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1 @c -*-texinfo-*-
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2 @c This is part of the XEmacs Lisp Reference Manual.
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3 @c Copyright (C) 1990, 1991, 1992, 1993, 1994 Free Software Foundation, Inc.
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4 @c See the file lispref.texi for copying conditions.
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5 @setfilename ../../info/compile.info
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6 @node Byte Compilation, Debugging, Loading, Top
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7 @chapter Byte Compilation
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8 @cindex byte-code
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9 @cindex compilation
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10
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11 XEmacs Lisp has a @dfn{compiler} that translates functions written
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12 in Lisp into a special representation called @dfn{byte-code} that can be
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13 executed more efficiently. The compiler replaces Lisp function
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14 definitions with byte-code. When a byte-coded function is called, its
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15 definition is evaluated by the @dfn{byte-code interpreter}.
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16
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17 Because the byte-compiled code is evaluated by the byte-code
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18 interpreter, instead of being executed directly by the machine's
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19 hardware (as true compiled code is), byte-code is completely
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20 transportable from machine to machine without recompilation. It is not,
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21 however, as fast as true compiled code.
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22
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217
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23 In general, any version of Emacs can run byte-compiled code produced
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24 by recent earlier versions of Emacs, but the reverse is not true. In
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25 particular, if you compile a program with XEmacs 20, the compiled code
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26 may not run in earlier versions.
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27
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28 The first time a compiled-function object is executed, the byte-code
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29 instructions are validated and the byte-code is further optimized. An
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30 @code{invalid-byte-code} error is signaled if the byte-code is invalid,
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31 for example if it contains invalid opcodes. This usually means a bug in
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32 the byte compiler.
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33
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34 @iftex
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35 @xref{Docs and Compilation}.
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36 @end iftex
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37
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38 @xref{Compilation Errors}, for how to investigate errors occurring in
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39 byte compilation.
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40
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41 @menu
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42 * Speed of Byte-Code:: An example of speedup from byte compilation.
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43 * Compilation Functions:: Byte compilation functions.
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44 * Docs and Compilation:: Dynamic loading of documentation strings.
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45 * Dynamic Loading:: Dynamic loading of individual functions.
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46 * Eval During Compile:: Code to be evaluated when you compile.
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47 * Compiled-Function Objects:: The data type used for byte-compiled functions.
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48 * Disassembly:: Disassembling byte-code; how to read byte-code.
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49 @end menu
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50
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51 @node Speed of Byte-Code
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52 @section Performance of Byte-Compiled Code
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53
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54 A byte-compiled function is not as efficient as a primitive function
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55 written in C, but runs much faster than the version written in Lisp.
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56 Here is an example:
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57
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58 @example
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59 @group
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60 (defun silly-loop (n)
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61 "Return time before and after N iterations of a loop."
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62 (let ((t1 (current-time-string)))
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63 (while (> (setq n (1- n))
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64 0))
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65 (list t1 (current-time-string))))
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66 @result{} silly-loop
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67 @end group
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68
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69 @group
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70 (silly-loop 5000000)
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71 @result{} ("Mon Sep 14 15:51:49 1998"
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72 "Mon Sep 14 15:52:07 1998") ; @r{18 seconds}
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73 @end group
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74
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75 @group
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76 (byte-compile 'silly-loop)
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77 @result{} #<compiled-function
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78 (n)
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79 "...(23)"
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80 [current-time-string t1 n 0]
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81 2
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82 "Return time before and after N iterations of a loop.">
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83 @end group
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84
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85 @group
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86 (silly-loop 5000000)
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87 @result{} ("Mon Sep 14 15:53:43 1998"
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88 "Mon Sep 14 15:53:49 1998") ; @r{6 seconds}
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89 @end group
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90 @end example
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91
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92 In this example, the interpreted code required 18 seconds to run,
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93 whereas the byte-compiled code required 6 seconds. These results are
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94 representative, but actual results will vary greatly.
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95
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96 @node Compilation Functions
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97 @comment node-name, next, previous, up
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98 @section The Compilation Functions
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99 @cindex compilation functions
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100
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101 You can byte-compile an individual function or macro definition with
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102 the @code{byte-compile} function. You can compile a whole file with
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103 @code{byte-compile-file}, or several files with
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104 @code{byte-recompile-directory} or @code{batch-byte-compile}.
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105
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106 When you run the byte compiler, you may get warnings in a buffer
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107 called @samp{*Compile-Log*}. These report things in your program that
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108 suggest a problem but are not necessarily erroneous.
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109
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110 @cindex macro compilation
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111 Be careful when byte-compiling code that uses macros. Macro calls are
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112 expanded when they are compiled, so the macros must already be defined
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113 for proper compilation. For more details, see @ref{Compiling Macros}.
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114
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115 Normally, compiling a file does not evaluate the file's contents or
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116 load the file. But it does execute any @code{require} calls at top
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117 level in the file. One way to ensure that necessary macro definitions
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118 are available during compilation is to @code{require} the file that defines
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119 them (@pxref{Named Features}). To avoid loading the macro definition files
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120 when someone @emph{runs} the compiled program, write
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121 @code{eval-when-compile} around the @code{require} calls (@pxref{Eval
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122 During Compile}).
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123
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124 @defun byte-compile symbol
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125 This function byte-compiles the function definition of @var{symbol},
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126 replacing the previous definition with the compiled one. The function
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127 definition of @var{symbol} must be the actual code for the function;
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128 i.e., the compiler does not follow indirection to another symbol.
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129 @code{byte-compile} returns the new, compiled definition of
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130 @var{symbol}.
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131
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132 If @var{symbol}'s definition is a compiled-function object,
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133 @code{byte-compile} does nothing and returns @code{nil}. Lisp records
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134 only one function definition for any symbol, and if that is already
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135 compiled, non-compiled code is not available anywhere. So there is no
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136 way to ``compile the same definition again.''
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137
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138 @example
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139 @group
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140 (defun factorial (integer)
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141 "Compute factorial of INTEGER."
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142 (if (= 1 integer) 1
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143 (* integer (factorial (1- integer)))))
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144 @result{} factorial
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145 @end group
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146
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147 @group
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148 (byte-compile 'factorial)
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149 @result{} #<compiled-function
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150 (integer)
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151 "...(21)"
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152 [integer 1 factorial]
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153 3
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154 "Compute factorial of INTEGER.">
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155 @end group
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156 @end example
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157
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158 @noindent
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159 The result is a compiled-function object. The string it contains is
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160 the actual byte-code; each character in it is an instruction or an
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161 operand of an instruction. The vector contains all the constants,
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162 variable names and function names used by the function, except for
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163 certain primitives that are coded as special instructions.
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164 @end defun
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165
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166 @deffn Command compile-defun &optional arg
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167 This command reads the defun containing point, compiles it, and
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168 evaluates the result. If you use this on a defun that is actually a
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169 function definition, the effect is to install a compiled version of that
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170 function.
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171
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172 @c XEmacs feature
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173 If @var{arg} is non-@code{nil}, the result is inserted in the current
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174 buffer after the form; otherwise, it is printed in the minibuffer.
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175 @end deffn
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176
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177 @deffn Command byte-compile-file filename &optional load
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178 This function compiles a file of Lisp code named @var{filename} into
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179 a file of byte-code. The output file's name is made by appending
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180 @samp{c} to the end of @var{filename}.
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181
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182 @c XEmacs feature
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183 If @code{load} is non-@code{nil}, the file is loaded after having been
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184 compiled.
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185
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186 Compilation works by reading the input file one form at a time. If it
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187 is a definition of a function or macro, the compiled function or macro
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188 definition is written out. Other forms are batched together, then each
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189 batch is compiled, and written so that its compiled code will be
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190 executed when the file is read. All comments are discarded when the
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191 input file is read.
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192
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193 This command returns @code{t}. When called interactively, it prompts
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194 for the file name.
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195
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196 @example
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197 @group
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198 % ls -l push*
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199 -rw-r--r-- 1 lewis 791 Oct 5 20:31 push.el
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200 @end group
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201
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202 @group
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203 (byte-compile-file "~/emacs/push.el")
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204 @result{} t
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205 @end group
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206
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207 @group
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208 % ls -l push*
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209 -rw-r--r-- 1 lewis 791 Oct 5 20:31 push.el
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210 -rw-r--r-- 1 lewis 638 Oct 8 20:25 push.elc
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211 @end group
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212 @end example
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213 @end deffn
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214
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215 @c flag is not optional in FSF Emacs
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216 @deffn Command byte-recompile-directory directory &optional flag
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217 @cindex library compilation
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218 This function recompiles every @samp{.el} file in @var{directory} that
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219 needs recompilation. A file needs recompilation if a @samp{.elc} file
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220 exists but is older than the @samp{.el} file.
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221
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222 When a @samp{.el} file has no corresponding @samp{.elc} file, then
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223 @var{flag} says what to do. If it is @code{nil}, these files are
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224 ignored. If it is non-@code{nil}, the user is asked whether to compile
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225 each such file.
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226
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227 The return value of this command is unpredictable.
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228 @end deffn
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229
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230 @defun batch-byte-compile
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231 This function runs @code{byte-compile-file} on files specified on the
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232 command line. This function must be used only in a batch execution of
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233 Emacs, as it kills Emacs on completion. An error in one file does not
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234 prevent processing of subsequent files. (The file that gets the error
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235 will not, of course, produce any compiled code.)
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236
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237 @example
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238 % emacs -batch -f batch-byte-compile *.el
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239 @end example
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240 @end defun
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241
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242 @c XEmacs feature
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243 @defun batch-byte-recompile-directory
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244 This function is similar to @code{batch-byte-compile} but runs the
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245 command @code{byte-recompile-directory} on the files remaining on the
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246 command line.
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247 @end defun
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248
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249 @c XEmacs feature
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250 @defvar byte-recompile-directory-ignore-errors-p
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251 If non-@code{nil}, this specifies that @code{byte-recompile-directory}
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252 will continue compiling even when an error occurs in a file. This is
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253 normally @code{nil}, but is bound to @code{t} by
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254 @code{batch-byte-recompile-directory}.
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255 @end defvar
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256
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257 @defun byte-code instructions constants stack-size
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258 @cindex byte-code interpreter
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259 This function actually interprets byte-code.
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260 Don't call this function yourself. Only the byte compiler knows how to
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261 generate valid calls to this function.
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262
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263 In newer Emacs versions (19 and up), byte code is usually executed as
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264 part of a compiled-function object, and only rarely due to an explicit
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265 call to @code{byte-code}. A byte-compiled function was once actually
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266 defined with a body that calls @code{byte-code}, but in recent versions
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267 of Emacs @code{byte-code} is only used to run isolated fragments of lisp
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268 code without an associated argument list.
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269 @end defun
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270
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271 @node Docs and Compilation
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272 @section Documentation Strings and Compilation
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273 @cindex dynamic loading of documentation
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274
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275 Functions and variables loaded from a byte-compiled file access their
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276 documentation strings dynamically from the file whenever needed. This
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277 saves space within Emacs, and makes loading faster because the
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278 documentation strings themselves need not be processed while loading the
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279 file. Actual access to the documentation strings becomes slower as a
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280 result, but normally not enough to bother users.
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281
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282 Dynamic access to documentation strings does have drawbacks:
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283
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284 @itemize @bullet
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285 @item
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286 If you delete or move the compiled file after loading it, Emacs can no
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287 longer access the documentation strings for the functions and variables
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288 in the file.
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289
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290 @item
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291 If you alter the compiled file (such as by compiling a new version),
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292 then further access to documentation strings in this file will give
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293 nonsense results.
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294 @end itemize
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295
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296 If your site installs Emacs following the usual procedures, these
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297 problems will never normally occur. Installing a new version uses a new
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298 directory with a different name; as long as the old version remains
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299 installed, its files will remain unmodified in the places where they are
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300 expected to be.
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301
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302 However, if you have built Emacs yourself and use it from the
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303 directory where you built it, you will experience this problem
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304 occasionally if you edit and recompile Lisp files. When it happens, you
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305 can cure the problem by reloading the file after recompiling it.
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306
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307 Versions of Emacs up to and including XEmacs 19.14 and FSF Emacs 19.28
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308 do not support the dynamic docstrings feature, and so will not be able
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309 to load bytecode created by more recent Emacs versions. You can turn
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310 off the dynamic docstring feature by setting
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311 @code{byte-compile-dynamic-docstrings} to @code{nil}. Once this is
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312 done, you can compile files that will load into older Emacs versions.
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313 You can do this globally, or for one source file by specifying a
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314 file-local binding for the variable. Here's one way to do that:
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315
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316 @example
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317 -*-byte-compile-dynamic-docstrings: nil;-*-
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318 @end example
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319
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320 @defvar byte-compile-dynamic-docstrings
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321 If this is non-@code{nil}, the byte compiler generates compiled files
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322 that are set up for dynamic loading of documentation strings.
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323 @end defvar
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324
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325 @cindex @samp{#@@@var{count}}
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326 @cindex @samp{#$}
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327 The dynamic documentation string feature writes compiled files that
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328 use a special Lisp reader construct, @samp{#@@@var{count}}. This
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329 construct skips the next @var{count} characters. It also uses the
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330 @samp{#$} construct, which stands for ``the name of this file, as a
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331 string.'' It is best not to use these constructs in Lisp source files.
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332
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333 @node Dynamic Loading
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334 @section Dynamic Loading of Individual Functions
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335
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336 @cindex dynamic loading of functions
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337 @cindex lazy loading
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338 When you compile a file, you can optionally enable the @dfn{dynamic
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339 function loading} feature (also known as @dfn{lazy loading}). With
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340 dynamic function loading, loading the file doesn't fully read the
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341 function definitions in the file. Instead, each function definition
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342 contains a place-holder which refers to the file. The first time each
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343 function is called, it reads the full definition from the file, to
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344 replace the place-holder.
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345
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346 The advantage of dynamic function loading is that loading the file
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347 becomes much faster. This is a good thing for a file which contains
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348 many separate commands, provided that using one of them does not imply
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349 you will soon (or ever) use the rest. A specialized mode which provides
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350 many keyboard commands often has that usage pattern: a user may invoke
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351 the mode, but use only a few of the commands it provides.
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352
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353 The dynamic loading feature has certain disadvantages:
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354
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355 @itemize @bullet
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356 @item
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357 If you delete or move the compiled file after loading it, Emacs can no
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358 longer load the remaining function definitions not already loaded.
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359
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360 @item
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361 If you alter the compiled file (such as by compiling a new version),
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362 then trying to load any function not already loaded will get nonsense
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363 results.
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364 @end itemize
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365
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366 If you compile a new version of the file, the best thing to do is
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367 immediately load the new compiled file. That will prevent any future
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368 problems.
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369
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370 The byte compiler uses the dynamic function loading feature if the
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371 variable @code{byte-compile-dynamic} is non-@code{nil} at compilation
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372 time. Do not set this variable globally, since dynamic loading is
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373 desirable only for certain files. Instead, enable the feature for
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374 specific source files with file-local variable bindings, like this:
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375
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376 @example
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377 -*-byte-compile-dynamic: t;-*-
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378 @end example
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379
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380 @defvar byte-compile-dynamic
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381 If this is non-@code{nil}, the byte compiler generates compiled files
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382 that are set up for dynamic function loading.
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383 @end defvar
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384
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385 @defun fetch-bytecode function
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386 This immediately finishes loading the definition of @var{function} from
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387 its byte-compiled file, if it is not fully loaded already. The argument
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388 @var{function} may be a compiled-function object or a function name.
|
|
|
389 @end defun
|
|
|
390
|
|
|
391 @node Eval During Compile
|
|
|
392 @section Evaluation During Compilation
|
|
|
393
|
|
|
394 These features permit you to write code to be evaluated during
|
|
|
395 compilation of a program.
|
|
|
396
|
|
|
397 @defspec eval-and-compile body
|
|
|
398 This form marks @var{body} to be evaluated both when you compile the
|
|
|
399 containing code and when you run it (whether compiled or not).
|
|
|
400
|
|
|
401 You can get a similar result by putting @var{body} in a separate file
|
|
|
402 and referring to that file with @code{require}. Using @code{require} is
|
|
|
403 preferable if there is a substantial amount of code to be executed in
|
|
|
404 this way.
|
|
|
405 @end defspec
|
|
|
406
|
|
|
407 @defspec eval-when-compile body
|
|
|
408 This form marks @var{body} to be evaluated at compile time and not when
|
|
|
409 the compiled program is loaded. The result of evaluation by the
|
|
|
410 compiler becomes a constant which appears in the compiled program. When
|
|
|
411 the program is interpreted, not compiled at all, @var{body} is evaluated
|
|
|
412 normally.
|
|
|
413
|
|
|
414 At top level, this is analogous to the Common Lisp idiom
|
|
|
415 @code{(eval-when (compile eval) @dots{})}. Elsewhere, the Common Lisp
|
|
|
416 @samp{#.} reader macro (but not when interpreting) is closer to what
|
|
|
417 @code{eval-when-compile} does.
|
|
|
418 @end defspec
|
|
|
419
|
|
|
420 @node Compiled-Function Objects
|
|
|
421 @section Compiled-Function Objects
|
|
|
422 @cindex compiled function
|
|
|
423 @cindex byte-code function
|
|
|
424
|
|
|
425 Byte-compiled functions have a special data type: they are
|
|
380
|
426 @dfn{compiled-function objects}. The evaluator handles this data type
|
|
|
427 specially when it appears as a function to be called.
|
|
0
|
428
|
|
380
|
429 The printed representation for a compiled-function object normally
|
|
|
430 begins with @samp{#<compiled-function} and ends with @samp{>}. However,
|
|
|
431 if the variable @code{print-readably} is non-@code{nil}, the object is
|
|
|
432 printed beginning with @samp{#[} and ending with @samp{]}. This
|
|
|
433 representation can be read directly by the Lisp reader, and is used in
|
|
|
434 byte-compiled files (those ending in @samp{.elc}).
|
|
0
|
435
|
|
|
436 In Emacs version 18, there was no compiled-function object data type;
|
|
|
437 compiled functions used the function @code{byte-code} to run the byte
|
|
|
438 code.
|
|
|
439
|
|
380
|
440 A compiled-function object has a number of different attributes.
|
|
0
|
441 They are:
|
|
|
442
|
|
|
443 @table @var
|
|
|
444 @item arglist
|
|
|
445 The list of argument symbols.
|
|
|
446
|
|
|
447 @item instructions
|
|
|
448 The string containing the byte-code instructions.
|
|
|
449
|
|
|
450 @item constants
|
|
|
451 The vector of Lisp objects referenced by the byte code. These include
|
|
|
452 symbols used as function names and variable names.
|
|
|
453
|
|
380
|
454 @item stack-size
|
|
0
|
455 The maximum stack size this function needs.
|
|
|
456
|
|
|
457 @item doc-string
|
|
|
458 The documentation string (if any); otherwise, @code{nil}. The value may
|
|
|
459 be a number or a list, in case the documentation string is stored in a
|
|
|
460 file. Use the function @code{documentation} to get the real
|
|
|
461 documentation string (@pxref{Accessing Documentation}).
|
|
|
462
|
|
|
463 @item interactive
|
|
|
464 The interactive spec (if any). This can be a string or a Lisp
|
|
|
465 expression. It is @code{nil} for a function that isn't interactive.
|
|
|
466
|
|
|
467 @item domain
|
|
|
468 The domain (if any). This is only meaningful if I18N3 (message-translation)
|
|
|
469 support was compiled into XEmacs. This is a string defining which
|
|
|
470 domain to find the translation for the documentation string and
|
|
|
471 interactive prompt. @xref{Domain Specification}.
|
|
|
472 @end table
|
|
|
473
|
|
|
474 Here's an example of a compiled-function object, in printed
|
|
|
475 representation. It is the definition of the command
|
|
|
476 @code{backward-sexp}.
|
|
|
477
|
|
|
478 @example
|
|
380
|
479 (symbol-function 'backward-sexp)
|
|
|
480 @result{} #<compiled-function
|
|
219
|
481 (&optional arg)
|
|
|
482 "...(15)" [arg 1 forward-sexp] 2 854740 "_p">
|
|
0
|
483 @end example
|
|
|
484
|
|
|
485 The primitive way to create a compiled-function object is with
|
|
|
486 @code{make-byte-code}:
|
|
|
487
|
|
380
|
488 @defun make-byte-code arglist instructions constants stack-size &optional doc-string interactive
|
|
0
|
489 This function constructs and returns a compiled-function object
|
|
380
|
490 with the specified attributes.
|
|
0
|
491
|
|
298
|
492 @emph{Please note:} Unlike all other Emacs-lisp functions, calling this with
|
|
0
|
493 five arguments is @emph{not} the same as calling it with six arguments,
|
|
|
494 the last of which is @code{nil}. If the @var{interactive} arg is
|
|
|
495 specified as @code{nil}, then that means that this function was defined
|
|
|
496 with @code{(interactive)}. If the arg is not specified, then that means
|
|
|
497 the function is not interactive. This is terrible behavior which is
|
|
|
498 retained for compatibility with old @samp{.elc} files which expected
|
|
|
499 these semantics.
|
|
|
500 @end defun
|
|
|
501
|
|
|
502 You should not try to come up with the elements for a compiled-function
|
|
|
503 object yourself, because if they are inconsistent, XEmacs may crash
|
|
|
504 when you call the function. Always leave it to the byte compiler to
|
|
|
505 create these objects; it makes the elements consistent (we hope).
|
|
|
506
|
|
|
507 The following primitives are provided for accessing the elements of
|
|
|
508 a compiled-function object.
|
|
|
509
|
|
|
510 @defun compiled-function-arglist function
|
|
|
511 This function returns the argument list of compiled-function object
|
|
|
512 @var{function}.
|
|
|
513 @end defun
|
|
|
514
|
|
|
515 @defun compiled-function-instructions function
|
|
|
516 This function returns a string describing the byte-code instructions
|
|
|
517 of compiled-function object @var{function}.
|
|
|
518 @end defun
|
|
|
519
|
|
|
520 @defun compiled-function-constants function
|
|
|
521 This function returns the vector of Lisp objects referenced by
|
|
|
522 compiled-function object @var{function}.
|
|
|
523 @end defun
|
|
|
524
|
|
|
525 @defun compiled-function-stack-size function
|
|
|
526 This function returns the maximum stack size needed by compiled-function
|
|
|
527 object @var{function}.
|
|
|
528 @end defun
|
|
|
529
|
|
|
530 @defun compiled-function-doc-string function
|
|
|
531 This function returns the doc string of compiled-function object
|
|
|
532 @var{function}, if available.
|
|
|
533 @end defun
|
|
|
534
|
|
|
535 @defun compiled-function-interactive function
|
|
|
536 This function returns the interactive spec of compiled-function object
|
|
|
537 @var{function}, if any. The return value is @code{nil} or a two-element
|
|
|
538 list, the first element of which is the symbol @code{interactive} and
|
|
|
539 the second element is the interactive spec (a string or Lisp form).
|
|
|
540 @end defun
|
|
|
541
|
|
|
542 @defun compiled-function-domain function
|
|
|
543 This function returns the domain of compiled-function object
|
|
|
544 @var{function}, if any. The result will be a string or @code{nil}.
|
|
|
545 @xref{Domain Specification}.
|
|
|
546 @end defun
|
|
|
547
|
|
|
548 @node Disassembly
|
|
|
549 @section Disassembled Byte-Code
|
|
|
550 @cindex disassembled byte-code
|
|
|
551
|
|
|
552 People do not write byte-code; that job is left to the byte compiler.
|
|
|
553 But we provide a disassembler to satisfy a cat-like curiosity. The
|
|
|
554 disassembler converts the byte-compiled code into humanly readable
|
|
|
555 form.
|
|
|
556
|
|
|
557 The byte-code interpreter is implemented as a simple stack machine.
|
|
|
558 It pushes values onto a stack of its own, then pops them off to use them
|
|
|
559 in calculations whose results are themselves pushed back on the stack.
|
|
|
560 When a byte-code function returns, it pops a value off the stack and
|
|
|
561 returns it as the value of the function.
|
|
|
562
|
|
|
563 In addition to the stack, byte-code functions can use, bind, and set
|
|
|
564 ordinary Lisp variables, by transferring values between variables and
|
|
|
565 the stack.
|
|
|
566
|
|
|
567 @deffn Command disassemble object &optional stream
|
|
|
568 This function prints the disassembled code for @var{object}. If
|
|
|
569 @var{stream} is supplied, then output goes there. Otherwise, the
|
|
|
570 disassembled code is printed to the stream @code{standard-output}. The
|
|
|
571 argument @var{object} can be a function name or a lambda expression.
|
|
|
572
|
|
|
573 As a special exception, if this function is used interactively,
|
|
|
574 it outputs to a buffer named @samp{*Disassemble*}.
|
|
|
575 @end deffn
|
|
|
576
|
|
|
577 Here are two examples of using the @code{disassemble} function. We
|
|
|
578 have added explanatory comments to help you relate the byte-code to the
|
|
|
579 Lisp source; these do not appear in the output of @code{disassemble}.
|
|
|
580
|
|
|
581 @example
|
|
|
582 @group
|
|
|
583 (defun factorial (integer)
|
|
|
584 "Compute factorial of an integer."
|
|
|
585 (if (= 1 integer) 1
|
|
|
586 (* integer (factorial (1- integer)))))
|
|
|
587 @result{} factorial
|
|
|
588 @end group
|
|
|
589
|
|
|
590 @group
|
|
|
591 (factorial 4)
|
|
|
592 @result{} 24
|
|
|
593 @end group
|
|
|
594
|
|
|
595 @group
|
|
|
596 (disassemble 'factorial)
|
|
|
597 @print{} byte-code for factorial:
|
|
|
598 doc: Compute factorial of an integer.
|
|
|
599 args: (integer)
|
|
|
600 @end group
|
|
|
601
|
|
|
602 @group
|
|
380
|
603 0 varref integer ; @r{Get value of @code{integer}}
|
|
0
|
604 ; @r{from the environment}
|
|
|
605 ; @r{and push the value}
|
|
|
606 ; @r{onto the stack.}
|
|
380
|
607
|
|
|
608 1 constant 1 ; @r{Push 1 onto stack.}
|
|
0
|
609 @end group
|
|
|
610
|
|
|
611 @group
|
|
|
612 2 eqlsign ; @r{Pop top two values off stack,}
|
|
|
613 ; @r{compare them,}
|
|
|
614 ; @r{and push result onto stack.}
|
|
|
615 @end group
|
|
|
616
|
|
|
617 @group
|
|
380
|
618 3 goto-if-nil 1 ; @r{Pop and test top of stack;}
|
|
|
619 ; @r{if @code{nil},}
|
|
|
620 ; @r{go to label 1 (which is also byte 7),}
|
|
0
|
621 ; @r{else continue.}
|
|
|
622 @end group
|
|
|
623
|
|
|
624 @group
|
|
380
|
625 5 constant 1 ; @r{Push 1 onto top of stack.}
|
|
0
|
626
|
|
380
|
627 6 return ; @r{Return the top element}
|
|
|
628 ; @r{of the stack.}
|
|
0
|
629 @end group
|
|
|
630
|
|
380
|
631 7:1 varref integer ; @r{Push value of @code{integer} onto stack.}
|
|
|
632
|
|
0
|
633 @group
|
|
380
|
634 8 constant factorial ; @r{Push @code{factorial} onto stack.}
|
|
0
|
635
|
|
380
|
636 9 varref integer ; @r{Push value of @code{integer} onto stack.}
|
|
0
|
637
|
|
380
|
638 10 sub1 ; @r{Pop @code{integer}, decrement value,}
|
|
0
|
639 ; @r{push new value onto stack.}
|
|
|
640 @end group
|
|
|
641
|
|
|
642 @group
|
|
|
643 ; @r{Stack now contains:}
|
|
|
644 ; @minus{} @r{decremented value of @code{integer}}
|
|
380
|
645 ; @minus{} @r{@code{factorial}}
|
|
0
|
646 ; @minus{} @r{value of @code{integer}}
|
|
|
647 @end group
|
|
|
648
|
|
|
649 @group
|
|
|
650 15 call 1 ; @r{Call function @code{factorial} using}
|
|
|
651 ; @r{the first (i.e., the top) element}
|
|
|
652 ; @r{of the stack as the argument;}
|
|
|
653 ; @r{push returned value onto stack.}
|
|
|
654 @end group
|
|
|
655
|
|
|
656 @group
|
|
|
657 ; @r{Stack now contains:}
|
|
|
658 ; @minus{} @r{result of recursive}
|
|
|
659 ; @r{call to @code{factorial}}
|
|
|
660 ; @minus{} @r{value of @code{integer}}
|
|
|
661 @end group
|
|
|
662
|
|
|
663 @group
|
|
380
|
664 12 mult ; @r{Pop top two values off the stack,}
|
|
|
665 ; @r{multiply them,}
|
|
0
|
666 ; @r{pushing the result onto the stack.}
|
|
|
667 @end group
|
|
|
668
|
|
|
669 @group
|
|
380
|
670 13 return ; @r{Return the top element}
|
|
0
|
671 ; @r{of the stack.}
|
|
|
672 @result{} nil
|
|
|
673 @end group
|
|
|
674 @end example
|
|
|
675
|
|
|
676 The @code{silly-loop} function is somewhat more complex:
|
|
|
677
|
|
|
678 @example
|
|
|
679 @group
|
|
|
680 (defun silly-loop (n)
|
|
|
681 "Return time before and after N iterations of a loop."
|
|
|
682 (let ((t1 (current-time-string)))
|
|
380
|
683 (while (> (setq n (1- n))
|
|
0
|
684 0))
|
|
|
685 (list t1 (current-time-string))))
|
|
|
686 @result{} silly-loop
|
|
|
687 @end group
|
|
|
688
|
|
|
689 @group
|
|
|
690 (disassemble 'silly-loop)
|
|
|
691 @print{} byte-code for silly-loop:
|
|
|
692 doc: Return time before and after N iterations of a loop.
|
|
|
693 args: (n)
|
|
|
694
|
|
|
695 0 constant current-time-string ; @r{Push}
|
|
|
696 ; @r{@code{current-time-string}}
|
|
|
697 ; @r{onto top of stack.}
|
|
|
698 @end group
|
|
|
699
|
|
|
700 @group
|
|
|
701 1 call 0 ; @r{Call @code{current-time-string}}
|
|
|
702 ; @r{ with no argument,}
|
|
|
703 ; @r{ pushing result onto stack.}
|
|
|
704 @end group
|
|
|
705
|
|
|
706 @group
|
|
|
707 2 varbind t1 ; @r{Pop stack and bind @code{t1}}
|
|
|
708 ; @r{to popped value.}
|
|
|
709 @end group
|
|
|
710
|
|
|
711 @group
|
|
380
|
712 3:1 varref n ; @r{Get value of @code{n} from}
|
|
0
|
713 ; @r{the environment and push}
|
|
|
714 ; @r{the value onto the stack.}
|
|
|
715 @end group
|
|
|
716
|
|
|
717 @group
|
|
|
718 4 sub1 ; @r{Subtract 1 from top of stack.}
|
|
|
719 @end group
|
|
|
720
|
|
|
721 @group
|
|
|
722 5 dup ; @r{Duplicate the top of the stack;}
|
|
|
723 ; @r{i.e., copy the top of}
|
|
|
724 ; @r{the stack and push the}
|
|
|
725 ; @r{copy onto the stack.}
|
|
|
726
|
|
|
727 6 varset n ; @r{Pop the top of the stack,}
|
|
380
|
728 ; @r{and set @code{n} to the value.}
|
|
0
|
729
|
|
|
730 ; @r{In effect, the sequence @code{dup varset}}
|
|
|
731 ; @r{copies the top of the stack}
|
|
|
732 ; @r{into the value of @code{n}}
|
|
|
733 ; @r{without popping it.}
|
|
|
734 @end group
|
|
|
735
|
|
|
736 @group
|
|
|
737 7 constant 0 ; @r{Push 0 onto stack.}
|
|
|
738
|
|
|
739 8 gtr ; @r{Pop top two values off stack,}
|
|
|
740 ; @r{test if @var{n} is greater than 0}
|
|
|
741 ; @r{and push result onto stack.}
|
|
|
742 @end group
|
|
|
743
|
|
|
744 @group
|
|
380
|
745 9 goto-if-not-nil 1 ; @r{Goto label 1 (byte 3) if @code{n} <= 0}
|
|
0
|
746 ; @r{(this exits the while loop).}
|
|
|
747 ; @r{else pop top of stack}
|
|
|
748 ; @r{and continue}
|
|
|
749 @end group
|
|
|
750
|
|
|
751 @group
|
|
380
|
752 11 varref t1 ; @r{Push value of @code{t1} onto stack.}
|
|
0
|
753 @end group
|
|
|
754
|
|
|
755 @group
|
|
380
|
756 12 constant current-time-string ; @r{Push}
|
|
0
|
757 ; @r{@code{current-time-string}}
|
|
|
758 ; @r{onto top of stack.}
|
|
|
759 @end group
|
|
|
760
|
|
|
761 @group
|
|
380
|
762 13 call 0 ; @r{Call @code{current-time-string} again.}
|
|
|
763
|
|
|
764 14 unbind 1 ; @r{Unbind @code{t1} in local environment.}
|
|
0
|
765 @end group
|
|
|
766
|
|
|
767 @group
|
|
380
|
768 15 list2 ; @r{Pop top two elements off stack,}
|
|
0
|
769 ; @r{create a list of them,}
|
|
|
770 ; @r{and push list onto stack.}
|
|
|
771 @end group
|
|
|
772
|
|
|
773 @group
|
|
380
|
774 16 return ; @r{Return the top element of the stack.}
|
|
0
|
775
|
|
|
776 @result{} nil
|
|
|
777 @end group
|
|
|
778 @end example
|
|
|
779
|
|
|
780
|
