1 | #ifndef UTIL_H__ |
1 | #ifndef UTIL_H__ |
2 | #define UTIL_H__ |
2 | #define UTIL_H__ |
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3 | |
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4 | //#define PREFER_MALLOC |
3 | |
5 | |
4 | #if __GNUC__ >= 3 |
6 | #if __GNUC__ >= 3 |
5 | # define is_constant(c) __builtin_constant_p (c) |
7 | # define is_constant(c) __builtin_constant_p (c) |
6 | #else |
8 | #else |
7 | # define is_constant(c) 0 |
9 | # define is_constant(c) 0 |
8 | #endif |
10 | #endif |
9 | |
11 | |
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12 | #include <cstddef> |
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13 | #include <cmath> |
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14 | #include <new> |
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15 | #include <vector> |
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16 | |
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17 | #include <glib.h> |
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18 | |
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19 | #include <shstr.h> |
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20 | #include <traits.h> |
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21 | |
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22 | // use a gcc extension for auto declarations until ISO C++ sanctifies them |
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23 | #define AUTODECL(var,expr) typeof(expr) var = (expr) |
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24 | |
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25 | // very ugly macro that basicaly declares and initialises a variable |
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26 | // that is in scope for the next statement only |
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27 | // works only for stuff that can be assigned 0 and converts to false |
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28 | // (note: works great for pointers) |
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29 | // most ugly macro I ever wrote |
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30 | #define declvar(type, name, value) if (type name = 0) { } else if (((name) = (value)), 1) |
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31 | |
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32 | // in range including end |
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33 | #define IN_RANGE_INC(val,beg,end) \ |
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34 | ((unsigned int)(val) - (unsigned int)(beg) <= (unsigned int)(end) - (unsigned int)(beg)) |
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35 | |
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36 | // in range excluding end |
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37 | #define IN_RANGE_EXC(val,beg,end) \ |
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38 | ((unsigned int)(val) - (unsigned int)(beg) < (unsigned int)(end) - (unsigned int)(beg)) |
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39 | |
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40 | void fork_abort (const char *msg); |
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41 | |
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42 | // rationale for using (U) not (T) is to reduce signed/unsigned issues, |
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43 | // as a is often a constant while b is the variable. it is still a bug, though. |
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44 | template<typename T, typename U> static inline T min (T a, U b) { return (U)a < b ? (U)a : b; } |
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45 | template<typename T, typename U> static inline T max (T a, U b) { return (U)a > b ? (U)a : b; } |
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46 | template<typename T, typename U, typename V> static inline T clamp (T v, U a, V b) { return v < (T)a ? (T)a : v >(T)b ? (T)b : v; } |
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47 | |
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48 | template<typename T, typename U> static inline void swap (T& a, U& b) { T t=a; a=(T)b; b=(U)t; } |
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49 | |
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50 | // this is much faster than crossfires original algorithm |
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51 | // on modern cpus |
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52 | inline int |
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53 | isqrt (int n) |
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54 | { |
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55 | return (int)sqrtf ((float)n); |
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56 | } |
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57 | |
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58 | // this is only twice as fast as naive sqrtf (dx*dy+dy*dy) |
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59 | #if 0 |
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60 | // and has a max. error of 6 in the range -100..+100. |
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61 | #else |
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62 | // and has a max. error of 9 in the range -100..+100. |
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63 | #endif |
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64 | inline int |
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65 | idistance (int dx, int dy) |
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66 | { |
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67 | unsigned int dx_ = abs (dx); |
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68 | unsigned int dy_ = abs (dy); |
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69 | |
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70 | #if 0 |
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71 | return dx_ > dy_ |
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72 | ? (dx_ * 61685 + dy_ * 26870) >> 16 |
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73 | : (dy_ * 61685 + dx_ * 26870) >> 16; |
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74 | #else |
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75 | return dx_ + dy_ - min (dx_, dy_) * 5 / 8; |
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76 | #endif |
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77 | } |
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78 | |
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79 | /* |
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80 | * absdir(int): Returns a number between 1 and 8, which represent |
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81 | * the "absolute" direction of a number (it actually takes care of |
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82 | * "overflow" in previous calculations of a direction). |
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83 | */ |
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84 | inline int |
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85 | absdir (int d) |
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86 | { |
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87 | return ((d - 1) & 7) + 1; |
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88 | } |
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89 | |
10 | // makes dynamically allocated objects zero-initialised |
90 | // makes dynamically allocated objects zero-initialised |
11 | struct zero_initialised |
91 | struct zero_initialised |
12 | { |
92 | { |
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93 | void *operator new (size_t s, void *p) |
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94 | { |
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95 | memset (p, 0, s); |
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96 | return p; |
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97 | } |
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98 | |
13 | void *operator new (size_t s); |
99 | void *operator new (size_t s) |
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100 | { |
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101 | return g_slice_alloc0 (s); |
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102 | } |
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103 | |
14 | void *operator new [] (size_t s); |
104 | void *operator new[] (size_t s) |
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105 | { |
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106 | return g_slice_alloc0 (s); |
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107 | } |
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108 | |
15 | void operator delete (void *p, size_t s); |
109 | void operator delete (void *p, size_t s) |
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110 | { |
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111 | g_slice_free1 (s, p); |
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112 | } |
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113 | |
16 | void operator delete [] (void *p, size_t s); |
114 | void operator delete[] (void *p, size_t s) |
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115 | { |
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116 | g_slice_free1 (s, p); |
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117 | } |
17 | }; |
118 | }; |
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119 | |
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120 | void *salloc_ (int n) throw (std::bad_alloc); |
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121 | void *salloc_ (int n, void *src) throw (std::bad_alloc); |
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122 | |
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123 | // strictly the same as g_slice_alloc, but never returns 0 |
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124 | template<typename T> |
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125 | inline T *salloc (int n = 1) throw (std::bad_alloc) { return (T *)salloc_ (n * sizeof (T)); } |
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126 | |
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127 | // also copies src into the new area, like "memdup" |
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128 | // if src is 0, clears the memory |
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129 | template<typename T> |
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130 | inline T *salloc (int n, T *src) throw (std::bad_alloc) { return (T *)salloc_ (n * sizeof (T), (void *)src); } |
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131 | |
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132 | // clears the memory |
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133 | template<typename T> |
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134 | inline T *salloc0(int n = 1) throw (std::bad_alloc) { return (T *)salloc_ (n * sizeof (T), 0); } |
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135 | |
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136 | // for symmetry |
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137 | template<typename T> |
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138 | inline void sfree (T *ptr, int n = 1) throw () |
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139 | { |
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140 | #ifdef PREFER_MALLOC |
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141 | free (ptr); |
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142 | #else |
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143 | g_slice_free1 (n * sizeof (T), (void *)ptr); |
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144 | #endif |
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145 | } |
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146 | |
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147 | // a STL-compatible allocator that uses g_slice |
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148 | // boy, this is verbose |
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149 | template<typename Tp> |
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150 | struct slice_allocator |
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151 | { |
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152 | typedef size_t size_type; |
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153 | typedef ptrdiff_t difference_type; |
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154 | typedef Tp *pointer; |
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155 | typedef const Tp *const_pointer; |
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156 | typedef Tp &reference; |
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157 | typedef const Tp &const_reference; |
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158 | typedef Tp value_type; |
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159 | |
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160 | template <class U> |
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161 | struct rebind |
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162 | { |
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163 | typedef slice_allocator<U> other; |
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164 | }; |
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165 | |
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166 | slice_allocator () throw () { } |
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167 | slice_allocator (const slice_allocator &o) throw () { } |
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168 | template<typename Tp2> |
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169 | slice_allocator (const slice_allocator<Tp2> &) throw () { } |
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170 | |
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171 | ~slice_allocator () { } |
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172 | |
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173 | pointer address (reference x) const { return &x; } |
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174 | const_pointer address (const_reference x) const { return &x; } |
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175 | |
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176 | pointer allocate (size_type n, const_pointer = 0) |
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177 | { |
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178 | return salloc<Tp> (n); |
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179 | } |
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180 | |
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181 | void deallocate (pointer p, size_type n) |
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182 | { |
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183 | sfree<Tp> (p, n); |
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184 | } |
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185 | |
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186 | size_type max_size ()const throw () |
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187 | { |
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188 | return size_t (-1) / sizeof (Tp); |
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189 | } |
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190 | |
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191 | void construct (pointer p, const Tp &val) |
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192 | { |
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193 | ::new (p) Tp (val); |
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194 | } |
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195 | |
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196 | void destroy (pointer p) |
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197 | { |
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198 | p->~Tp (); |
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199 | } |
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200 | }; |
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201 | |
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202 | // P. L'Ecuyer, “Maximally Equidistributed Combined Tausworthe Generators”, Mathematics of Computation, 65, 213 (1996), 203–213. |
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203 | // http://www.iro.umontreal.ca/~lecuyer/myftp/papers/tausme.ps |
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204 | // http://www.iro.umontreal.ca/~lecuyer/myftp/papers/tausme2.ps |
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205 | struct tausworthe_random_generator |
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206 | { |
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207 | // generator |
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208 | uint32_t state [4]; |
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209 | |
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210 | void operator =(const tausworthe_random_generator &src) |
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211 | { |
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212 | state [0] = src.state [0]; |
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213 | state [1] = src.state [1]; |
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214 | state [2] = src.state [2]; |
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215 | state [3] = src.state [3]; |
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216 | } |
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217 | |
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218 | void seed (uint32_t seed); |
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219 | uint32_t next (); |
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220 | |
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221 | // uniform distribution |
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222 | uint32_t operator ()(uint32_t r_max) |
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223 | { |
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224 | return is_constant (r_max) |
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225 | ? this->next () % r_max |
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226 | : get_range (r_max); |
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227 | } |
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228 | |
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229 | // return a number within (min .. max) |
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230 | int operator () (int r_min, int r_max) |
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231 | { |
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232 | return is_constant (r_min) && is_constant (r_max) |
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233 | ? r_min + (*this) (max (r_max - r_min + 1, 1)) |
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234 | : get_range (r_min, r_max); |
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235 | } |
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236 | |
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237 | double operator ()() |
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238 | { |
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239 | return this->next () / (double)0xFFFFFFFFU; |
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240 | } |
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241 | |
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242 | protected: |
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243 | uint32_t get_range (uint32_t r_max); |
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244 | int get_range (int r_min, int r_max); |
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245 | }; |
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246 | |
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247 | typedef tausworthe_random_generator rand_gen; |
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248 | |
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249 | extern rand_gen rndm; |
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250 | |
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251 | template<class T> |
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252 | struct refptr |
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253 | { |
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254 | T *p; |
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255 | |
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256 | refptr () : p(0) { } |
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257 | refptr (const refptr<T> &p) : p(p.p) { if (p) p->refcnt_inc (); } |
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258 | refptr (T *p) : p(p) { if (p) p->refcnt_inc (); } |
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259 | ~refptr () { if (p) p->refcnt_dec (); } |
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260 | |
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261 | const refptr<T> &operator =(T *o) |
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262 | { |
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263 | if (p) p->refcnt_dec (); |
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264 | p = o; |
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265 | if (p) p->refcnt_inc (); |
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266 | |
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267 | return *this; |
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268 | } |
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269 | |
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270 | const refptr<T> &operator =(const refptr<T> o) |
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271 | { |
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272 | *this = o.p; |
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273 | return *this; |
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274 | } |
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275 | |
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276 | T &operator * () const { return *p; } |
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277 | T *operator ->() const { return p; } |
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278 | |
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279 | operator T *() const { return p; } |
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280 | }; |
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281 | |
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282 | typedef refptr<maptile> maptile_ptr; |
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283 | typedef refptr<object> object_ptr; |
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284 | typedef refptr<archetype> arch_ptr; |
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285 | typedef refptr<client> client_ptr; |
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286 | typedef refptr<player> player_ptr; |
18 | |
287 | |
19 | struct str_hash |
288 | struct str_hash |
20 | { |
289 | { |
21 | std::size_t operator ()(const char *s) const |
290 | std::size_t operator ()(const char *s) const |
22 | { |
291 | { |
… | |
… | |
48 | { |
317 | { |
49 | return !strcmp (a, b); |
318 | return !strcmp (a, b); |
50 | } |
319 | } |
51 | }; |
320 | }; |
52 | |
321 | |
53 | #endif |
322 | template<class T> |
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323 | struct unordered_vector : std::vector<T, slice_allocator<T> > |
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324 | { |
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325 | typedef typename unordered_vector::iterator iterator; |
54 | |
326 | |
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327 | void erase (unsigned int pos) |
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328 | { |
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329 | if (pos < this->size () - 1) |
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330 | (*this)[pos] = (*this)[this->size () - 1]; |
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331 | |
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332 | this->pop_back (); |
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333 | } |
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334 | |
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335 | void erase (iterator i) |
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336 | { |
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337 | erase ((unsigned int )(i - this->begin ())); |
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338 | } |
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339 | }; |
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340 | |
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341 | template<class T, int T::* index> |
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342 | struct object_vector : std::vector<T *, slice_allocator<T *> > |
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343 | { |
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344 | void insert (T *obj) |
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345 | { |
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346 | assert (!(obj->*index)); |
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347 | push_back (obj); |
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348 | obj->*index = this->size (); |
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349 | } |
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350 | |
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351 | void insert (T &obj) |
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352 | { |
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353 | insert (&obj); |
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354 | } |
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355 | |
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356 | void erase (T *obj) |
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357 | { |
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358 | assert (obj->*index); |
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359 | int pos = obj->*index; |
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360 | obj->*index = 0; |
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361 | |
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362 | if (pos < this->size ()) |
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363 | { |
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364 | (*this)[pos - 1] = (*this)[this->size () - 1]; |
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365 | (*this)[pos - 1]->*index = pos; |
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366 | } |
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367 | |
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368 | this->pop_back (); |
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369 | } |
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370 | |
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371 | void erase (T &obj) |
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372 | { |
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373 | errase (&obj); |
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374 | } |
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375 | }; |
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376 | |
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377 | // basically does what strncpy should do, but appends "..." to strings exceeding length |
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378 | void assign (char *dst, const char *src, int maxlen); |
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379 | |
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380 | // type-safe version of assign |
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381 | template<int N> |
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382 | inline void assign (char (&dst)[N], const char *src) |
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383 | { |
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384 | assign ((char *)&dst, src, N); |
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385 | } |
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386 | |
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387 | typedef double tstamp; |
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388 | |
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389 | // return current time as timestampe |
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390 | tstamp now (); |
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391 | |
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392 | int similar_direction (int a, int b); |
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393 | |
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394 | #endif |
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395 | |