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41 extern int gcov_is_error();
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42
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43 /* Verbose mode for debug. */
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44 static int verbose;
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45
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46 /* Set verbose flag. */
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47 void gcov_set_verbose (void)
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48 {
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49 verbose = 1;
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50 }
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51
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52 /* The following part is to read Gcda and reconstruct GCOV_INFO. */
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53
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54 #include "obstack.h"
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55 #include <unistd.h>
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56 #ifdef HAVE_FTW_H
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57 #include <ftw.h>
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58 #endif
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59
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60 static void tag_function (unsigned, unsigned);
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61 static void tag_blocks (unsigned, unsigned);
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62 static void tag_arcs (unsigned, unsigned);
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63 static void tag_lines (unsigned, unsigned);
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64 static void tag_counters (unsigned, unsigned);
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65 static void tag_summary (unsigned, unsigned);
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66
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67 /* The gcov_info for the first module. */
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68 static struct gcov_info *curr_gcov_info;
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69 /* The gcov_info being processed. */
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70 static struct gcov_info *gcov_info_head;
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71 /* This variable contains all the functions in current module. */
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72 static struct obstack fn_info;
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73 /* The function being processed. */
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74 static struct gcov_fn_info *curr_fn_info;
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75 /* The number of functions seen so far. */
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76 static unsigned num_fn_info;
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77 /* This variable contains all the counters for current module. */
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78 static int k_ctrs_mask[GCOV_COUNTERS];
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79 /* The kind of counters that have been seen. */
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80 static struct gcov_ctr_info k_ctrs[GCOV_COUNTERS];
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81 /* Number of kind of counters that have been seen. */
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82 static int k_ctrs_types;
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131
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83 /* The object summary being processed. */
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84 static struct gcov_summary *curr_object_summary;
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111
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85
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86 /* Merge functions for counters. */
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87 #define DEF_GCOV_COUNTER(COUNTER, NAME, FN_TYPE) __gcov_merge ## FN_TYPE,
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88 static gcov_merge_fn ctr_merge_functions[GCOV_COUNTERS] = {
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89 #include "gcov-counter.def"
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90 };
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91 #undef DEF_GCOV_COUNTER
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92
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93 /* Set the ctrs field in gcov_fn_info object FN_INFO. */
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94
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95 static void
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96 set_fn_ctrs (struct gcov_fn_info *fn_info)
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97 {
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98 int j = 0, i;
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99
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100 for (i = 0; i < GCOV_COUNTERS; i++)
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101 {
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102 if (k_ctrs_mask[i] == 0)
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103 continue;
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104 fn_info->ctrs[j].num = k_ctrs[i].num;
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105 fn_info->ctrs[j].values = k_ctrs[i].values;
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106 j++;
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107 }
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108 if (k_ctrs_types == 0)
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109 k_ctrs_types = j;
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110 else
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111 gcc_assert (j == k_ctrs_types);
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112 }
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113
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114 /* For each tag in gcda file, we have an entry here.
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115 TAG is the tag value; NAME is the tag name; and
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116 PROC is the handler function. */
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117
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118 typedef struct tag_format
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119 {
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120 unsigned tag;
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121 char const *name;
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122 void (*proc) (unsigned, unsigned);
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123 } tag_format_t;
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124
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125 /* Handler table for various Tags. */
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126
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127 static const tag_format_t tag_table[] =
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128 {
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129 {0, "NOP", NULL},
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130 {0, "UNKNOWN", NULL},
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131 {0, "COUNTERS", tag_counters},
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132 {GCOV_TAG_FUNCTION, "FUNCTION", tag_function},
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133 {GCOV_TAG_BLOCKS, "BLOCKS", tag_blocks},
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134 {GCOV_TAG_ARCS, "ARCS", tag_arcs},
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135 {GCOV_TAG_LINES, "LINES", tag_lines},
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136 {GCOV_TAG_OBJECT_SUMMARY, "OBJECT_SUMMARY", tag_summary},
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137 {0, NULL, NULL}
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138 };
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139
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140 /* Handler for reading function tag. */
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141
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142 static void
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143 tag_function (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED)
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144 {
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145 int i;
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146
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147 /* write out previous fn_info. */
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148 if (num_fn_info)
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149 {
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150 set_fn_ctrs (curr_fn_info);
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151 obstack_ptr_grow (&fn_info, curr_fn_info);
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152 }
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153
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154 /* Here we over allocate a bit, using GCOV_COUNTERS instead of the actual active
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155 counter types. */
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156 curr_fn_info = (struct gcov_fn_info *) xcalloc (sizeof (struct gcov_fn_info)
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157 + GCOV_COUNTERS * sizeof (struct gcov_ctr_info), 1);
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158
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159 for (i = 0; i < GCOV_COUNTERS; i++)
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160 k_ctrs[i].num = 0;
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161 k_ctrs_types = 0;
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162
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163 curr_fn_info->key = curr_gcov_info;
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164 curr_fn_info->ident = gcov_read_unsigned ();
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165 curr_fn_info->lineno_checksum = gcov_read_unsigned ();
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166 curr_fn_info->cfg_checksum = gcov_read_unsigned ();
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167 num_fn_info++;
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168
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169 if (verbose)
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170 fnotice (stdout, "tag one function id=%d\n", curr_fn_info->ident);
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171 }
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172
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173 /* Handler for reading block tag. */
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174
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175 static void
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176 tag_blocks (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED)
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177 {
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178 /* TBD: gcov-tool currently does not handle gcno files. Assert here. */
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179 gcc_unreachable ();
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180 }
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181
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182 /* Handler for reading flow arc tag. */
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183
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184 static void
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185 tag_arcs (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED)
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186 {
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187 /* TBD: gcov-tool currently does not handle gcno files. Assert here. */
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188 gcc_unreachable ();
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189 }
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190
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191 /* Handler for reading line tag. */
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192
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193 static void
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194 tag_lines (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED)
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195 {
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196 /* TBD: gcov-tool currently does not handle gcno files. Assert here. */
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197 gcc_unreachable ();
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198 }
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199
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200 /* Handler for reading counters array tag with value as TAG and length of LENGTH. */
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201
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202 static void
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203 tag_counters (unsigned tag, unsigned length)
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204 {
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205 unsigned n_counts = GCOV_TAG_COUNTER_NUM (length);
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206 gcov_type *values;
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207 unsigned ix;
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208 unsigned tag_ix;
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209
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210 tag_ix = GCOV_COUNTER_FOR_TAG (tag);
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211 gcc_assert (tag_ix < GCOV_COUNTERS);
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212 k_ctrs_mask [tag_ix] = 1;
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213 gcc_assert (k_ctrs[tag_ix].num == 0);
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214 k_ctrs[tag_ix].num = n_counts;
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215
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216 k_ctrs[tag_ix].values = values = (gcov_type *) xmalloc (n_counts * sizeof (gcov_type));
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217 gcc_assert (values);
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218
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219 for (ix = 0; ix != n_counts; ix++)
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220 values[ix] = gcov_read_counter ();
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221 }
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222
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223 /* Handler for reading summary tag. */
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224
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225 static void
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226 tag_summary (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED)
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227 {
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131
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228 curr_object_summary = (gcov_summary *) xcalloc (sizeof (gcov_summary), 1);
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229 gcov_read_summary (curr_object_summary);
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111
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230 }
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231
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232 /* This function is called at the end of reading a gcda file.
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233 It flushes the contents in curr_fn_info to gcov_info object OBJ_INFO. */
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234
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235 static void
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236 read_gcda_finalize (struct gcov_info *obj_info)
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237 {
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238 int i;
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239
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240 set_fn_ctrs (curr_fn_info);
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241 obstack_ptr_grow (&fn_info, curr_fn_info);
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242
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131
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243 /* We set the following fields: merge, n_functions, functions
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244 and summary. */
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111
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245 obj_info->n_functions = num_fn_info;
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246 obj_info->functions = (const struct gcov_fn_info**) obstack_finish (&fn_info);
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247
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248 /* wrap all the counter array. */
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249 for (i=0; i< GCOV_COUNTERS; i++)
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250 {
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251 if (k_ctrs_mask[i])
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252 obj_info->merge[i] = ctr_merge_functions[i];
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253 }
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254 }
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255
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256 /* Read the content of a gcda file FILENAME, and return a gcov_info data structure.
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257 Program level summary CURRENT_SUMMARY will also be updated. */
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258
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259 static struct gcov_info *
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260 read_gcda_file (const char *filename)
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261 {
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262 unsigned tags[4];
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263 unsigned depth = 0;
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264 unsigned magic, version;
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265 struct gcov_info *obj_info;
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266 int i;
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267
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268 for (i=0; i< GCOV_COUNTERS; i++)
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269 k_ctrs_mask[i] = 0;
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270 k_ctrs_types = 0;
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271
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272 if (!gcov_open (filename))
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273 {
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274 fnotice (stderr, "%s:cannot open\n", filename);
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275 return NULL;
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276 }
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277
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278 /* Read magic. */
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279 magic = gcov_read_unsigned ();
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280 if (magic != GCOV_DATA_MAGIC)
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281 {
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282 fnotice (stderr, "%s:not a gcov data file\n", filename);
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283 gcov_close ();
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284 return NULL;
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285 }
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286
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287 /* Read version. */
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288 version = gcov_read_unsigned ();
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289 if (version != GCOV_VERSION)
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290 {
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291 fnotice (stderr, "%s:incorrect gcov version %d vs %d \n", filename, version, GCOV_VERSION);
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292 gcov_close ();
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293 return NULL;
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294 }
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295
|
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296 /* Instantiate a gcov_info object. */
|
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297 curr_gcov_info = obj_info = (struct gcov_info *) xcalloc (sizeof (struct gcov_info) +
|
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298 sizeof (struct gcov_ctr_info) * GCOV_COUNTERS, 1);
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299
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300 obj_info->version = version;
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301 obstack_init (&fn_info);
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302 num_fn_info = 0;
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303 curr_fn_info = 0;
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131
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304 curr_object_summary = NULL;
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111
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305 {
|
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306 size_t len = strlen (filename) + 1;
|
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307 char *str_dup = (char*) xmalloc (len);
|
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308
|
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309 memcpy (str_dup, filename, len);
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310 obj_info->filename = str_dup;
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311 }
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312
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313 /* Read stamp. */
|
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314 obj_info->stamp = gcov_read_unsigned ();
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315
|
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316 while (1)
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317 {
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318 gcov_position_t base;
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319 unsigned tag, length;
|
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320 tag_format_t const *format;
|
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321 unsigned tag_depth;
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322 int error;
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323 unsigned mask;
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324
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325 tag = gcov_read_unsigned ();
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326 if (!tag)
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327 break;
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328 length = gcov_read_unsigned ();
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329 base = gcov_position ();
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330 mask = GCOV_TAG_MASK (tag) >> 1;
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331 for (tag_depth = 4; mask; mask >>= 8)
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332 {
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333 if (((mask & 0xff) != 0xff))
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334 {
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335 warning (0, "%s:tag `%x' is invalid\n", filename, tag);
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336 break;
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337 }
|
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338 tag_depth--;
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339 }
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340 for (format = tag_table; format->name; format++)
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341 if (format->tag == tag)
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342 goto found;
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343 format = &tag_table[GCOV_TAG_IS_COUNTER (tag) ? 2 : 1];
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344 found:;
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345 if (tag)
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346 {
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347 if (depth && depth < tag_depth)
|
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348 {
|
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349 if (!GCOV_TAG_IS_SUBTAG (tags[depth - 1], tag))
|
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350 warning (0, "%s:tag `%x' is incorrectly nested\n",
|
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351 filename, tag);
|
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352 }
|
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353 depth = tag_depth;
|
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354 tags[depth - 1] = tag;
|
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355 }
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356
|
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357 if (format->proc)
|
|
358 {
|
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359 unsigned long actual_length;
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360
|
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361 (*format->proc) (tag, length);
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362
|
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363 actual_length = gcov_position () - base;
|
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364 if (actual_length > length)
|
|
365 warning (0, "%s:record size mismatch %lu bytes overread\n",
|
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366 filename, actual_length - length);
|
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367 else if (length > actual_length)
|
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368 warning (0, "%s:record size mismatch %lu bytes unread\n",
|
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369 filename, length - actual_length);
|
|
370 }
|
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371
|
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372 gcov_sync (base, length);
|
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373 if ((error = gcov_is_error ()))
|
|
374 {
|
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375 warning (0, error < 0 ? "%s:counter overflow at %lu\n" :
|
|
376 "%s:read error at %lu\n", filename,
|
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377 (long unsigned) gcov_position ());
|
|
378 break;
|
|
379 }
|
|
380 }
|
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381
|
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382 read_gcda_finalize (obj_info);
|
|
383 gcov_close ();
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384
|
|
385 return obj_info;
|
|
386 }
|
|
387
|
|
388 #ifdef HAVE_FTW_H
|
|
389 /* This will be called by ftw(). It opens and read a gcda file FILENAME.
|
|
390 Return a non-zero value to stop the tree walk. */
|
|
391
|
|
392 static int
|
|
393 ftw_read_file (const char *filename,
|
|
394 const struct stat *status ATTRIBUTE_UNUSED,
|
|
395 int type)
|
|
396 {
|
|
397 int filename_len;
|
|
398 int suffix_len;
|
|
399 struct gcov_info *obj_info;
|
|
400
|
|
401 /* Only read regular files. */
|
|
402 if (type != FTW_F)
|
|
403 return 0;
|
|
404
|
|
405 filename_len = strlen (filename);
|
|
406 suffix_len = strlen (GCOV_DATA_SUFFIX);
|
|
407
|
|
408 if (filename_len <= suffix_len)
|
|
409 return 0;
|
|
410
|
|
411 if (strcmp(filename + filename_len - suffix_len, GCOV_DATA_SUFFIX))
|
|
412 return 0;
|
|
413
|
|
414 if (verbose)
|
|
415 fnotice (stderr, "reading file: %s\n", filename);
|
|
416
|
|
417 obj_info = read_gcda_file (filename);
|
|
418 if (!obj_info)
|
|
419 return 0;
|
|
420
|
|
421 obj_info->next = gcov_info_head;
|
|
422 gcov_info_head = obj_info;
|
|
423
|
|
424 return 0;
|
|
425 }
|
|
426 #endif
|
|
427
|
|
428 /* Initializer for reading a profile dir. */
|
|
429
|
|
430 static inline void
|
|
431 read_profile_dir_init (void)
|
|
432 {
|
|
433 gcov_info_head = 0;
|
|
434 }
|
|
435
|
|
436 /* Driver for read a profile directory and convert into gcov_info list in memory.
|
|
437 Return NULL on error,
|
|
438 Return the head of gcov_info list on success. */
|
|
439
|
|
440 struct gcov_info *
|
|
441 gcov_read_profile_dir (const char* dir_name, int recompute_summary ATTRIBUTE_UNUSED)
|
|
442 {
|
|
443 char *pwd;
|
|
444 int ret;
|
|
445
|
|
446 read_profile_dir_init ();
|
|
447
|
|
448 if (access (dir_name, R_OK) != 0)
|
|
449 {
|
|
450 fnotice (stderr, "cannot access directory %s\n", dir_name);
|
|
451 return NULL;
|
|
452 }
|
|
453 pwd = getcwd (NULL, 0);
|
|
454 gcc_assert (pwd);
|
|
455 ret = chdir (dir_name);
|
|
456 if (ret !=0)
|
|
457 {
|
|
458 fnotice (stderr, "%s is not a directory\n", dir_name);
|
|
459 return NULL;
|
|
460 }
|
|
461 #ifdef HAVE_FTW_H
|
|
462 ftw (".", ftw_read_file, 50);
|
|
463 #endif
|
|
464 ret = chdir (pwd);
|
|
465 free (pwd);
|
|
466
|
|
467
|
|
468 return gcov_info_head;;
|
|
469 }
|
|
470
|
|
471 /* This part of the code is to merge profile counters. These
|
|
472 variables are set in merge_wrapper and to be used by
|
|
473 global function gcov_read_counter_mem() and gcov_get_merge_weight. */
|
|
474
|
|
475 /* We save the counter value address to this variable. */
|
|
476 static gcov_type *gcov_value_buf;
|
|
477
|
|
478 /* The number of counter values to be read by current merging. */
|
|
479 static gcov_unsigned_t gcov_value_buf_size;
|
|
480
|
|
481 /* The index of counter values being read. */
|
|
482 static gcov_unsigned_t gcov_value_buf_pos;
|
|
483
|
|
484 /* The weight of current merging. */
|
|
485 static unsigned gcov_merge_weight;
|
|
486
|
|
487 /* Read a counter value from gcov_value_buf array. */
|
|
488
|
|
489 gcov_type
|
|
490 gcov_read_counter_mem (void)
|
|
491 {
|
|
492 gcov_type ret;
|
|
493 gcc_assert (gcov_value_buf_pos < gcov_value_buf_size);
|
|
494 ret = *(gcov_value_buf + gcov_value_buf_pos);
|
|
495 ++gcov_value_buf_pos;
|
|
496 return ret;
|
|
497 }
|
|
498
|
|
499 /* Return the recorded merge weight. */
|
|
500
|
|
501 unsigned
|
|
502 gcov_get_merge_weight (void)
|
|
503 {
|
|
504 return gcov_merge_weight;
|
|
505 }
|
|
506
|
|
507 /* A wrapper function for merge functions. It sets up the
|
|
508 value buffer and weights and then calls the merge function. */
|
|
509
|
|
510 static void
|
|
511 merge_wrapper (gcov_merge_fn f, gcov_type *v1, gcov_unsigned_t n,
|
|
512 gcov_type *v2, unsigned w)
|
|
513 {
|
|
514 gcov_value_buf = v2;
|
|
515 gcov_value_buf_pos = 0;
|
|
516 gcov_value_buf_size = n;
|
|
517 gcov_merge_weight = w;
|
|
518 (*f) (v1, n);
|
|
519 }
|
|
520
|
|
521 /* Offline tool to manipulate profile data.
|
|
522 This tool targets on matched profiles. But it has some tolerance on
|
|
523 unmatched profiles.
|
|
524 When merging p1 to p2 (p2 is the dst),
|
|
525 * m.gcda in p1 but not in p2: append m.gcda to p2 with specified weight;
|
|
526 emit warning
|
|
527 * m.gcda in p2 but not in p1: keep m.gcda in p2 and multiply by
|
|
528 specified weight; emit warning.
|
|
529 * m.gcda in both p1 and p2:
|
|
530 ** p1->m.gcda->f checksum matches p2->m.gcda->f: simple merge.
|
|
531 ** p1->m.gcda->f checksum does not matches p2->m.gcda->f: keep
|
|
532 p2->m.gcda->f and
|
|
533 drop p1->m.gcda->f. A warning is emitted. */
|
|
534
|
|
535 /* Add INFO2's counter to INFO1, multiplying by weight W. */
|
|
536
|
|
537 static int
|
|
538 gcov_merge (struct gcov_info *info1, struct gcov_info *info2, int w)
|
|
539 {
|
|
540 unsigned f_ix;
|
|
541 unsigned n_functions = info1->n_functions;
|
|
542 int has_mismatch = 0;
|
|
543
|
|
544 gcc_assert (info2->n_functions == n_functions);
|
|
545 for (f_ix = 0; f_ix < n_functions; f_ix++)
|
|
546 {
|
|
547 unsigned t_ix;
|
|
548 const struct gcov_fn_info *gfi_ptr1 = info1->functions[f_ix];
|
|
549 const struct gcov_fn_info *gfi_ptr2 = info2->functions[f_ix];
|
|
550 const struct gcov_ctr_info *ci_ptr1, *ci_ptr2;
|
|
551
|
|
552 if (!gfi_ptr1 || gfi_ptr1->key != info1)
|
|
553 continue;
|
|
554 if (!gfi_ptr2 || gfi_ptr2->key != info2)
|
|
555 continue;
|
|
556
|
|
557 if (gfi_ptr1->cfg_checksum != gfi_ptr2->cfg_checksum)
|
|
558 {
|
|
559 fnotice (stderr, "in %s, cfg_checksum mismatch, skipping\n",
|
|
560 info1->filename);
|
|
561 has_mismatch = 1;
|
|
562 continue;
|
|
563 }
|
|
564 ci_ptr1 = gfi_ptr1->ctrs;
|
|
565 ci_ptr2 = gfi_ptr2->ctrs;
|
|
566 for (t_ix = 0; t_ix != GCOV_COUNTERS; t_ix++)
|
|
567 {
|
|
568 gcov_merge_fn merge1 = info1->merge[t_ix];
|
|
569 gcov_merge_fn merge2 = info2->merge[t_ix];
|
|
570
|
|
571 gcc_assert (merge1 == merge2);
|
|
572 if (!merge1)
|
|
573 continue;
|
|
574 gcc_assert (ci_ptr1->num == ci_ptr2->num);
|
|
575 merge_wrapper (merge1, ci_ptr1->values, ci_ptr1->num, ci_ptr2->values, w);
|
|
576 ci_ptr1++;
|
|
577 ci_ptr2++;
|
|
578 }
|
|
579 }
|
|
580
|
|
581 return has_mismatch;
|
|
582 }
|
|
583
|
|
584 /* Find and return the match gcov_info object for INFO from ARRAY.
|
|
585 SIZE is the length of ARRAY.
|
|
586 Return NULL if there is no match. */
|
|
587
|
|
588 static struct gcov_info *
|
|
589 find_match_gcov_info (struct gcov_info **array, int size,
|
|
590 struct gcov_info *info)
|
|
591 {
|
|
592 struct gcov_info *gi_ptr;
|
|
593 struct gcov_info *ret = NULL;
|
|
594 int i;
|
|
595
|
|
596 for (i = 0; i < size; i++)
|
|
597 {
|
|
598 gi_ptr = array[i];
|
|
599 if (gi_ptr == 0)
|
|
600 continue;
|
|
601 if (!strcmp (gi_ptr->filename, info->filename))
|
|
602 {
|
|
603 ret = gi_ptr;
|
|
604 array[i] = 0;
|
|
605 break;
|
|
606 }
|
|
607 }
|
|
608
|
|
609 if (ret && ret->n_functions != info->n_functions)
|
|
610 {
|
|
611 fnotice (stderr, "mismatched profiles in %s (%d functions"
|
|
612 " vs %d functions)\n",
|
|
613 ret->filename,
|
|
614 ret->n_functions,
|
|
615 info->n_functions);
|
|
616 ret = NULL;
|
|
617 }
|
|
618 return ret;
|
|
619 }
|
|
620
|
|
621 /* Merge the list of gcov_info objects from SRC_PROFILE to TGT_PROFILE.
|
|
622 Return 0 on success: without mismatch.
|
|
623 Reutrn 1 on error. */
|
|
624
|
|
625 int
|
|
626 gcov_profile_merge (struct gcov_info *tgt_profile, struct gcov_info *src_profile,
|
|
627 int w1, int w2)
|
|
628 {
|
|
629 struct gcov_info *gi_ptr;
|
|
630 struct gcov_info **tgt_infos;
|
|
631 struct gcov_info *tgt_tail;
|
|
632 struct gcov_info **in_src_not_tgt;
|
|
633 unsigned tgt_cnt = 0, src_cnt = 0;
|
|
634 unsigned unmatch_info_cnt = 0;
|
|
635 unsigned int i;
|
|
636
|
|
637 for (gi_ptr = tgt_profile; gi_ptr; gi_ptr = gi_ptr->next)
|
|
638 tgt_cnt++;
|
|
639 for (gi_ptr = src_profile; gi_ptr; gi_ptr = gi_ptr->next)
|
|
640 src_cnt++;
|
|
641 tgt_infos = (struct gcov_info **) xmalloc (sizeof (struct gcov_info *)
|
|
642 * tgt_cnt);
|
|
643 gcc_assert (tgt_infos);
|
|
644 in_src_not_tgt = (struct gcov_info **) xmalloc (sizeof (struct gcov_info *)
|
|
645 * src_cnt);
|
|
646 gcc_assert (in_src_not_tgt);
|
|
647
|
|
648 for (gi_ptr = tgt_profile, i = 0; gi_ptr; gi_ptr = gi_ptr->next, i++)
|
|
649 tgt_infos[i] = gi_ptr;
|
|
650
|
|
651 tgt_tail = tgt_infos[tgt_cnt - 1];
|
|
652
|
|
653 /* First pass on tgt_profile, we multiply w1 to all counters. */
|
|
654 if (w1 > 1)
|
|
655 {
|
|
656 for (i = 0; i < tgt_cnt; i++)
|
|
657 gcov_merge (tgt_infos[i], tgt_infos[i], w1-1);
|
|
658 }
|
|
659
|
|
660 /* Second pass, add src_profile to the tgt_profile. */
|
|
661 for (gi_ptr = src_profile; gi_ptr; gi_ptr = gi_ptr->next)
|
|
662 {
|
|
663 struct gcov_info *gi_ptr1;
|
|
664
|
|
665 gi_ptr1 = find_match_gcov_info (tgt_infos, tgt_cnt, gi_ptr);
|
|
666 if (gi_ptr1 == NULL)
|
|
667 {
|
|
668 in_src_not_tgt[unmatch_info_cnt++] = gi_ptr;
|
|
669 continue;
|
|
670 }
|
|
671 gcov_merge (gi_ptr1, gi_ptr, w2);
|
|
672 }
|
|
673
|
|
674 /* For modules in src but not in tgt. We adjust the counter and append. */
|
|
675 for (i = 0; i < unmatch_info_cnt; i++)
|
|
676 {
|
|
677 gi_ptr = in_src_not_tgt[i];
|
|
678 gcov_merge (gi_ptr, gi_ptr, w2 - 1);
|
|
679 gi_ptr->next = NULL;
|
|
680 tgt_tail->next = gi_ptr;
|
|
681 tgt_tail = gi_ptr;
|
|
682 }
|
|
683
|
|
684 return 0;
|
|
685 }
|
|
686
|
|
687 typedef gcov_type (*counter_op_fn) (gcov_type, void*, void*);
|
|
688
|
|
689 /* Performing FN upon arc counters. */
|
|
690
|
|
691 static void
|
|
692 __gcov_add_counter_op (gcov_type *counters, unsigned n_counters,
|
|
693 counter_op_fn fn, void *data1, void *data2)
|
|
694 {
|
|
695 for (; n_counters; counters++, n_counters--)
|
|
696 {
|
|
697 gcov_type val = *counters;
|
|
698 *counters = fn(val, data1, data2);
|
|
699 }
|
|
700 }
|
|
701
|
|
702 /* Performing FN upon ior counters. */
|
|
703
|
|
704 static void
|
|
705 __gcov_ior_counter_op (gcov_type *counters ATTRIBUTE_UNUSED,
|
|
706 unsigned n_counters ATTRIBUTE_UNUSED,
|
|
707 counter_op_fn fn ATTRIBUTE_UNUSED,
|
|
708 void *data1 ATTRIBUTE_UNUSED,
|
|
709 void *data2 ATTRIBUTE_UNUSED)
|
|
710 {
|
|
711 /* Do nothing. */
|
|
712 }
|
|
713
|
|
714 /* Performing FN upon time-profile counters. */
|
|
715
|
|
716 static void
|
|
717 __gcov_time_profile_counter_op (gcov_type *counters ATTRIBUTE_UNUSED,
|
|
718 unsigned n_counters ATTRIBUTE_UNUSED,
|
|
719 counter_op_fn fn ATTRIBUTE_UNUSED,
|
|
720 void *data1 ATTRIBUTE_UNUSED,
|
|
721 void *data2 ATTRIBUTE_UNUSED)
|
|
722 {
|
|
723 /* Do nothing. */
|
|
724 }
|
|
725
|
|
726 /* Performing FN upon single counters. */
|
|
727
|
|
728 static void
|
|
729 __gcov_single_counter_op (gcov_type *counters, unsigned n_counters,
|
|
730 counter_op_fn fn, void *data1, void *data2)
|
|
731 {
|
|
732 unsigned i, n_measures;
|
|
733
|
|
734 gcc_assert (!(n_counters % 3));
|
|
735 n_measures = n_counters / 3;
|
|
736 for (i = 0; i < n_measures; i++, counters += 3)
|
|
737 {
|
|
738 counters[1] = fn (counters[1], data1, data2);
|
|
739 counters[2] = fn (counters[2], data1, data2);
|
|
740 }
|
|
741 }
|
|
742
|
|
743 /* Performing FN upon indirect-call profile counters. */
|
|
744
|
|
745 static void
|
|
746 __gcov_icall_topn_counter_op (gcov_type *counters, unsigned n_counters,
|
|
747 counter_op_fn fn, void *data1, void *data2)
|
|
748 {
|
|
749 unsigned i;
|
|
750
|
|
751 gcc_assert (!(n_counters % GCOV_ICALL_TOPN_NCOUNTS));
|
|
752 for (i = 0; i < n_counters; i += GCOV_ICALL_TOPN_NCOUNTS)
|
|
753 {
|
|
754 unsigned j;
|
|
755 gcov_type *value_array = &counters[i + 1];
|
|
756
|
|
757 for (j = 0; j < GCOV_ICALL_TOPN_NCOUNTS - 1; j += 2)
|
|
758 value_array[j + 1] = fn (value_array[j + 1], data1, data2);
|
|
759 }
|
|
760 }
|
|
761
|
|
762 /* Scaling the counter value V by multiplying *(float*) DATA1. */
|
|
763
|
|
764 static gcov_type
|
|
765 fp_scale (gcov_type v, void *data1, void *data2 ATTRIBUTE_UNUSED)
|
|
766 {
|
|
767 float f = *(float *) data1;
|
|
768 return (gcov_type) (v * f);
|
|
769 }
|
|
770
|
|
771 /* Scaling the counter value V by multiplying DATA2/DATA1. */
|
|
772
|
|
773 static gcov_type
|
|
774 int_scale (gcov_type v, void *data1, void *data2)
|
|
775 {
|
|
776 int n = *(int *) data1;
|
|
777 int d = *(int *) data2;
|
|
778 return (gcov_type) ( RDIV (v,d) * n);
|
|
779 }
|
|
780
|
|
781 /* Type of function used to process counters. */
|
|
782 typedef void (*gcov_counter_fn) (gcov_type *, gcov_unsigned_t,
|
|
783 counter_op_fn, void *, void *);
|
|
784
|
|
785 /* Function array to process profile counters. */
|
|
786 #define DEF_GCOV_COUNTER(COUNTER, NAME, FN_TYPE) \
|
|
787 __gcov ## FN_TYPE ## _counter_op,
|
|
788 static gcov_counter_fn ctr_functions[GCOV_COUNTERS] = {
|
|
789 #include "gcov-counter.def"
|
|
790 };
|
|
791 #undef DEF_GCOV_COUNTER
|
|
792
|
|
793 /* Driver for scaling profile counters. */
|
|
794
|
|
795 int
|
|
796 gcov_profile_scale (struct gcov_info *profile, float scale_factor, int n, int d)
|
|
797 {
|
|
798 struct gcov_info *gi_ptr;
|
|
799 unsigned f_ix;
|
|
800
|
|
801 if (verbose)
|
|
802 fnotice (stdout, "scale_factor is %f or %d/%d\n", scale_factor, n, d);
|
|
803
|
|
804 /* Scaling the counters. */
|
|
805 for (gi_ptr = profile; gi_ptr; gi_ptr = gi_ptr->next)
|
|
806 for (f_ix = 0; f_ix < gi_ptr->n_functions; f_ix++)
|
|
807 {
|
|
808 unsigned t_ix;
|
|
809 const struct gcov_fn_info *gfi_ptr = gi_ptr->functions[f_ix];
|
|
810 const struct gcov_ctr_info *ci_ptr;
|
|
811
|
|
812 if (!gfi_ptr || gfi_ptr->key != gi_ptr)
|
|
813 continue;
|
|
814
|
|
815 ci_ptr = gfi_ptr->ctrs;
|
|
816 for (t_ix = 0; t_ix != GCOV_COUNTERS; t_ix++)
|
|
817 {
|
|
818 gcov_merge_fn merge = gi_ptr->merge[t_ix];
|
|
819
|
|
820 if (!merge)
|
|
821 continue;
|
|
822 if (d == 0)
|
|
823 (*ctr_functions[t_ix]) (ci_ptr->values, ci_ptr->num,
|
|
824 fp_scale, &scale_factor, NULL);
|
|
825 else
|
|
826 (*ctr_functions[t_ix]) (ci_ptr->values, ci_ptr->num,
|
|
827 int_scale, &n, &d);
|
|
828 ci_ptr++;
|
|
829 }
|
|
830 }
|
|
831
|
|
832 return 0;
|
|
833 }
|
|
834
|
|
835 /* Driver to normalize profile counters. */
|
|
836
|
|
837 int
|
|
838 gcov_profile_normalize (struct gcov_info *profile, gcov_type max_val)
|
|
839 {
|
|
840 struct gcov_info *gi_ptr;
|
|
841 gcov_type curr_max_val = 0;
|
|
842 unsigned f_ix;
|
|
843 unsigned int i;
|
|
844 float scale_factor;
|
|
845
|
|
846 /* Find the largest count value. */
|
|
847 for (gi_ptr = profile; gi_ptr; gi_ptr = gi_ptr->next)
|
|
848 for (f_ix = 0; f_ix < gi_ptr->n_functions; f_ix++)
|
|
849 {
|
|
850 unsigned t_ix;
|
|
851 const struct gcov_fn_info *gfi_ptr = gi_ptr->functions[f_ix];
|
|
852 const struct gcov_ctr_info *ci_ptr;
|
|
853
|
|
854 if (!gfi_ptr || gfi_ptr->key != gi_ptr)
|
|
855 continue;
|
|
856
|
|
857 ci_ptr = gfi_ptr->ctrs;
|
|
858 for (t_ix = 0; t_ix < 1; t_ix++)
|
|
859 {
|
|
860 for (i = 0; i < ci_ptr->num; i++)
|
|
861 if (ci_ptr->values[i] > curr_max_val)
|
|
862 curr_max_val = ci_ptr->values[i];
|
|
863 ci_ptr++;
|
|
864 }
|
|
865 }
|
|
866
|
|
867 scale_factor = (float)max_val / curr_max_val;
|
|
868 if (verbose)
|
|
869 fnotice (stdout, "max_val is %" PRId64 "\n", curr_max_val);
|
|
870
|
|
871 return gcov_profile_scale (profile, scale_factor, 0, 0);
|
|
872 }
|
|
873
|
|
874 /* The following variables are defined in gcc/gcov-tool.c. */
|
|
875 extern int overlap_func_level;
|
|
876 extern int overlap_obj_level;
|
|
877 extern int overlap_hot_only;
|
|
878 extern int overlap_use_fullname;
|
|
879 extern double overlap_hot_threshold;
|
|
880
|
|
881 /* Compute the overlap score of two values. The score is defined as:
|
|
882 min (V1/SUM_1, V2/SUM_2) */
|
|
883
|
|
884 static double
|
|
885 calculate_2_entries (const unsigned long v1, const unsigned long v2,
|
|
886 const double sum_1, const double sum_2)
|
|
887 {
|
|
888 double val1 = (sum_1 == 0.0 ? 0.0 : v1/sum_1);
|
|
889 double val2 = (sum_2 == 0.0 ? 0.0 : v2/sum_2);
|
|
890
|
|
891 if (val2 < val1)
|
|
892 val1 = val2;
|
|
893
|
|
894 return val1;
|
|
895 }
|
|
896
|
|
897 /* Compute the overlap score between GCOV_INFO1 and GCOV_INFO2.
|
|
898 This function also updates cumulative score CUM_1_RESULT and
|
|
899 CUM_2_RESULT. */
|
|
900
|
|
901 static double
|
|
902 compute_one_gcov (const struct gcov_info *gcov_info1,
|
|
903 const struct gcov_info *gcov_info2,
|
|
904 const double sum_1, const double sum_2,
|
|
905 double *cum_1_result, double *cum_2_result)
|
|
906 {
|
|
907 unsigned f_ix;
|
|
908 double ret = 0;
|
|
909 double cum_1 = 0, cum_2 = 0;
|
|
910 const struct gcov_info *gcov_info = 0;
|
|
911 double *cum_p;
|
|
912 double sum;
|
|
913
|
|
914 gcc_assert (gcov_info1 || gcov_info2);
|
|
915 if (!gcov_info1)
|
|
916 {
|
|
917 gcov_info = gcov_info2;
|
|
918 cum_p = cum_2_result;
|
|
919 sum = sum_2;
|
|
920 *cum_1_result = 0;
|
|
921 } else
|
|
922 if (!gcov_info2)
|
|
923 {
|
|
924 gcov_info = gcov_info1;
|
|
925 cum_p = cum_1_result;
|
|
926 sum = sum_1;
|
|
927 *cum_2_result = 0;
|
|
928 }
|
|
929
|
|
930 if (gcov_info)
|
|
931 {
|
|
932 for (f_ix = 0; f_ix < gcov_info->n_functions; f_ix++)
|
|
933 {
|
|
934 const struct gcov_fn_info *gfi_ptr = gcov_info->functions[f_ix];
|
|
935 if (!gfi_ptr || gfi_ptr->key != gcov_info)
|
|
936 continue;
|
|
937 const struct gcov_ctr_info *ci_ptr = gfi_ptr->ctrs;
|
131
|
938 unsigned c_num;
|
|
939 for (c_num = 0; c_num < ci_ptr->num; c_num++)
|
|
940 cum_1 += ci_ptr->values[c_num] / sum;
|
111
|
941 }
|
|
942 *cum_p = cum_1;
|
|
943 return 0.0;
|
|
944 }
|
|
945
|
|
946 for (f_ix = 0; f_ix < gcov_info1->n_functions; f_ix++)
|
|
947 {
|
|
948 double func_cum_1 = 0.0;
|
|
949 double func_cum_2 = 0.0;
|
|
950 double func_val = 0.0;
|
|
951 int nonzero = 0;
|
|
952 int hot = 0;
|
|
953 const struct gcov_fn_info *gfi_ptr1 = gcov_info1->functions[f_ix];
|
|
954 const struct gcov_fn_info *gfi_ptr2 = gcov_info2->functions[f_ix];
|
|
955
|
|
956 if (!gfi_ptr1 || gfi_ptr1->key != gcov_info1)
|
|
957 continue;
|
|
958 if (!gfi_ptr2 || gfi_ptr2->key != gcov_info2)
|
|
959 continue;
|
|
960
|
|
961 const struct gcov_ctr_info *ci_ptr1 = gfi_ptr1->ctrs;
|
|
962 const struct gcov_ctr_info *ci_ptr2 = gfi_ptr2->ctrs;
|
131
|
963 unsigned c_num;
|
|
964 for (c_num = 0; c_num < ci_ptr1->num; c_num++)
|
|
965 {
|
|
966 if (ci_ptr1->values[c_num] | ci_ptr2->values[c_num])
|
|
967 {
|
|
968 func_val += calculate_2_entries (ci_ptr1->values[c_num],
|
|
969 ci_ptr2->values[c_num],
|
|
970 sum_1, sum_2);
|
111
|
971
|
131
|
972 func_cum_1 += ci_ptr1->values[c_num] / sum_1;
|
|
973 func_cum_2 += ci_ptr2->values[c_num] / sum_2;
|
|
974 nonzero = 1;
|
|
975 if (ci_ptr1->values[c_num] / sum_1 >= overlap_hot_threshold
|
|
976 || ci_ptr2->values[c_num] / sum_2 >= overlap_hot_threshold)
|
|
977 hot = 1;
|
|
978 }
|
|
979 }
|
111
|
980
|
|
981 ret += func_val;
|
|
982 cum_1 += func_cum_1;
|
|
983 cum_2 += func_cum_2;
|
|
984 if (overlap_func_level && nonzero && (!overlap_hot_only || hot))
|
|
985 {
|
|
986 printf(" \tfunc_id=%10d \toverlap =%6.5f%% (%5.5f%% %5.5f%%)\n",
|
|
987 gfi_ptr1->ident, func_val*100, func_cum_1*100, func_cum_2*100);
|
|
988 }
|
|
989 }
|
|
990 *cum_1_result = cum_1;
|
|
991 *cum_2_result = cum_2;
|
|
992 return ret;
|
|
993 }
|
|
994
|
|
995 /* Test if all counter values in this GCOV_INFO are cold.
|
|
996 "Cold" is defined as the counter value being less than
|
|
997 or equal to THRESHOLD. */
|
|
998
|
|
999 static bool
|
|
1000 gcov_info_count_all_cold (const struct gcov_info *gcov_info,
|
|
1001 gcov_type threshold)
|
|
1002 {
|
|
1003 unsigned f_ix;
|
|
1004
|
|
1005 for (f_ix = 0; f_ix < gcov_info->n_functions; f_ix++)
|
|
1006 {
|
|
1007 const struct gcov_fn_info *gfi_ptr = gcov_info->functions[f_ix];
|
|
1008
|
|
1009 if (!gfi_ptr || gfi_ptr->key != gcov_info)
|
|
1010 continue;
|
|
1011 const struct gcov_ctr_info *ci_ptr = gfi_ptr->ctrs;
|
131
|
1012 for (unsigned c_num = 0; c_num < ci_ptr->num; c_num++)
|
|
1013 if (ci_ptr->values[c_num] > threshold)
|
|
1014 return false;
|
111
|
1015 }
|
|
1016
|
|
1017 return true;
|
|
1018 }
|
|
1019
|
|
1020 /* Test if all counter values in this GCOV_INFO are 0. */
|
|
1021
|
|
1022 static bool
|
|
1023 gcov_info_count_all_zero (const struct gcov_info *gcov_info)
|
|
1024 {
|
|
1025 return gcov_info_count_all_cold (gcov_info, 0);
|
|
1026 }
|
|
1027
|
|
1028 /* A pair of matched GCOV_INFO.
|
|
1029 The flag is a bitvector:
|
|
1030 b0: obj1's all counts are 0;
|
|
1031 b1: obj1's all counts are cold (but no 0);
|
|
1032 b2: obj1 is hot;
|
|
1033 b3: no obj1 to match obj2;
|
|
1034 b4: obj2's all counts are 0;
|
|
1035 b5: obj2's all counts are cold (but no 0);
|
|
1036 b6: obj2 is hot;
|
|
1037 b7: no obj2 to match obj1;
|
|
1038 */
|
|
1039 struct overlap_t {
|
|
1040 const struct gcov_info *obj1;
|
|
1041 const struct gcov_info *obj2;
|
|
1042 char flag;
|
|
1043 };
|
|
1044
|
|
1045 #define FLAG_BOTH_ZERO(flag) ((flag & 0x1) && (flag & 0x10))
|
|
1046 #define FLAG_BOTH_COLD(flag) ((flag & 0x2) && (flag & 0x20))
|
|
1047 #define FLAG_ONE_HOT(flag) ((flag & 0x4) || (flag & 0x40))
|
|
1048
|
|
1049 /* Cumlative overlap dscore for profile1 and profile2. */
|
|
1050 static double overlap_sum_1, overlap_sum_2;
|
|
1051
|
|
1052 /* The number of gcda files in the profiles. */
|
|
1053 static unsigned gcda_files[2];
|
|
1054
|
|
1055 /* The number of unique gcda files in the profiles
|
|
1056 (not existing in the other profile). */
|
|
1057 static unsigned unique_gcda_files[2];
|
|
1058
|
|
1059 /* The number of gcda files that all counter values are 0. */
|
|
1060 static unsigned zero_gcda_files[2];
|
|
1061
|
|
1062 /* The number of gcda files that all counter values are cold (but not 0). */
|
|
1063 static unsigned cold_gcda_files[2];
|
|
1064
|
|
1065 /* The number of gcda files that includes hot counter values. */
|
|
1066 static unsigned hot_gcda_files[2];
|
|
1067
|
|
1068 /* The number of gcda files with hot count value in either profiles. */
|
|
1069 static unsigned both_hot_cnt;
|
|
1070
|
|
1071 /* The number of gcda files with all counts cold (but not 0) in
|
|
1072 both profiles. */
|
|
1073 static unsigned both_cold_cnt;
|
|
1074
|
|
1075 /* The number of gcda files with all counts 0 in both profiles. */
|
|
1076 static unsigned both_zero_cnt;
|
|
1077
|
|
1078 /* Extract the basename of the filename NAME. */
|
|
1079
|
|
1080 static char *
|
|
1081 extract_file_basename (const char *name)
|
|
1082 {
|
|
1083 char *str;
|
|
1084 int len = 0;
|
|
1085 char *path = xstrdup (name);
|
|
1086 char sep_str[2];
|
|
1087
|
|
1088 sep_str[0] = DIR_SEPARATOR;
|
|
1089 sep_str[1] = 0;
|
|
1090 str = strstr(path, sep_str);
|
|
1091 do{
|
|
1092 len = strlen(str) + 1;
|
|
1093 path = &path[strlen(path) - len + 2];
|
|
1094 str = strstr(path, sep_str);
|
|
1095 } while(str);
|
|
1096
|
|
1097 return path;
|
|
1098 }
|
|
1099
|
|
1100 /* Utility function to get the filename. */
|
|
1101
|
|
1102 static const char *
|
|
1103 get_file_basename (const char *name)
|
|
1104 {
|
|
1105 if (overlap_use_fullname)
|
|
1106 return name;
|
|
1107 return extract_file_basename (name);
|
|
1108 }
|
|
1109
|
|
1110 /* A utility function to set the flag for the gcda files. */
|
|
1111
|
|
1112 static void
|
|
1113 set_flag (struct overlap_t *e)
|
|
1114 {
|
|
1115 char flag = 0;
|
|
1116
|
|
1117 if (!e->obj1)
|
|
1118 {
|
|
1119 unique_gcda_files[1]++;
|
|
1120 flag = 0x8;
|
|
1121 }
|
|
1122 else
|
|
1123 {
|
|
1124 gcda_files[0]++;
|
|
1125 if (gcov_info_count_all_zero (e->obj1))
|
|
1126 {
|
|
1127 zero_gcda_files[0]++;
|
|
1128 flag = 0x1;
|
|
1129 }
|
|
1130 else
|
|
1131 if (gcov_info_count_all_cold (e->obj1, overlap_sum_1
|
|
1132 * overlap_hot_threshold))
|
|
1133 {
|
|
1134 cold_gcda_files[0]++;
|
|
1135 flag = 0x2;
|
|
1136 }
|
|
1137 else
|
|
1138 {
|
|
1139 hot_gcda_files[0]++;
|
|
1140 flag = 0x4;
|
|
1141 }
|
|
1142 }
|
|
1143
|
|
1144 if (!e->obj2)
|
|
1145 {
|
|
1146 unique_gcda_files[0]++;
|
|
1147 flag |= (0x8 << 4);
|
|
1148 }
|
|
1149 else
|
|
1150 {
|
|
1151 gcda_files[1]++;
|
|
1152 if (gcov_info_count_all_zero (e->obj2))
|
|
1153 {
|
|
1154 zero_gcda_files[1]++;
|
|
1155 flag |= (0x1 << 4);
|
|
1156 }
|
|
1157 else
|
|
1158 if (gcov_info_count_all_cold (e->obj2, overlap_sum_2
|
|
1159 * overlap_hot_threshold))
|
|
1160 {
|
|
1161 cold_gcda_files[1]++;
|
|
1162 flag |= (0x2 << 4);
|
|
1163 }
|
|
1164 else
|
|
1165 {
|
|
1166 hot_gcda_files[1]++;
|
|
1167 flag |= (0x4 << 4);
|
|
1168 }
|
|
1169 }
|
|
1170
|
|
1171 gcc_assert (flag);
|
|
1172 e->flag = flag;
|
|
1173 }
|
|
1174
|
|
1175 /* Test if INFO1 and INFO2 are from the matched source file.
|
|
1176 Return 1 if they match; return 0 otherwise. */
|
|
1177
|
|
1178 static int
|
|
1179 matched_gcov_info (const struct gcov_info *info1, const struct gcov_info *info2)
|
|
1180 {
|
|
1181 /* For FDO, we have to match the name. This can be expensive.
|
|
1182 Maybe we should use hash here. */
|
|
1183 if (strcmp (info1->filename, info2->filename))
|
|
1184 return 0;
|
|
1185
|
|
1186 if (info1->n_functions != info2->n_functions)
|
|
1187 {
|
|
1188 fnotice (stderr, "mismatched profiles in %s (%d functions"
|
|
1189 " vs %d functions)\n",
|
|
1190 info1->filename,
|
|
1191 info1->n_functions,
|
|
1192 info2->n_functions);
|
|
1193 return 0;
|
|
1194 }
|
|
1195 return 1;
|
|
1196 }
|
|
1197
|
|
1198 /* Compute the overlap score of two profiles with the head of GCOV_LIST1 and
|
|
1199 GCOV_LIST1. Return a number ranging from [0.0, 1.0], with 0.0 meaning no
|
|
1200 match and 1.0 meaning a perfect match. */
|
|
1201
|
|
1202 static double
|
|
1203 calculate_overlap (struct gcov_info *gcov_list1,
|
|
1204 struct gcov_info *gcov_list2)
|
|
1205 {
|
|
1206 unsigned list1_cnt = 0, list2_cnt= 0, all_cnt;
|
|
1207 unsigned int i, j;
|
|
1208 const struct gcov_info *gi_ptr;
|
|
1209 struct overlap_t *all_infos;
|
|
1210
|
|
1211 for (gi_ptr = gcov_list1; gi_ptr; gi_ptr = gi_ptr->next)
|
|
1212 list1_cnt++;
|
|
1213 for (gi_ptr = gcov_list2; gi_ptr; gi_ptr = gi_ptr->next)
|
|
1214 list2_cnt++;
|
|
1215 all_cnt = list1_cnt + list2_cnt;
|
|
1216 all_infos = (struct overlap_t *) xmalloc (sizeof (struct overlap_t)
|
|
1217 * all_cnt * 2);
|
|
1218 gcc_assert (all_infos);
|
|
1219
|
|
1220 i = 0;
|
|
1221 for (gi_ptr = gcov_list1; gi_ptr; gi_ptr = gi_ptr->next, i++)
|
|
1222 {
|
|
1223 all_infos[i].obj1 = gi_ptr;
|
|
1224 all_infos[i].obj2 = 0;
|
|
1225 }
|
|
1226
|
|
1227 for (gi_ptr = gcov_list2; gi_ptr; gi_ptr = gi_ptr->next, i++)
|
|
1228 {
|
|
1229 all_infos[i].obj1 = 0;
|
|
1230 all_infos[i].obj2 = gi_ptr;
|
|
1231 }
|
|
1232
|
|
1233 for (i = list1_cnt; i < all_cnt; i++)
|
|
1234 {
|
|
1235 if (all_infos[i].obj2 == 0)
|
|
1236 continue;
|
|
1237 for (j = 0; j < list1_cnt; j++)
|
|
1238 {
|
|
1239 if (all_infos[j].obj2 != 0)
|
|
1240 continue;
|
|
1241 if (matched_gcov_info (all_infos[i].obj2, all_infos[j].obj1))
|
|
1242 {
|
|
1243 all_infos[j].obj2 = all_infos[i].obj2;
|
|
1244 all_infos[i].obj2 = 0;
|
|
1245 break;
|
|
1246 }
|
|
1247 }
|
|
1248 }
|
|
1249
|
|
1250 for (i = 0; i < all_cnt; i++)
|
|
1251 if (all_infos[i].obj1 || all_infos[i].obj2)
|
|
1252 {
|
|
1253 set_flag (all_infos + i);
|
|
1254 if (FLAG_ONE_HOT (all_infos[i].flag))
|
|
1255 both_hot_cnt++;
|
|
1256 if (FLAG_BOTH_COLD(all_infos[i].flag))
|
|
1257 both_cold_cnt++;
|
|
1258 if (FLAG_BOTH_ZERO(all_infos[i].flag))
|
|
1259 both_zero_cnt++;
|
|
1260 }
|
|
1261
|
|
1262 double prg_val = 0;
|
|
1263 double sum_val = 0;
|
|
1264 double sum_cum_1 = 0;
|
|
1265 double sum_cum_2 = 0;
|
|
1266
|
|
1267 for (i = 0; i < all_cnt; i++)
|
|
1268 {
|
|
1269 double val;
|
|
1270 double cum_1, cum_2;
|
|
1271 const char *filename;
|
|
1272
|
|
1273 if (all_infos[i].obj1 == 0 && all_infos[i].obj2 == 0)
|
|
1274 continue;
|
|
1275 if (FLAG_BOTH_ZERO (all_infos[i].flag))
|
|
1276 continue;
|
|
1277
|
|
1278 if (all_infos[i].obj1)
|
|
1279 filename = get_file_basename (all_infos[i].obj1->filename);
|
|
1280 else
|
|
1281 filename = get_file_basename (all_infos[i].obj2->filename);
|
|
1282
|
|
1283 if (overlap_func_level)
|
|
1284 printf("\n processing %36s:\n", filename);
|
|
1285
|
|
1286 val = compute_one_gcov (all_infos[i].obj1, all_infos[i].obj2,
|
|
1287 overlap_sum_1, overlap_sum_2, &cum_1, &cum_2);
|
|
1288
|
|
1289 if (overlap_obj_level && (!overlap_hot_only || FLAG_ONE_HOT (all_infos[i].flag)))
|
|
1290 {
|
|
1291 printf(" obj=%36s overlap = %6.2f%% (%5.2f%% %5.2f%%)\n",
|
|
1292 filename, val*100, cum_1*100, cum_2*100);
|
|
1293 sum_val += val;
|
|
1294 sum_cum_1 += cum_1;
|
|
1295 sum_cum_2 += cum_2;
|
|
1296 }
|
|
1297
|
|
1298 prg_val += val;
|
|
1299
|
|
1300 }
|
|
1301
|
|
1302 if (overlap_obj_level)
|
|
1303 printf(" SUM:%36s overlap = %6.2f%% (%5.2f%% %5.2f%%)\n",
|
|
1304 "", sum_val*100, sum_cum_1*100, sum_cum_2*100);
|
|
1305
|
|
1306 printf (" Statistics:\n"
|
|
1307 " profile1_# profile2_# overlap_#\n");
|
|
1308 printf (" gcda files: %12u\t%12u\t%12u\n", gcda_files[0], gcda_files[1],
|
|
1309 gcda_files[0]-unique_gcda_files[0]);
|
|
1310 printf (" unique files: %12u\t%12u\n", unique_gcda_files[0],
|
|
1311 unique_gcda_files[1]);
|
|
1312 printf (" hot files: %12u\t%12u\t%12u\n", hot_gcda_files[0],
|
|
1313 hot_gcda_files[1], both_hot_cnt);
|
|
1314 printf (" cold files: %12u\t%12u\t%12u\n", cold_gcda_files[0],
|
|
1315 cold_gcda_files[1], both_cold_cnt);
|
|
1316 printf (" zero files: %12u\t%12u\t%12u\n", zero_gcda_files[0],
|
|
1317 zero_gcda_files[1], both_zero_cnt);
|
|
1318
|
|
1319 return prg_val;
|
|
1320 }
|
|
1321
|
|
1322 /* Compute the overlap score of two lists of gcov_info objects PROFILE1 and
|
|
1323 PROFILE2.
|
|
1324 Return 0 on success: without mismatch. Reutrn 1 on error. */
|
|
1325
|
|
1326 int
|
|
1327 gcov_profile_overlap (struct gcov_info *profile1, struct gcov_info *profile2)
|
|
1328 {
|
|
1329 double result;
|
|
1330
|
|
1331 result = calculate_overlap (profile1, profile2);
|
|
1332
|
|
1333 if (result > 0)
|
|
1334 {
|
|
1335 printf("\nProgram level overlap result is %3.2f%%\n\n", result*100);
|
|
1336 return 0;
|
|
1337 }
|
|
1338 return 1;
|
|
1339 }
|