| … | |
… | |
| 58 | |
58 | |
| 59 | =head2 TYPES / TYPE SUPPORT |
59 | =head2 TYPES / TYPE SUPPORT |
| 60 | |
60 | |
| 61 | ecb.h makes sure that the following types are defined (in the expected way): |
61 | ecb.h makes sure that the following types are defined (in the expected way): |
| 62 | |
62 | |
| 63 | int8_t uint8_t int16_t uint16_t |
63 | int8_t uint8_ |
| 64 | int32_t uint32_t int64_t uint64_t |
64 | int16_t uint16_t |
|
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65 | int32_t uint32_ |
|
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66 | int64_t uint64_t |
|
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67 | int_fast8_t uint_fast8_t |
|
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68 | int_fast16_t uint_fast16_t |
|
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69 | int_fast32_t uint_fast32_t |
|
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70 | int_fast64_t uint_fast64_t |
| 65 | intptr_t uintptr_t |
71 | intptr_t uintptr_t |
| 66 | |
72 | |
| 67 | The macro C<ECB_PTRSIZE> is defined to the size of a pointer on this |
73 | The macro C<ECB_PTRSIZE> is defined to the size of a pointer on this |
| 68 | platform (currently C<4> or C<8>). |
74 | platform (currently C<4> or C<8>) and can be used in preprocessor |
|
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75 | expressions. |
| 69 | |
76 | |
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77 | For C<ptrdiff_t> and C<size_t> use C<stddef.h>/C<cstddef>. |
|
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78 | |
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79 | =head2 LANGUAGE/ENVIRONMENT/COMPILER VERSIONS |
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80 | |
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81 | All the following symbols expand to an expression that can be tested in |
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82 | preprocessor instructions as well as treated as a boolean (use C<!!> to |
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83 | ensure it's either C<0> or C<1> if you need that). |
|
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84 | |
|
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85 | =over 4 |
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86 | |
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87 | =item ECB_C |
|
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88 | |
|
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89 | True if the implementation defines the C<__STDC__> macro to a true value, |
|
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90 | while not claiming to be C++. |
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91 | |
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92 | =item ECB_C99 |
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93 | |
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94 | True if the implementation claims to be compliant to C99 (ISO/IEC |
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95 | 9899:1999) or any later version, while not claiming to be C++. |
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96 | |
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97 | Note that later versions (ECB_C11) remove core features again (for |
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98 | example, variable length arrays). |
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99 | |
|
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100 | =item ECB_C11, ECB_C17 |
|
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101 | |
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102 | True if the implementation claims to be compliant to C11/C17 (ISO/IEC |
|
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103 | 9899:2011, :20187) or any later version, while not claiming to be C++. |
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104 | |
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105 | =item ECB_CPP |
|
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106 | |
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107 | True if the implementation defines the C<__cplusplus__> macro to a true |
|
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108 | value, which is typically true for C++ compilers. |
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109 | |
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110 | =item ECB_CPP11, ECB_CPP14, ECB_CPP17 |
|
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111 | |
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112 | True if the implementation claims to be compliant to C++11/C++14/C++17 |
|
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113 | (ISO/IEC 14882:2011, :2014, :2017) or any later version. |
|
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114 | |
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115 | =item ECB_GCC_VERSION (major, minor) |
|
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116 | |
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117 | Expands to a true value (suitable for testing in by the preprocessor) |
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118 | if the compiler used is GNU C and the version is the given version, or |
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119 | higher. |
|
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120 | |
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121 | This macro tries to return false on compilers that claim to be GCC |
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122 | compatible but aren't. |
|
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123 | |
|
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124 | =item ECB_EXTERN_C |
|
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125 | |
|
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126 | Expands to C<extern "C"> in C++, and a simple C<extern> in C. |
|
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127 | |
|
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128 | This can be used to declare a single external C function: |
|
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129 | |
|
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130 | ECB_EXTERN_C int printf (const char *format, ...); |
|
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131 | |
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132 | =item ECB_EXTERN_C_BEG / ECB_EXTERN_C_END |
|
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133 | |
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134 | These two macros can be used to wrap multiple C<extern "C"> definitions - |
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135 | they expand to nothing in C. |
|
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136 | |
|
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137 | They are most useful in header files: |
|
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138 | |
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139 | ECB_EXTERN_C_BEG |
|
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140 | |
|
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141 | int mycfun1 (int x); |
|
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142 | int mycfun2 (int x); |
|
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143 | |
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144 | ECB_EXTERN_C_END |
|
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145 | |
|
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146 | =item ECB_STDFP |
|
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147 | |
|
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148 | If this evaluates to a true value (suitable for testing in by the |
|
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149 | preprocessor), then C<float> and C<double> use IEEE 754 single/binary32 |
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150 | and double/binary64 representations internally I<and> the endianness of |
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151 | both types match the endianness of C<uint32_t> and C<uint64_t>. |
|
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152 | |
|
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153 | This means you can just copy the bits of a C<float> (or C<double>) to an |
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154 | C<uint32_t> (or C<uint64_t>) and get the raw IEEE 754 bit representation |
|
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155 | without having to think about format or endianness. |
|
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156 | |
|
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157 | This is true for basically all modern platforms, although F<ecb.h> might |
|
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158 | not be able to deduce this correctly everywhere and might err on the safe |
|
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159 | side. |
|
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160 | |
|
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161 | =item ECB_AMD64, ECB_AMD64_X32 |
|
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162 | |
|
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163 | These two macros are defined to C<1> on the x86_64/amd64 ABI and the X32 |
|
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164 | ABI, respectively, and undefined elsewhere. |
|
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165 | |
|
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166 | The designers of the new X32 ABI for some inexplicable reason decided to |
|
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167 | make it look exactly like amd64, even though it's completely incompatible |
|
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168 | to that ABI, breaking about every piece of software that assumed that |
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169 | C<__x86_64> stands for, well, the x86-64 ABI, making these macros |
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170 | necessary. |
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171 | |
|
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172 | =back |
|
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173 | |
|
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174 | =head2 MACRO TRICKERY |
|
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175 | |
|
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176 | =over 4 |
|
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177 | |
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178 | =item ECB_CONCAT (a, b) |
|
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179 | |
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180 | Expands any macros in C<a> and C<b>, then concatenates the result to form |
|
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181 | a single token. This is mainly useful to form identifiers from components, |
|
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182 | e.g.: |
|
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183 | |
|
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184 | #define S1 str |
|
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185 | #define S2 cpy |
|
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186 | |
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187 | ECB_CONCAT (S1, S2)(dst, src); // == strcpy (dst, src); |
|
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188 | |
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189 | =item ECB_STRINGIFY (arg) |
|
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190 | |
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191 | Expands any macros in C<arg> and returns the stringified version of |
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192 | it. This is mainly useful to get the contents of a macro in string form, |
|
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193 | e.g.: |
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194 | |
|
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195 | #define SQL_LIMIT 100 |
|
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196 | sql_exec ("select * from table limit " ECB_STRINGIFY (SQL_LIMIT)); |
|
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197 | |
|
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198 | =item ECB_STRINGIFY_EXPR (expr) |
|
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199 | |
|
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200 | Like C<ECB_STRINGIFY>, but additionally evaluates C<expr> to make sure it |
|
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201 | is a valid expression. This is useful to catch typos or cases where the |
|
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202 | macro isn't available: |
|
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203 | |
|
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204 | #include <errno.h> |
|
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205 | |
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206 | ECB_STRINGIFY (EDOM); // "33" (on my system at least) |
|
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207 | ECB_STRINGIFY_EXPR (EDOM); // "33" |
|
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208 | |
|
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209 | // now imagine we had a typo: |
|
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210 | |
|
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211 | ECB_STRINGIFY (EDAM); // "EDAM" |
|
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212 | ECB_STRINGIFY_EXPR (EDAM); // error: EDAM undefined |
|
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213 | |
|
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214 | =back |
|
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215 | |
| 70 | =head2 GCC ATTRIBUTES |
216 | =head2 ATTRIBUTES |
| 71 | |
217 | |
| 72 | A major part of libecb deals with GCC attributes. These are additional |
218 | A major part of libecb deals with additional attributes that can be |
| 73 | attributes that you can assign to functions, variables and sometimes even |
219 | assigned to functions, variables and sometimes even types - much like |
| 74 | types - much like C<const> or C<volatile> in C. |
220 | C<const> or C<volatile> in C. They are implemented using either GCC |
| 75 | |
221 | attributes or other compiler/language specific features. Attributes |
| 76 | While GCC allows declarations to show up in many surprising places, |
|
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| 77 | but not in many expected places, the safest way is to put attribute |
|
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| 78 | declarations before the whole declaration: |
222 | declarations must be put before the whole declaration: |
| 79 | |
223 | |
| 80 | ecb_const int mysqrt (int a); |
224 | ecb_const int mysqrt (int a); |
| 81 | ecb_unused int i; |
225 | ecb_unused int i; |
| 82 | |
226 | |
| 83 | For variables, it is often nicer to put the attribute after the name, and |
|
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| 84 | avoid multiple declarations using commas: |
|
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| 85 | |
|
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| 86 | int i ecb_unused; |
|
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| 87 | |
|
|
| 88 | =over 4 |
227 | =over 4 |
| 89 | |
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| 90 | =item ecb_attribute ((attrs...)) |
|
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| 91 | |
|
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| 92 | A simple wrapper that expands to C<__attribute__((attrs))> on GCC, and to |
|
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| 93 | nothing on other compilers, so the effect is that only GCC sees these. |
|
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| 94 | |
|
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| 95 | Example: use the C<deprecated> attribute on a function. |
|
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| 96 | |
|
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| 97 | ecb_attribute((__deprecated__)) void |
|
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| 98 | do_not_use_me_anymore (void); |
|
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| 99 | |
228 | |
| 100 | =item ecb_unused |
229 | =item ecb_unused |
| 101 | |
230 | |
| 102 | Marks a function or a variable as "unused", which simply suppresses a |
231 | Marks a function or a variable as "unused", which simply suppresses a |
| 103 | warning by GCC when it detects it as unused. This is useful when you e.g. |
232 | warning by GCC when it detects it as unused. This is useful when you e.g. |
| 104 | declare a variable but do not always use it: |
233 | declare a variable but do not always use it: |
| 105 | |
234 | |
| 106 | { |
235 | { |
| 107 | int var ecb_unused; |
236 | ecb_unused int var; |
| 108 | |
237 | |
| 109 | #ifdef SOMECONDITION |
238 | #ifdef SOMECONDITION |
| 110 | var = ...; |
239 | var = ...; |
| 111 | return var; |
240 | return var; |
| 112 | #else |
241 | #else |
| 113 | return 0; |
242 | return 0; |
| 114 | #endif |
243 | #endif |
| 115 | } |
244 | } |
| 116 | |
245 | |
|
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246 | =item ecb_deprecated |
|
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247 | |
|
|
248 | Similar to C<ecb_unused>, but marks a function, variable or type as |
|
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249 | deprecated. This makes some compilers warn when the type is used. |
|
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250 | |
|
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251 | =item ecb_deprecated_message (message) |
|
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252 | |
|
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253 | Same as C<ecb_deprecated>, but if possible, the specified diagnostic is |
|
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254 | used instead of a generic depreciation message when the object is being |
|
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255 | used. |
|
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256 | |
| 117 | =item ecb_inline |
257 | =item ecb_inline |
| 118 | |
258 | |
| 119 | This is not actually an attribute, but you use it like one. It expands |
259 | Expands either to (a compiler-specific equivalent of) C<static inline> or |
| 120 | either to C<static inline> or to just C<static>, if inline isn't |
260 | to just C<static>, if inline isn't supported. It should be used to declare |
| 121 | supported. It should be used to declare functions that should be inlined, |
261 | functions that should be inlined, for code size or speed reasons. |
| 122 | for code size or speed reasons. |
|
|
| 123 | |
262 | |
| 124 | Example: inline this function, it surely will reduce codesize. |
263 | Example: inline this function, it surely will reduce codesize. |
| 125 | |
264 | |
| 126 | ecb_inline int |
265 | ecb_inline int |
| 127 | negmul (int a, int b) |
266 | negmul (int a, int b) |
| … | |
… | |
| 129 | return - (a * b); |
268 | return - (a * b); |
| 130 | } |
269 | } |
| 131 | |
270 | |
| 132 | =item ecb_noinline |
271 | =item ecb_noinline |
| 133 | |
272 | |
| 134 | Prevent a function from being inlined - it might be optimised away, but |
273 | Prevents a function from being inlined - it might be optimised away, but |
| 135 | not inlined into other functions. This is useful if you know your function |
274 | not inlined into other functions. This is useful if you know your function |
| 136 | is rarely called and large enough for inlining not to be helpful. |
275 | is rarely called and large enough for inlining not to be helpful. |
| 137 | |
276 | |
| 138 | =item ecb_noreturn |
277 | =item ecb_noreturn |
| 139 | |
278 | |
| … | |
… | |
| 149 | } |
288 | } |
| 150 | |
289 | |
| 151 | In this case, the compiler would probably be smart enough to deduce it on |
290 | In this case, the compiler would probably be smart enough to deduce it on |
| 152 | its own, so this is mainly useful for declarations. |
291 | its own, so this is mainly useful for declarations. |
| 153 | |
292 | |
|
|
293 | =item ecb_restrict |
|
|
294 | |
|
|
295 | Expands to the C<restrict> keyword or equivalent on compilers that support |
|
|
296 | them, and to nothing on others. Must be specified on a pointer type or |
|
|
297 | an array index to indicate that the memory doesn't alias with any other |
|
|
298 | restricted pointer in the same scope. |
|
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299 | |
|
|
300 | Example: multiply a vector, and allow the compiler to parallelise the |
|
|
301 | loop, because it knows it doesn't overwrite input values. |
|
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302 | |
|
|
303 | void |
|
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304 | multiply (ecb_restrict float *src, |
|
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305 | ecb_restrict float *dst, |
|
|
306 | int len, float factor) |
|
|
307 | { |
|
|
308 | int i; |
|
|
309 | |
|
|
310 | for (i = 0; i < len; ++i) |
|
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311 | dst [i] = src [i] * factor; |
|
|
312 | } |
|
|
313 | |
| 154 | =item ecb_const |
314 | =item ecb_const |
| 155 | |
315 | |
| 156 | Declares that the function only depends on the values of its arguments, |
316 | Declares that the function only depends on the values of its arguments, |
| 157 | much like a mathematical function. It specifically does not read or write |
317 | much like a mathematical function. It specifically does not read or write |
| 158 | any memory any arguments might point to, global variables, or call any |
318 | any memory any arguments might point to, global variables, or call any |
| … | |
… | |
| 218 | functions only called in exceptional or rare cases. |
378 | functions only called in exceptional or rare cases. |
| 219 | |
379 | |
| 220 | =item ecb_artificial |
380 | =item ecb_artificial |
| 221 | |
381 | |
| 222 | Declares the function as "artificial", in this case meaning that this |
382 | Declares the function as "artificial", in this case meaning that this |
| 223 | function is not really mean to be a function, but more like an accessor |
383 | function is not really meant to be a function, but more like an accessor |
| 224 | - many methods in C++ classes are mere accessor functions, and having a |
384 | - many methods in C++ classes are mere accessor functions, and having a |
| 225 | crash reported in such a method, or single-stepping through them, is not |
385 | crash reported in such a method, or single-stepping through them, is not |
| 226 | usually so helpful, especially when it's inlined to just a few instructions. |
386 | usually so helpful, especially when it's inlined to just a few instructions. |
| 227 | |
387 | |
| 228 | Marking them as artificial will instruct the debugger about just this, |
388 | Marking them as artificial will instruct the debugger about just this, |
| … | |
… | |
| 248 | |
408 | |
| 249 | =head2 OPTIMISATION HINTS |
409 | =head2 OPTIMISATION HINTS |
| 250 | |
410 | |
| 251 | =over 4 |
411 | =over 4 |
| 252 | |
412 | |
|
|
413 | =item ECB_OPTIMIZE_SIZE |
|
|
414 | |
|
|
415 | Is C<1> when the compiler optimizes for size, C<0> otherwise. This symbol |
|
|
416 | can also be defined before including F<ecb.h>, in which case it will be |
|
|
417 | unchanged. |
|
|
418 | |
| 253 | =item bool ecb_is_constant(expr) |
419 | =item bool ecb_is_constant (expr) |
| 254 | |
420 | |
| 255 | Returns true iff the expression can be deduced to be a compile-time |
421 | Returns true iff the expression can be deduced to be a compile-time |
| 256 | constant, and false otherwise. |
422 | constant, and false otherwise. |
| 257 | |
423 | |
| 258 | For example, when you have a C<rndm16> function that returns a 16 bit |
424 | For example, when you have a C<rndm16> function that returns a 16 bit |
| … | |
… | |
| 276 | return is_constant (n) && !(n & (n - 1)) |
442 | return is_constant (n) && !(n & (n - 1)) |
| 277 | ? rndm16 () & (num - 1) |
443 | ? rndm16 () & (num - 1) |
| 278 | : (n * (uint32_t)rndm16 ()) >> 16; |
444 | : (n * (uint32_t)rndm16 ()) >> 16; |
| 279 | } |
445 | } |
| 280 | |
446 | |
| 281 | =item bool ecb_expect (expr, value) |
447 | =item ecb_expect (expr, value) |
| 282 | |
448 | |
| 283 | Evaluates C<expr> and returns it. In addition, it tells the compiler that |
449 | Evaluates C<expr> and returns it. In addition, it tells the compiler that |
| 284 | the C<expr> evaluates to C<value> a lot, which can be used for static |
450 | the C<expr> evaluates to C<value> a lot, which can be used for static |
| 285 | branch optimisations. |
451 | branch optimisations. |
| 286 | |
452 | |
| … | |
… | |
| 333 | { |
499 | { |
| 334 | if (ecb_expect_false (current + size > end)) |
500 | if (ecb_expect_false (current + size > end)) |
| 335 | real_reserve_method (size); /* presumably noinline */ |
501 | real_reserve_method (size); /* presumably noinline */ |
| 336 | } |
502 | } |
| 337 | |
503 | |
| 338 | =item bool ecb_assume (cond) |
504 | =item ecb_assume (cond) |
| 339 | |
505 | |
| 340 | Try to tell the compiler that some condition is true, even if it's not |
506 | Tries to tell the compiler that some condition is true, even if it's not |
| 341 | obvious. |
507 | obvious. This is not a function, but a statement: it cannot be used in |
|
|
508 | another expression. |
| 342 | |
509 | |
| 343 | This can be used to teach the compiler about invariants or other |
510 | This can be used to teach the compiler about invariants or other |
| 344 | conditions that might improve code generation, but which are impossible to |
511 | conditions that might improve code generation, but which are impossible to |
| 345 | deduce form the code itself. |
512 | deduce form the code itself. |
| 346 | |
513 | |
| … | |
… | |
| 363 | |
530 | |
| 364 | Then the compiler I<might> be able to optimise out the second call |
531 | Then the compiler I<might> be able to optimise out the second call |
| 365 | completely, as it knows that C<< current + 1 > end >> is false and the |
532 | completely, as it knows that C<< current + 1 > end >> is false and the |
| 366 | call will never be executed. |
533 | call will never be executed. |
| 367 | |
534 | |
| 368 | =item bool ecb_unreachable () |
535 | =item ecb_unreachable () |
| 369 | |
536 | |
| 370 | This function does nothing itself, except tell the compiler that it will |
537 | This function does nothing itself, except tell the compiler that it will |
| 371 | never be executed. Apart from suppressing a warning in some cases, this |
538 | never be executed. Apart from suppressing a warning in some cases, this |
| 372 | function can be used to implement C<ecb_assume> or similar functions. |
539 | function can be used to implement C<ecb_assume> or similar functionality. |
| 373 | |
540 | |
| 374 | =item bool ecb_prefetch (addr, rw, locality) |
541 | =item ecb_prefetch (addr, rw, locality) |
| 375 | |
542 | |
| 376 | Tells the compiler to try to prefetch memory at the given C<addr>ess |
543 | Tells the compiler to try to prefetch memory at the given C<addr>ess |
| 377 | for either reading (C<rw> = 0) or writing (C<rw> = 1). A C<locality> of |
544 | for either reading (C<rw> = 0) or writing (C<rw> = 1). A C<locality> of |
| 378 | C<0> means that there will only be one access later, C<3> means that |
545 | C<0> means that there will only be one access later, C<3> means that |
| 379 | the data will likely be accessed very often, and values in between mean |
546 | the data will likely be accessed very often, and values in between mean |
| 380 | something... in between. The memory pointed to by the address does not |
547 | something... in between. The memory pointed to by the address does not |
| 381 | need to be accessible (it could be a null pointer for example), but C<rw> |
548 | need to be accessible (it could be a null pointer for example), but C<rw> |
| 382 | and C<locality> must be compile-time constants. |
549 | and C<locality> must be compile-time constants. |
| 383 | |
550 | |
|
|
551 | This is a statement, not a function: you cannot use it as part of an |
|
|
552 | expression. |
|
|
553 | |
| 384 | An obvious way to use this is to prefetch some data far away, in a big |
554 | An obvious way to use this is to prefetch some data far away, in a big |
| 385 | array you loop over. This prefetches memory some 128 array elements later, |
555 | array you loop over. This prefetches memory some 128 array elements later, |
| 386 | in the hope that it will be ready when the CPU arrives at that location. |
556 | in the hope that it will be ready when the CPU arrives at that location. |
| 387 | |
557 | |
| 388 | int sum = 0; |
558 | int sum = 0; |
| … | |
… | |
| 425 | |
595 | |
| 426 | =item int ecb_ctz32 (uint32_t x) |
596 | =item int ecb_ctz32 (uint32_t x) |
| 427 | |
597 | |
| 428 | =item int ecb_ctz64 (uint64_t x) |
598 | =item int ecb_ctz64 (uint64_t x) |
| 429 | |
599 | |
|
|
600 | =item int ecb_ctz (T x) [C++] |
|
|
601 | |
| 430 | Returns the index of the least significant bit set in C<x> (or |
602 | Returns the index of the least significant bit set in C<x> (or |
| 431 | equivalently the number of bits set to 0 before the least significant bit |
603 | equivalently the number of bits set to 0 before the least significant bit |
| 432 | set), starting from 0. If C<x> is 0 the result is undefined. |
604 | set), starting from 0. If C<x> is 0 the result is undefined. |
| 433 | |
605 | |
| 434 | For smaller types than C<uint32_t> you can safely use C<ecb_ctz32>. |
606 | For smaller types than C<uint32_t> you can safely use C<ecb_ctz32>. |
| 435 | |
607 | |
|
|
608 | The overloaded C++ C<ecb_ctz> function supports C<uint8_t>, C<uint16_t>, |
|
|
609 | C<uint32_t> and C<uint64_t> types. |
|
|
610 | |
| 436 | For example: |
611 | For example: |
| 437 | |
612 | |
| 438 | ecb_ctz32 (3) = 0 |
613 | ecb_ctz32 (3) = 0 |
| 439 | ecb_ctz32 (6) = 1 |
614 | ecb_ctz32 (6) = 1 |
| 440 | |
615 | |
| 441 | =item bool ecb_is_pot32 (uint32_t x) |
616 | =item bool ecb_is_pot32 (uint32_t x) |
| 442 | |
617 | |
| 443 | =item bool ecb_is_pot64 (uint32_t x) |
618 | =item bool ecb_is_pot64 (uint32_t x) |
| 444 | |
619 | |
|
|
620 | =item bool ecb_is_pot (T x) [C++] |
|
|
621 | |
| 445 | Return true iff C<x> is a power of two or C<x == 0>. |
622 | Returns true iff C<x> is a power of two or C<x == 0>. |
| 446 | |
623 | |
| 447 | For smaller types then C<uint32_t> you can safely use C<ecb_is_pot32>. |
624 | For smaller types than C<uint32_t> you can safely use C<ecb_is_pot32>. |
|
|
625 | |
|
|
626 | The overloaded C++ C<ecb_is_pot> function supports C<uint8_t>, C<uint16_t>, |
|
|
627 | C<uint32_t> and C<uint64_t> types. |
| 448 | |
628 | |
| 449 | =item int ecb_ld32 (uint32_t x) |
629 | =item int ecb_ld32 (uint32_t x) |
| 450 | |
630 | |
| 451 | =item int ecb_ld64 (uint64_t x) |
631 | =item int ecb_ld64 (uint64_t x) |
|
|
632 | |
|
|
633 | =item int ecb_ld64 (T x) [C++] |
| 452 | |
634 | |
| 453 | Returns the index of the most significant bit set in C<x>, or the number |
635 | Returns the index of the most significant bit set in C<x>, or the number |
| 454 | of digits the number requires in binary (so that C<< 2**ld <= x < |
636 | of digits the number requires in binary (so that C<< 2**ld <= x < |
| 455 | 2**(ld+1) >>). If C<x> is 0 the result is undefined. A common use case is |
637 | 2**(ld+1) >>). If C<x> is 0 the result is undefined. A common use case is |
| 456 | to compute the integer binary logarithm, i.e. C<floor (log2 (n))>, for |
638 | to compute the integer binary logarithm, i.e. C<floor (log2 (n))>, for |
| … | |
… | |
| 461 | the given data type), while C<ecb_ld> returns how many bits the number |
643 | the given data type), while C<ecb_ld> returns how many bits the number |
| 462 | itself requires. |
644 | itself requires. |
| 463 | |
645 | |
| 464 | For smaller types than C<uint32_t> you can safely use C<ecb_ld32>. |
646 | For smaller types than C<uint32_t> you can safely use C<ecb_ld32>. |
| 465 | |
647 | |
|
|
648 | The overloaded C++ C<ecb_ld> function supports C<uint8_t>, C<uint16_t>, |
|
|
649 | C<uint32_t> and C<uint64_t> types. |
|
|
650 | |
| 466 | =item int ecb_popcount32 (uint32_t x) |
651 | =item int ecb_popcount32 (uint32_t x) |
| 467 | |
652 | |
| 468 | =item int ecb_popcount64 (uint64_t x) |
653 | =item int ecb_popcount64 (uint64_t x) |
| 469 | |
654 | |
|
|
655 | =item int ecb_popcount (T x) [C++] |
|
|
656 | |
| 470 | Returns the number of bits set to 1 in C<x>. |
657 | Returns the number of bits set to 1 in C<x>. |
| 471 | |
658 | |
| 472 | For smaller types than C<uint32_t> you can safely use C<ecb_popcount32>. |
659 | For smaller types than C<uint32_t> you can safely use C<ecb_popcount32>. |
|
|
660 | |
|
|
661 | The overloaded C++ C<ecb_popcount> function supports C<uint8_t>, C<uint16_t>, |
|
|
662 | C<uint32_t> and C<uint64_t> types. |
| 473 | |
663 | |
| 474 | For example: |
664 | For example: |
| 475 | |
665 | |
| 476 | ecb_popcount32 (7) = 3 |
666 | ecb_popcount32 (7) = 3 |
| 477 | ecb_popcount32 (255) = 8 |
667 | ecb_popcount32 (255) = 8 |
| … | |
… | |
| 480 | |
670 | |
| 481 | =item uint16_t ecb_bitrev16 (uint16_t x) |
671 | =item uint16_t ecb_bitrev16 (uint16_t x) |
| 482 | |
672 | |
| 483 | =item uint32_t ecb_bitrev32 (uint32_t x) |
673 | =item uint32_t ecb_bitrev32 (uint32_t x) |
| 484 | |
674 | |
|
|
675 | =item T ecb_bitrev (T x) [C++] |
|
|
676 | |
| 485 | Reverses the bits in x, i.e. the MSB becomes the LSB, MSB-1 becomes LSB+1 |
677 | Reverses the bits in x, i.e. the MSB becomes the LSB, MSB-1 becomes LSB+1 |
| 486 | and so on. |
678 | and so on. |
| 487 | |
679 | |
|
|
680 | The overloaded C++ C<ecb_bitrev> function supports C<uint8_t>, C<uint16_t> and C<uint32_t> types. |
|
|
681 | |
| 488 | Example: |
682 | Example: |
| 489 | |
683 | |
| 490 | ecb_bitrev8 (0xa7) = 0xea |
684 | ecb_bitrev8 (0xa7) = 0xea |
| 491 | ecb_bitrev32 (0xffcc4411) = 0x882233ff |
685 | ecb_bitrev32 (0xffcc4411) = 0x882233ff |
|
|
686 | |
|
|
687 | =item T ecb_bitrev (T x) [C++] |
|
|
688 | |
|
|
689 | Overloaded C++ bitrev function. |
|
|
690 | |
|
|
691 | C<T> must be one of C<uint8_t>, C<uint16_t> or C<uint32_t>. |
| 492 | |
692 | |
| 493 | =item uint32_t ecb_bswap16 (uint32_t x) |
693 | =item uint32_t ecb_bswap16 (uint32_t x) |
| 494 | |
694 | |
| 495 | =item uint32_t ecb_bswap32 (uint32_t x) |
695 | =item uint32_t ecb_bswap32 (uint32_t x) |
| 496 | |
696 | |
| … | |
… | |
| 498 | |
698 | |
| 499 | These functions return the value of the 16-bit (32-bit, 64-bit) value |
699 | These functions return the value of the 16-bit (32-bit, 64-bit) value |
| 500 | C<x> after reversing the order of bytes (0x11223344 becomes 0x44332211 in |
700 | C<x> after reversing the order of bytes (0x11223344 becomes 0x44332211 in |
| 501 | C<ecb_bswap32>). |
701 | C<ecb_bswap32>). |
| 502 | |
702 | |
|
|
703 | The overloaded C++ C<ecb_bswap> function supports C<uint8_t>, C<uint16_t>, |
|
|
704 | C<uint32_t> and C<uint64_t> types. |
|
|
705 | |
| 503 | =item uint8_t ecb_rotl8 (uint8_t x, unsigned int count) |
706 | =item uint8_t ecb_rotl8 (uint8_t x, unsigned int count) |
| 504 | |
707 | |
| 505 | =item uint16_t ecb_rotl16 (uint16_t x, unsigned int count) |
708 | =item uint16_t ecb_rotl16 (uint16_t x, unsigned int count) |
| 506 | |
709 | |
| 507 | =item uint32_t ecb_rotl32 (uint32_t x, unsigned int count) |
710 | =item uint32_t ecb_rotl32 (uint32_t x, unsigned int count) |
| … | |
… | |
| 521 | (C<ecb_rotl>). |
724 | (C<ecb_rotl>). |
| 522 | |
725 | |
| 523 | Current GCC versions understand these functions and usually compile them |
726 | Current GCC versions understand these functions and usually compile them |
| 524 | to "optimal" code (e.g. a single C<rol> or a combination of C<shld> on |
727 | to "optimal" code (e.g. a single C<rol> or a combination of C<shld> on |
| 525 | x86). |
728 | x86). |
|
|
729 | |
|
|
730 | =item T ecb_rotl (T x, unsigned int count) [C++] |
|
|
731 | |
|
|
732 | =item T ecb_rotr (T x, unsigned int count) [C++] |
|
|
733 | |
|
|
734 | Overloaded C++ rotl/rotr functions. |
|
|
735 | |
|
|
736 | C<T> must be one of C<uint8_t>, C<uint16_t>, C<uint32_t> or C<uint64_t>. |
|
|
737 | |
|
|
738 | =back |
|
|
739 | |
|
|
740 | =head2 HOST ENDIANNESS CONVERSION |
|
|
741 | |
|
|
742 | =over 4 |
|
|
743 | |
|
|
744 | =item uint_fast16_t ecb_be_u16_to_host (uint_fast16_t v) |
|
|
745 | |
|
|
746 | =item uint_fast32_t ecb_be_u32_to_host (uint_fast32_t v) |
|
|
747 | |
|
|
748 | =item uint_fast64_t ecb_be_u64_to_host (uint_fast64_t v) |
|
|
749 | |
|
|
750 | =item uint_fast16_t ecb_le_u16_to_host (uint_fast16_t v) |
|
|
751 | |
|
|
752 | =item uint_fast32_t ecb_le_u32_to_host (uint_fast32_t v) |
|
|
753 | |
|
|
754 | =item uint_fast64_t ecb_le_u64_to_host (uint_fast64_t v) |
|
|
755 | |
|
|
756 | Convert an unsigned 16, 32 or 64 bit value from big or little endian to host byte order. |
|
|
757 | |
|
|
758 | The naming convention is C<ecb_>(C<be>|C<le>)C<_u>C<16|32|64>C<_to_host>, |
|
|
759 | where be and le stand for big endian and little endian, respectively. |
|
|
760 | |
|
|
761 | =item uint_fast16_t ecb_host_to_be_u16 (uint_fast16_t v) |
|
|
762 | |
|
|
763 | =item uint_fast32_t ecb_host_to_be_u32 (uint_fast32_t v) |
|
|
764 | |
|
|
765 | =item uint_fast64_t ecb_host_to_be_u64 (uint_fast64_t v) |
|
|
766 | |
|
|
767 | =item uint_fast16_t ecb_host_to_le_u16 (uint_fast16_t v) |
|
|
768 | |
|
|
769 | =item uint_fast32_t ecb_host_to_le_u32 (uint_fast32_t v) |
|
|
770 | |
|
|
771 | =item uint_fast64_t ecb_host_to_le_u64 (uint_fast64_t v) |
|
|
772 | |
|
|
773 | Like above, but converts I<from> host byte order to the specified |
|
|
774 | endianness. |
|
|
775 | |
|
|
776 | =back |
|
|
777 | |
|
|
778 | In C++ the following additional template functions are supported: |
|
|
779 | |
|
|
780 | =over 4 |
|
|
781 | |
|
|
782 | =item T ecb_be_to_host (T v) |
|
|
783 | |
|
|
784 | =item T ecb_le_to_host (T v) |
|
|
785 | |
|
|
786 | =item T ecb_host_to_be (T v) |
|
|
787 | |
|
|
788 | =item T ecb_host_to_le (T v) |
|
|
789 | |
|
|
790 | These functions work like their C counterparts, above, but use templates, |
|
|
791 | which make them useful in generic code. |
|
|
792 | |
|
|
793 | C<T> must be one of C<uint8_t>, C<uint16_t>, C<uint32_t> or C<uint64_t> |
|
|
794 | (so unlike their C counterparts, there is a version for C<uint8_t>, which |
|
|
795 | again can be useful in generic code). |
|
|
796 | |
|
|
797 | =head2 UNALIGNED LOAD/STORE |
|
|
798 | |
|
|
799 | These function load or store unaligned multi-byte values. |
|
|
800 | |
|
|
801 | =over 4 |
|
|
802 | |
|
|
803 | =item uint_fast16_t ecb_peek_u16_u (const void *ptr) |
|
|
804 | |
|
|
805 | =item uint_fast32_t ecb_peek_u32_u (const void *ptr) |
|
|
806 | |
|
|
807 | =item uint_fast64_t ecb_peek_u64_u (const void *ptr) |
|
|
808 | |
|
|
809 | These functions load an unaligned, unsigned 16, 32 or 64 bit value from |
|
|
810 | memory. |
|
|
811 | |
|
|
812 | =item uint_fast16_t ecb_peek_be_u16_u (const void *ptr) |
|
|
813 | |
|
|
814 | =item uint_fast32_t ecb_peek_be_u32_u (const void *ptr) |
|
|
815 | |
|
|
816 | =item uint_fast64_t ecb_peek_be_u64_u (const void *ptr) |
|
|
817 | |
|
|
818 | =item uint_fast16_t ecb_peek_le_u16_u (const void *ptr) |
|
|
819 | |
|
|
820 | =item uint_fast32_t ecb_peek_le_u32_u (const void *ptr) |
|
|
821 | |
|
|
822 | =item uint_fast64_t ecb_peek_le_u64_u (const void *ptr) |
|
|
823 | |
|
|
824 | Like above, but additionally convert from big endian (C<be>) or little |
|
|
825 | endian (C<le>) byte order to host byte order while doing so. |
|
|
826 | |
|
|
827 | =item ecb_poke_u16_u (void *ptr, uint16_t v) |
|
|
828 | |
|
|
829 | =item ecb_poke_u32_u (void *ptr, uint32_t v) |
|
|
830 | |
|
|
831 | =item ecb_poke_u64_u (void *ptr, uint64_t v) |
|
|
832 | |
|
|
833 | These functions store an unaligned, unsigned 16, 32 or 64 bit value to |
|
|
834 | memory. |
|
|
835 | |
|
|
836 | =item ecb_poke_be_u16_u (void *ptr, uint_fast16_t v) |
|
|
837 | |
|
|
838 | =item ecb_poke_be_u32_u (void *ptr, uint_fast32_t v) |
|
|
839 | |
|
|
840 | =item ecb_poke_be_u64_u (void *ptr, uint_fast64_t v) |
|
|
841 | |
|
|
842 | =item ecb_poke_le_u16_u (void *ptr, uint_fast16_t v) |
|
|
843 | |
|
|
844 | =item ecb_poke_le_u32_u (void *ptr, uint_fast32_t v) |
|
|
845 | |
|
|
846 | =item ecb_poke_le_u64_u (void *ptr, uint_fast64_t v) |
|
|
847 | |
|
|
848 | Like above, but additionally convert from host byte order to big endian |
|
|
849 | (C<be>) or little endian (C<le>) byte order while doing so. |
|
|
850 | |
|
|
851 | =back |
|
|
852 | |
|
|
853 | In C++ the following additional template functions are supported: |
|
|
854 | |
|
|
855 | =over 4 |
|
|
856 | |
|
|
857 | =item T ecb_peek (const void *ptr) |
|
|
858 | |
|
|
859 | =item T ecb_peek_be (const void *ptr) |
|
|
860 | |
|
|
861 | =item T ecb_peek_le (const void *ptr) |
|
|
862 | |
|
|
863 | =item T ecb_peek_u (const void *ptr) |
|
|
864 | |
|
|
865 | =item T ecb_peek_be_u (const void *ptr) |
|
|
866 | |
|
|
867 | =item T ecb_peek_le_u (const void *ptr) |
|
|
868 | |
|
|
869 | Similarly to their C counterparts, these functions load an unsigned 8, 16, |
|
|
870 | 32 or 64 bit value from memory, with optional conversion from big/little |
|
|
871 | endian. |
|
|
872 | |
|
|
873 | Since the type cannot be deduced, it has top be specified explicitly, e.g. |
|
|
874 | |
|
|
875 | uint_fast16_t v = ecb_peek<uint16_t> (ptr); |
|
|
876 | |
|
|
877 | C<T> must be one of C<uint8_t>, C<uint16_t>, C<uint32_t> or C<uint64_t>. |
|
|
878 | |
|
|
879 | Unlike their C counterparts, these functions support 8 bit quantities |
|
|
880 | (C<uint8_t>) and also have an aligned version (without the C<_u> prefix), |
|
|
881 | all of which hopefully makes them more useful in generic code. |
|
|
882 | |
|
|
883 | =item ecb_poke (void *ptr, T v) |
|
|
884 | |
|
|
885 | =item ecb_poke_be (void *ptr, T v) |
|
|
886 | |
|
|
887 | =item ecb_poke_le (void *ptr, T v) |
|
|
888 | |
|
|
889 | =item ecb_poke_u (void *ptr, T v) |
|
|
890 | |
|
|
891 | =item ecb_poke_be_u (void *ptr, T v) |
|
|
892 | |
|
|
893 | =item ecb_poke_le_u (void *ptr, T v) |
|
|
894 | |
|
|
895 | Again, similarly to their C counterparts, these functions store an |
|
|
896 | unsigned 8, 16, 32 or z64 bit value to memory, with optional conversion to |
|
|
897 | big/little endian. |
|
|
898 | |
|
|
899 | C<T> must be one of C<uint8_t>, C<uint16_t>, C<uint32_t> or C<uint64_t>. |
|
|
900 | |
|
|
901 | Unlike their C counterparts, these functions support 8 bit quantities |
|
|
902 | (C<uint8_t>) and also have an aligned version (without the C<_u> prefix), |
|
|
903 | all of which hopefully makes them more useful in generic code. |
|
|
904 | |
|
|
905 | =back |
|
|
906 | |
|
|
907 | =head2 FLOATING POINT FIDDLING |
|
|
908 | |
|
|
909 | =over 4 |
|
|
910 | |
|
|
911 | =item ECB_INFINITY [-UECB_NO_LIBM] |
|
|
912 | |
|
|
913 | Evaluates to positive infinity if supported by the platform, otherwise to |
|
|
914 | a truly huge number. |
|
|
915 | |
|
|
916 | =item ECB_NAN [-UECB_NO_LIBM] |
|
|
917 | |
|
|
918 | Evaluates to a quiet NAN if supported by the platform, otherwise to |
|
|
919 | C<ECB_INFINITY>. |
|
|
920 | |
|
|
921 | =item float ecb_ldexpf (float x, int exp) [-UECB_NO_LIBM] |
|
|
922 | |
|
|
923 | Same as C<ldexpf>, but always available. |
|
|
924 | |
|
|
925 | =item uint32_t ecb_float_to_binary16 (float x) [-UECB_NO_LIBM] |
|
|
926 | |
|
|
927 | =item uint32_t ecb_float_to_binary32 (float x) [-UECB_NO_LIBM] |
|
|
928 | |
|
|
929 | =item uint64_t ecb_double_to_binary64 (double x) [-UECB_NO_LIBM] |
|
|
930 | |
|
|
931 | These functions each take an argument in the native C<float> or C<double> |
|
|
932 | type and return the IEEE 754 bit representation of it (binary16/half, |
|
|
933 | binary32/single or binary64/double precision). |
|
|
934 | |
|
|
935 | The bit representation is just as IEEE 754 defines it, i.e. the sign bit |
|
|
936 | will be the most significant bit, followed by exponent and mantissa. |
|
|
937 | |
|
|
938 | This function should work even when the native floating point format isn't |
|
|
939 | IEEE compliant, of course at a speed and code size penalty, and of course |
|
|
940 | also within reasonable limits (it tries to convert NaNs, infinities and |
|
|
941 | denormals, but will likely convert negative zero to positive zero). |
|
|
942 | |
|
|
943 | On all modern platforms (where C<ECB_STDFP> is true), the compiler should |
|
|
944 | be able to optimise away this function completely. |
|
|
945 | |
|
|
946 | These functions can be helpful when serialising floats to the network - you |
|
|
947 | can serialise the return value like a normal uint16_t/uint32_t/uint64_t. |
|
|
948 | |
|
|
949 | Another use for these functions is to manipulate floating point values |
|
|
950 | directly. |
|
|
951 | |
|
|
952 | Silly example: toggle the sign bit of a float. |
|
|
953 | |
|
|
954 | /* On gcc-4.7 on amd64, */ |
|
|
955 | /* this results in a single add instruction to toggle the bit, and 4 extra */ |
|
|
956 | /* instructions to move the float value to an integer register and back. */ |
|
|
957 | |
|
|
958 | x = ecb_binary32_to_float (ecb_float_to_binary32 (x) ^ 0x80000000U) |
|
|
959 | |
|
|
960 | =item float ecb_binary16_to_float (uint16_t x) [-UECB_NO_LIBM] |
|
|
961 | |
|
|
962 | =item float ecb_binary32_to_float (uint32_t x) [-UECB_NO_LIBM] |
|
|
963 | |
|
|
964 | =item double ecb_binary64_to_double (uint64_t x) [-UECB_NO_LIBM] |
|
|
965 | |
|
|
966 | The reverse operation of the previous function - takes the bit |
|
|
967 | representation of an IEEE binary16, binary32 or binary64 number (half, |
|
|
968 | single or double precision) and converts it to the native C<float> or |
|
|
969 | C<double> format. |
|
|
970 | |
|
|
971 | This function should work even when the native floating point format isn't |
|
|
972 | IEEE compliant, of course at a speed and code size penalty, and of course |
|
|
973 | also within reasonable limits (it tries to convert normals and denormals, |
|
|
974 | and might be lucky for infinities, and with extraordinary luck, also for |
|
|
975 | negative zero). |
|
|
976 | |
|
|
977 | On all modern platforms (where C<ECB_STDFP> is true), the compiler should |
|
|
978 | be able to optimise away this function completely. |
|
|
979 | |
|
|
980 | =item uint16_t ecb_binary32_to_binary16 (uint32_t x) |
|
|
981 | |
|
|
982 | =item uint32_t ecb_binary16_to_binary32 (uint16_t x) |
|
|
983 | |
|
|
984 | Convert a IEEE binary32/single precision to binary16/half format, and vice |
|
|
985 | versa, handling all details (round-to-nearest-even, subnormals, infinity |
|
|
986 | and NaNs) correctly. |
|
|
987 | |
|
|
988 | These are functions are available under C<-DECB_NO_LIBM>, since |
|
|
989 | they do not rely on the platform floating point format. The |
|
|
990 | C<ecb_float_to_binary16> and C<ecb_binary16_to_float> functions are |
|
|
991 | usually what you want. |
| 526 | |
992 | |
| 527 | =back |
993 | =back |
| 528 | |
994 | |
| 529 | =head2 ARITHMETIC |
995 | =head2 ARITHMETIC |
| 530 | |
996 | |
| … | |
… | |
| 581 | for (i = 0; i < ecb_array_length (primes); i++) |
1047 | for (i = 0; i < ecb_array_length (primes); i++) |
| 582 | sum += primes [i]; |
1048 | sum += primes [i]; |
| 583 | |
1049 | |
| 584 | =back |
1050 | =back |
| 585 | |
1051 | |
|
|
1052 | =head2 SYMBOLS GOVERNING COMPILATION OF ECB.H ITSELF |
| 586 | |
1053 | |
|
|
1054 | These symbols need to be defined before including F<ecb.h> the first time. |
|
|
1055 | |
|
|
1056 | =over 4 |
|
|
1057 | |
|
|
1058 | =item ECB_NO_THREADS |
|
|
1059 | |
|
|
1060 | If F<ecb.h> is never used from multiple threads, then this symbol can |
|
|
1061 | be defined, in which case memory fences (and similar constructs) are |
|
|
1062 | completely removed, leading to more efficient code and fewer dependencies. |
|
|
1063 | |
|
|
1064 | Setting this symbol to a true value implies C<ECB_NO_SMP>. |
|
|
1065 | |
|
|
1066 | =item ECB_NO_SMP |
|
|
1067 | |
|
|
1068 | The weaker version of C<ECB_NO_THREADS> - if F<ecb.h> is used from |
|
|
1069 | multiple threads, but never concurrently (e.g. if the system the program |
|
|
1070 | runs on has only a single CPU with a single core, no hyperthreading and so |
|
|
1071 | on), then this symbol can be defined, leading to more efficient code and |
|
|
1072 | fewer dependencies. |
|
|
1073 | |
|
|
1074 | =item ECB_NO_LIBM |
|
|
1075 | |
|
|
1076 | When defined to C<1>, do not export any functions that might introduce |
|
|
1077 | dependencies on the math library (usually called F<-lm>) - these are |
|
|
1078 | marked with [-UECB_NO_LIBM]. |
|
|
1079 | |
|
|
1080 | =back |
|
|
1081 | |
|
|
1082 | =head1 UNDOCUMENTED FUNCTIONALITY |
|
|
1083 | |
|
|
1084 | F<ecb.h> is full of undocumented functionality as well, some of which is |
|
|
1085 | intended to be internal-use only, some of which we forgot to document, and |
|
|
1086 | some of which we hide because we are not sure we will keep the interface |
|
|
1087 | stable. |
|
|
1088 | |
|
|
1089 | While you are welcome to rummage around and use whatever you find useful |
|
|
1090 | (we can't stop you), keep in mind that we will change undocumented |
|
|
1091 | functionality in incompatible ways without thinking twice, while we are |
|
|
1092 | considerably more conservative with documented things. |
|
|
1093 | |
|
|
1094 | =head1 AUTHORS |
|
|
1095 | |
|
|
1096 | C<libecb> is designed and maintained by: |
|
|
1097 | |
|
|
1098 | Emanuele Giaquinta <e.giaquinta@glauco.it> |
|
|
1099 | Marc Alexander Lehmann <schmorp@schmorp.de> |
|
|
1100 | |
|
|
1101 | |
