3 .\" Copyright 2003 Ximian, Inc.
4 .\" Copyright 2004-2011 Novell, Inc.
6 .\" Miguel de Icaza (miguel@gnu.org)
10 mono \- Mono's ECMA-CLI native code generator (Just-in-Time and Ahead-of-Time)
13 .B mono [options] file [arguments...]
15 .B mono-sgen [options] file [arguments...]
17 \fImono\fP is a runtime implementation of the ECMA Common Language
18 Infrastructure. This can be used to run ECMA and .NET applications.
20 The runtime contains a native code generator that transforms the
21 Common Intermediate Language into native code.
23 The code generator can operate in two modes: just in time compilation
24 (JIT) or ahead of time compilation (AOT). Since code can be
25 dynamically loaded, the runtime environment and the JIT are always
26 present, even if code is compiled ahead of time.
28 The runtime loads the specified
35 is an ECMA assembly. They typically have a .exe or .dll extension.
37 The runtime provides a number of configuration options for running
38 applications, for developing and debugging, and for testing and
39 debugging the runtime itself.
41 The \fImono\fP command uses the Boehm conservative garbage collector
42 while the \fImono-sgen\fP command uses a moving and generational
45 On Unix-based systems, Mono provides a mechanism to emulate the
46 Windows-style file access, this includes providing a case insensitive
47 view of the file system, directory separator mapping (from \\ to /) and
48 stripping the drive letters.
50 This functionality is enabled by setting the
52 environment variable to one of
57 See the description for
59 in the environment variables section for more details.
61 The following options are available:
63 \fB--aot\fR, \fB--aot[=options]\fR
64 This option is used to precompile the CIL code in the specified
65 assembly to native code. The generated code is stored in a file with
66 the extension .so. This file will be automatically picked up by the
67 runtime when the assembly is executed.
69 Ahead-of-Time compilation is most useful if you use it in combination
70 with the -O=all,-shared flag which enables all of the optimizations in
71 the code generator to be performed. Some of those optimizations are
72 not practical for Just-in-Time compilation since they might be very
75 Unlike the .NET Framework, Ahead-of-Time compilation will not generate
76 domain independent code: it generates the same code that the
77 Just-in-Time compiler would produce. Since most applications use a
78 single domain, this is fine. If you want to optimize the generated
79 code for use in multi-domain applications, consider using the
82 This pre-compiles the methods, but the original assembly is still
83 required to execute as this one contains the metadata and exception
84 information which is not available on the generated file. When
85 precompiling code, you might want to compile with all optimizations
86 (-O=all). Pre-compiled code is position independent code.
88 Pre compilation is just a mechanism to reduce startup time, increase
89 code sharing across multiple mono processes and avoid just-in-time
90 compilation program startup costs. The original assembly must still
91 be present, as the metadata is contained there.
93 AOT code typically can not be moved from one computer to another
94 (CPU-specific optimizations that are detected at runtime) so you
95 should not try to move the pre-generated assemblies or package the
96 pre-generated assemblies for deployment.
98 A few options are available as a parameter to the
100 command line option. The options are separated by commas, and more
101 than one can be specified:
105 .I bind-to-runtime-version
107 If specified, forces the generated AOT files to be bound to the
108 runtime version of the compiling Mono. This will prevent the AOT
109 files from being consumed by a different Mono runtime.
111 This is currently an experimental feature as it is not complete.
112 This instructs Mono to precompile code that has historically not been
113 precompiled with AOT.
115 .I outfile=[filename]
116 Instructs the AOT compiler to save the output to the specified file.
119 Instructs the AOT compiler to emit debug symbol information.
121 .I save-temps,keep-temps
122 Instructs the AOT compiler to keep temporary files.
125 This is an experimental option for the AOT compiler to use multiple threads
126 when compiling the methods.
129 Instructs the AOT compiler to not output any debugging information.
131 .I ntrampolines=[number]
132 When compiling in full aot mode, the method trampolines must be precreated
133 in the AOT image. You can add additional method trampolines with this argument.
136 .I nrgctx-trampolines=[number]
137 When compiling in full aot mode, the generic sharing trampolines must be precreated
138 in the AOT image. You can add additional method trampolines with this argument.
141 .I nimt-trampolines=[number]
142 When compiling in full aot mode, the IMT trampolines must be precreated
143 in the AOT image. You can add additional method trampolines with this argument.
146 .I print-skipped-methods
147 If the AOT compiler cannot compile a method for any reason, enabling this flag
148 will output the skipped methods to the console.
151 The AOT compiler will emit a (ELF only) library initializer to automatically
152 register the aot compiled module with the runtime. This is only useful in static
156 Instructs the AOT compiler to output assembly code instead of an object file.
159 This instructs the compiler to generate sequence point checks that
160 allow Mono's soft debugger to debug applications even on systems where
161 it is not possible to set breakpoints or to single step (certain
162 hardware configurations like the cell phones and video gaming
166 Create an ELF object file (.o) or .s file which can be statically linked into an
167 executable when embedding the mono runtime. When this option is used, the object file
168 needs to be registered with the embedded runtime using the mono_aot_register_module
169 function which takes as its argument the mono_aot_module_<ASSEMBLY NAME>_info global
170 symbol from the object file:
173 extern void *mono_aot_module_hello_info;
175 mono_aot_register_module (mono_aot_module_hello_info);
180 Use the GNU style target triple <TRIPLE> to determine some code generation options, i.e.
181 --mtriple=armv7-linux-gnueabi will generate code that targets ARMv7. This is currently
182 only supported by the ARM backend. In LLVM mode, this triple is passed on to the LLVM
185 .I tool-prefix=<PREFIX>
186 Prepends <PREFIX> to the name of tools ran by the AOT compiler, i.e. 'as'/'ld'. For
187 example, --tool=prefix=arm-linux-gnueabi- will make the AOT compiler run
188 'arm-linux-gnueabi-as' instead of 'as'.
190 .I llvm-path=<PREFIX>
191 Same for the llvm tools 'opt' and 'llc'.
194 Print various stats collected during AOT compilation.
197 For more information about AOT, see: http://www.mono-project.com/AOT
200 \fB--attach=[options]\fR
201 Currently the only option supported by this command line argument is
202 \fBdisable\fR which disables the attach functionality.
204 \fB--config filename\fR
205 Load the specified configuration file instead of the default one(s).
206 The default files are /etc/mono/config and ~/.mono/config or the file
207 specified in the MONO_CONFIG environment variable, if set. See the
208 mono-config(5) man page for details on the format of this file.
210 \fB--debugger-agent=[options]\fR
211 This instructs the Mono runtime to
212 start a debugging agent inside the Mono runtime and connect it to a
213 client user interface will control the Mono process.
214 This option is typically used by IDEs, like the MonoDevelop IDE.
217 configuration is specified using one of more of the following options:
221 .I transport=transport_name
223 This is used to specify the transport that the debugger will use to
224 communicate. It must be specified and currently requires this to
229 Use this option to specify the IP address where your debugger client is
234 Specifies the diagnostics log level for
238 Used to specify the file where the log will be stored, it defaults to
242 Defaults to no, with the default option Mono will actively connect to the
243 host/port configured with the \fBaddress\fR option. If you set it to 'y', it
244 instructs the Mono runtime to start debugging in server mode, where Mono
245 actively waits for the debugger front end to connect to the Mono process.
246 Mono will print out to stdout the IP address and port where it is listening.
249 Defaults to yes, with the default option Mono will suspend the vm on startup
250 until it connects successfully to a debugger front end. If you set it to 'n', in
251 conjunction with \fBserver=y\fR, it instructs the Mono runtime to run as normal,
252 while caching metadata to send to the debugger front end on connection.
257 Configures the virtual machine to be better suited for desktop
258 applications. Currently this sets the GC system to avoid expanding
259 the heap as much as possible at the expense of slowing down garbage
263 This is an experimental flag that instructs the Mono runtime to not
264 generate any code at runtime and depend exclusively on the code
265 generated from using mono --aot=full previously. This is useful for
266 platforms that do not permit dynamic code generation.
268 Notice that this feature will abort execution at runtime if a codepath
269 in your program, or Mono's class libraries attempts to generate code
270 dynamically. You should test your software upfront and make sure that
271 you do not use any dynamic features.
273 \fB--gc=boehm\fR, \fB--gc=sgen\fR
274 Selects the Garbage Collector engine for Mono to use, Boehm or SGen.
275 Currently this merely ensures that you are running either the
276 \fImono\fR or \fImono-sgen\fR commands. This flag can be set in the
277 \fBMONO_ENV_OPTIONS\fR environment variable to force all of your child
278 processes to use one particular kind of GC with the Mono runtime.
280 \fB--help\fR, \fB-h\fR
281 Displays usage instructions.
284 If the Mono runtime has been compiled with LLVM support (not available
285 in all configurations), Mono will use the LLVM optimization and code
286 generation engine to JIT or AOT compile.
288 For more information, consult: http://www.mono-project.com/Mono_LLVM
291 When using a Mono that has been compiled with LLVM support, it forces
292 Mono to fallback to its JIT engine and not use the LLVM backend.
294 \fB--optimize=MODE\fR, \fB-O=MODE\fR
295 MODE is a comma separated list of optimizations. They also allow
296 optimizations to be turned off by prefixing the optimization name with
299 In general, Mono has been tuned to use the default set of flags,
300 before using these flags for a deployment setting, you might want to
301 actually measure the benefits of using them.
303 The following optimizations are implemented:
305 all Turn on all optimizations
306 peephole Peephole postpass
307 branch Branch optimizations
308 inline Inline method calls
309 cfold Constant folding
310 consprop Constant propagation
311 copyprop Copy propagation
312 deadce Dead code elimination
313 linears Linear scan global reg allocation
314 cmov Conditional moves [arch-dependency]
315 shared Emit per-domain code
316 sched Instruction scheduling
317 intrins Intrinsic method implementations
318 tailc Tail recursion and tail calls
319 loop Loop related optimizations
320 fcmov Fast x86 FP compares [arch-dependency]
321 leaf Leaf procedures optimizations
322 aot Usage of Ahead Of Time compiled code
323 precomp Precompile all methods before executing Main
324 abcrem Array bound checks removal
325 ssapre SSA based Partial Redundancy Elimination
326 sse2 SSE2 instructions on x86 [arch-dependency]
327 gshared Enable generic code sharing.
330 For example, to enable all the optimization but dead code
331 elimination and inlining, you can use:
333 -O=all,-deadce,-inline
336 The flags that are flagged with [arch-dependency] indicate that the
337 given option if used in combination with Ahead of Time compilation
338 (--aot flag) would produce pre-compiled code that will depend on the
339 current CPU and might not be safely moved to another computer.
341 \fB--runtime=VERSION\fR
342 Mono supports different runtime versions. The version used depends on the program
343 that is being run or on its configuration file (named program.exe.config). This option
344 can be used to override such autodetection, by forcing a different runtime version
345 to be used. Note that this should only be used to select a later compatible runtime
346 version than the one the program was compiled against. A typical usage is for
347 running a 1.1 program on a 2.0 version:
349 mono --runtime=v2.0.50727 program.exe
352 \fB--security\fR, \fB--security=mode\fR
353 Activate the security manager, a currently experimental feature in
354 Mono and it is OFF by default. The new code verifier can be enabled
355 with this option as well.
359 Using security without parameters is equivalent as calling it with the
362 The following modes are supported:
365 This allows mono to support declarative security attributes,
366 e.g. execution of Code Access Security (CAS) or non-CAS demands.
369 Enables the core-clr security system, typically used for
370 Moonlight/Silverlight applications. It provides a much simpler
371 security system than CAS, see http://www.mono-project.com/Moonlight
372 for more details and links to the descriptions of this new system.
375 Enables the new verifier and performs basic verification for code
376 validity. In this mode, unsafe code and P/Invoke are allowed. This
377 mode provides a better safety guarantee but it is still possible
378 for managed code to crash Mono.
381 Enables the new verifier and performs full verification of the code
382 being executed. It only allows verifiable code to be executed.
383 Unsafe code is not allowed but P/Invoke is. This mode should
384 not allow managed code to crash mono. The verification is not as
385 strict as ECMA 335 standard in order to stay compatible with the MS
388 The security system acts on user code: code contained in mscorlib or
389 the global assembly cache is always trusted.
394 Configures the virtual machine to be better suited for server
395 operations (currently, a no-op).
398 Verifies mscorlib and assemblies in the global
399 assembly cache for valid IL, and all user code for IL
402 This is different from \fB--security\fR's verifiable
403 or validil in that these options only check user code and skip
404 mscorlib and assemblies located on the global assembly cache.
406 \fB-V\fR, \fB--version\fR
407 Prints JIT version information (system configuration, release number
408 and branch names if available).
411 .SH DEVELOPMENT OPTIONS
412 The following options are used to help when developing a JITed application.
414 \fB--debug\fR, \fB--debug=OPTIONS\fR
415 Turns on the debugging mode in the runtime. If an assembly was
416 compiled with debugging information, it will produce line number
417 information for stack traces.
421 The optional OPTIONS argument is a comma separated list of debugging
422 options. These options are turned off by default since they generate
423 much larger and slower code at runtime.
425 The following options are supported:
428 Produces a detailed error when throwing a InvalidCastException. This
429 option needs to be enabled as this generates more verbose code at
433 Disable some JIT optimizations which are usually only disabled when
434 running inside the debugger. This can be helpful if you want to attach
435 to the running process with mdb.
438 Generate and register debugging information with gdb. This is only supported on some
439 platforms, and only when using gdb 7.0 or later.
443 \fB--profile[=profiler[:profiler_args]]\fR
444 Turns on profiling. For more information about profiling applications
445 and code coverage see the sections "PROFILING" and "CODE COVERAGE"
448 This option can be used multiple times, each time will load an
449 additional profiler. This allows developers to use modules that
450 extend the JIT through the Mono profiling interface.
452 \fB--trace[=expression]\fR
453 Shows method names as they are invoked. By default all methods are
456 The trace can be customized to include or exclude methods, classes or
457 assemblies. A trace expression is a comma separated list of targets,
458 each target can be prefixed with a minus sign to turn off a particular
459 target. The words `program', `all' and `disabled' have special
460 meaning. `program' refers to the main program being executed, and
461 `all' means all the method calls.
463 The `disabled' option is used to start up with tracing disabled. It
464 can be enabled at a later point in time in the program by sending the
465 SIGUSR2 signal to the runtime.
467 Assemblies are specified by their name, for example, to trace all
468 calls in the System assembly, use:
471 mono --trace=System app.exe
474 Classes are specified with the T: prefix. For example, to trace all
475 calls to the System.String class, use:
478 mono --trace=T:System.String app.exe
481 And individual methods are referenced with the M: prefix, and the
482 standard method notation:
485 mono --trace=M:System.Console:WriteLine app.exe
488 Exceptions can also be traced, it will cause a stack trace to be
489 printed every time an exception of the specified type is thrown.
490 The exception type can be specified with or without the namespace,
491 and to trace all exceptions, specify 'all' as the type name.
494 mono --trace=E:System.Exception app.exe
497 As previously noted, various rules can be specified at once:
500 mono --trace=T:System.String,T:System.Random app.exe
503 You can exclude pieces, the next example traces calls to
504 System.String except for the System.String:Concat method.
507 mono --trace=T:System.String,-M:System.String:Concat
510 Finally, namespaces can be specified using the N: prefix:
513 mono --trace=N:System.Xml
517 \fB--no-x86-stack-align\fR
518 Don't align stack frames on the x86 architecture. By default, Mono
519 aligns stack frames to 16 bytes on x86, so that local floating point
520 and SIMD variables can be properly aligned. This option turns off the
521 alignment, which usually saves one intruction per call, but might
522 result in significantly lower floating point and SIMD performance.
525 Generate a JIT method map in a /tmp/perf-PID.map file. This file is then
526 used, for example, by the perf tool included in recent Linux kernels.
527 Each line in the file has:
530 HEXADDR HEXSIZE methodname
533 Currently this option is only supported on Linux.
534 .SH JIT MAINTAINER OPTIONS
535 The maintainer options are only used by those developing the runtime
536 itself, and not typically of interest to runtime users or developers.
539 Inserts a breakpoint before the method whose name is `method'
540 (namespace.class:methodname). Use `Main' as method name to insert a
541 breakpoint on the application's main method.
544 Inserts a breakpoint on exceptions. This allows you to debug your
545 application with a native debugger when an exception is thrown.
548 This compiles a method (namespace.name:methodname), this is used for
549 testing the compiler performance or to examine the output of the code
553 Compiles all the methods in an assembly. This is used to test the
554 compiler performance or to examine the output of the code generator
556 \fB--graph=TYPE METHOD\fR
557 This generates a postscript file with a graph with the details about
558 the specified method (namespace.name:methodname). This requires `dot'
559 and ghostview to be installed (it expects Ghostview to be called
562 The following graphs are available:
564 cfg Control Flow Graph (CFG)
566 code CFG showing code
567 ssa CFG showing code after SSA translation
568 optcode CFG showing code after IR optimizations
571 Some graphs will only be available if certain optimizations are turned
575 Instruct the runtime on the number of times that the method specified
576 by --compile (or all the methods if --compileall is used) to be
577 compiled. This is used for testing the code generator performance.
580 Displays information about the work done by the runtime during the
581 execution of an application.
583 \fB--wapi=hps|semdel\fR
584 Perform maintenance of the process shared data.
586 semdel will delete the global semaphore.
588 hps will list the currently used handles.
590 \fB-v\fR, \fB--verbose\fR
591 Increases the verbosity level, each time it is listed, increases the
592 verbosity level to include more information (including, for example,
593 a disassembly of the native code produced, code selector info etc.).
595 The Mono runtime allows external processes to attach to a running
596 process and load assemblies into the running program. To attach to
597 the process, a special protocol is implemented in the Mono.Management
600 With this support it is possible to load assemblies that have an entry
601 point (they are created with -target:exe or -target:winexe) to be
602 loaded and executed in the Mono process.
604 The code is loaded into the root domain, and it starts execution on
605 the special runtime attach thread. The attached program should
606 create its own threads and return after invocation.
608 This support allows for example debugging applications by having the
609 csharp shell attach to running processes.
611 The mono runtime includes a profiler that can be used to explore
612 various performance related problems in your application. The
613 profiler is activated by passing the --profile command line argument
614 to the Mono runtime, the format is:
617 --profile[=profiler[:profiler_args]]
620 Mono has a built-in profiler called 'default' (and is also the default
621 if no arguments are specified), but developers can write custom
622 profilers, see the section "CUSTOM PROFILERS" for more details.
626 is not specified, the default profiler is used.
630 is a profiler-specific string of options for the profiler itself.
632 The default profiler accepts the following options 'alloc' to profile
633 memory consumption by the application; 'time' to profile the time
634 spent on each routine; 'jit' to collect time spent JIT-compiling methods
635 and 'stat' to perform sample statistical profiling.
636 If no options are provided the default is 'alloc,time,jit'.
639 profile data is printed to stdout: to change this, use the 'file=filename'
640 option to output the data to filename.
645 mono --profile program.exe
649 That will run the program with the default profiler and will do time
650 and allocation profiling.
654 mono --profile=default:stat,alloc,file=prof.out program.exe
657 Will do sample statistical profiling and allocation profiling on
658 program.exe. The profile data is put in prof.out.
660 Note that the statistical profiler has a very low overhead and should
661 be the preferred profiler to use (for better output use the full path
662 to the mono binary when running and make sure you have installed the
663 addr2line utility that comes from the binutils package).
665 This is the most advanced profiler.
667 The Mono \f[I]log\f[] profiler can be used to collect a lot of
668 information about a program running in the Mono runtime.
669 This data can be used (both while the process is running and later)
670 to do analyses of the program behaviour, determine resource usage,
671 performance issues or even look for particular execution patterns.
673 This is accomplished by logging the events provided by the Mono
674 runtime through the profiling interface and periodically writing
675 them to a file which can be later inspected with the mprof-report(1)
678 More information about how to use the log profiler is available on the
679 mprof-report(1) page.
681 Mono provides a mechanism for loading other profiling modules which in
682 the form of shared libraries. These profiling modules can hook up to
683 various parts of the Mono runtime to gather information about the code
686 To use a third party profiler you must pass the name of the profiler
690 mono --profile=custom program.exe
694 In the above sample Mono will load the user defined profiler from the
695 shared library `mono-profiler-custom.so'. This profiler module must
696 be on your dynamic linker library path.
698 A list of other third party profilers is available from Mono's web
699 site (www.mono-project.com/Performance_Tips)
701 Custom profiles are written as shared libraries. The shared library
702 must be called `mono-profiler-NAME.so' where `NAME' is the name of
705 For a sample of how to write your own custom profiler look in the
706 Mono source tree for in the samples/profiler.c.
708 Mono ships with a code coverage module. This module is activated by
709 using the Mono --profile=cov option. The format is:
710 \fB--profile=cov[:assembly-name[/namespace]] test-suite.exe\fR
712 By default code coverage will default to all the assemblies loaded,
713 you can limit this by specifying the assembly name, for example to
714 perform code coverage in the routines of your program use, for example
715 the following command line limits the code coverage to routines in the
719 mono --profile=cov:demo demo.exe
725 does not include the extension.
727 You can further restrict the code coverage output by specifying a
731 mono --profile=cov:demo/My.Utilities demo.exe
735 Which will only perform code coverage in the given assembly and
738 Typical output looks like this:
741 Not covered: Class:.ctor ()
742 Not covered: Class:A ()
743 Not covered: Driver:.ctor ()
744 Not covered: Driver:method ()
745 Partial coverage: Driver:Main ()
750 The offsets displayed are IL offsets.
752 A more powerful coverage tool is available in the module `monocov'.
753 See the monocov(1) man page for details.
755 To debug managed applications, you can use the
757 command, a command line debugger.
759 It is possible to obtain a stack trace of all the active threads in
760 Mono by sending the QUIT signal to Mono, you can do this from the
761 command line, like this:
767 Where pid is the Process ID of the Mono process you want to examine.
768 The process will continue running afterwards, but its state is not
772 this is a last-resort mechanism for debugging applications and should
773 not be used to monitor or probe a production application. The
774 integrity of the runtime after sending this signal is not guaranteed
775 and the application might crash or terminate at any given point
778 The \fB--debug=casts\fR option can be used to get more detailed
779 information for Invalid Cast operations, it will provide information
780 about the types involved.
782 You can use the MONO_LOG_LEVEL and MONO_LOG_MASK environment variables
783 to get verbose debugging output about the execution of your
784 application within Mono.
788 environment variable if set, the logging level is changed to the set
789 value. Possible values are "error", "critical", "warning", "message",
790 "info", "debug". The default value is "error". Messages with a logging
791 level greater then or equal to the log level will be printed to
794 Use "info" to track the dynamic loading of assemblies.
799 environment variable to limit the extent of the messages you get:
800 If set, the log mask is changed to the set value. Possible values are
801 "asm" (assembly loader), "type", "dll" (native library loader), "gc"
802 (garbage collector), "cfg" (config file loader), "aot" (precompiler),
803 "security" (e.g. Moonlight CoreCLR support) and "all".
804 The default value is "all". Changing the mask value allows you to display only
805 messages for a certain component. You can use multiple masks by comma
806 separating them. For example to see config file messages and assembly loader
807 messages set you mask to "asm,cfg".
809 The following is a common use to track down problems with P/Invoke:
812 $ MONO_LOG_LEVEL="debug" MONO_LOG_MASK="dll" mono glue.exe
817 Mono's XML serialization engine by default will use a reflection-based
818 approach to serialize which might be slow for continuous processing
819 (web service applications). The serialization engine will determine
820 when a class must use a hand-tuned serializer based on a few
821 parameters and if needed it will produce a customized C# serializer
822 for your types at runtime. This customized serializer then gets
823 dynamically loaded into your application.
825 You can control this with the MONO_XMLSERIALIZER_THS environment
828 The possible values are
830 to disable the use of a C# customized
831 serializer, or an integer that is the minimum number of uses before
832 the runtime will produce a custom serializer (0 will produce a
833 custom serializer on the first access, 50 will produce a serializer on
834 the 50th use). Mono will fallback to an interpreted serializer if the
835 serializer generation somehow fails. This behavior can be disabled
836 by setting the option
838 (for example: MONO_XMLSERIALIZER_THS=0,nofallback).
839 .SH ENVIRONMENT VARIABLES
842 Turns off the garbage collection in Mono. This should be only used
843 for debugging purposes
846 When Mono is compiled with LLVM support, this instructs the runtime to
847 stop using LLVM after the specified number of methods are JITed.
848 This is a tool used in diagnostics to help isolate problems in the
849 code generation backend. For example \fBLLVM_COUNT=10\fR would only
850 compile 10 methods with LLVM and then switch to the Mono JIT engine.
851 \fBLLVM_COUNT=0\fR would disable the LLVM engine altogether.
854 If set, this variable will instruct Mono to ahead-of-time compile new
855 assemblies on demand and store the result into a cache in
858 \fBMONO_ASPNET_INHIBIT_SETTINGSMAP\fR
859 Mono contains a feature which allows modifying settings in the .config files shipped
860 with Mono by using config section mappers. The mappers and the mapping rules are
861 defined in the $prefix/etc/mono/2.0/settings.map file and, optionally, in the
862 settings.map file found in the top-level directory of your ASP.NET application.
863 Both files are read by System.Web on application startup, if they are found at the
864 above locations. If you don't want the mapping to be performed you can set this
865 variable in your environment before starting the application and no action will
869 If set, this variable overrides the default system configuration directory
870 ($PREFIX/etc). It's used to locate machine.config file.
873 Sets the style of COM interop. If the value of this variable is "MS"
874 Mono will use string marhsalling routines from the liboleaut32 for the
875 BSTR type library, any other values will use the mono-builtin BSTR
879 If set, this variable overrides the default runtime configuration file
880 ($PREFIX/etc/mono/config). The --config command line options overrides the
881 environment variable.
884 Override the automatic cpu detection mechanism. Currently used only on arm.
885 The format of the value is as follows:
891 where V is the architecture number 4, 5, 6, 7 and the options can be currently be
895 MONO_CPU_ARCH="armv4 thumb" mono ...
899 \fBMONO_DISABLE_AIO\fR
900 If set, tells mono NOT to attempt using native asynchronous I/O services. In
901 that case, a default select/poll implementation is used. Currently only epoll()
904 \fBMONO_DISABLE_MANAGED_COLLATION\fR
905 If this environment variable is `yes', the runtime uses unmanaged
906 collation (which actually means no culture-sensitive collation). It
907 internally disables managed collation functionality invoked via the
908 members of System.Globalization.CompareInfo class. Collation is
911 \fBMONO_DISABLE_SHM\fR
912 Unix only: If set, disables the shared memory files used for
913 cross-process handles: process have only private handles. This means
914 that process and thread handles are not available to other processes,
915 and named mutexes, named events and named semaphores are not visible
918 This is can also be enabled by default by passing the
919 "--disable-shared-handles" option to configure.
921 This is the default from mono 2.8 onwards.
923 \fBMONO_EGD_SOCKET\fR
924 For platforms that do not otherwise have a way of obtaining random bytes
925 this can be set to the name of a file system socket on which an egd or
926 prngd daemon is listening.
928 \fBMONO_ENABLE_SHM\fR
929 Unix only: Enable support for cross-process handles. Cross-process
930 handles are used to expose process handles, thread handles, named
931 mutexes, named events and named semaphores across Unix processes.
933 \fBMONO_ENV_OPTIONS\fR
934 This environment variable allows you to pass command line arguments to
935 a Mono process through the environment. This is useful for example
936 to force all of your Mono processes to use LLVM or SGEN without having
937 to modify any launch scripts.
939 \fBMONO_EVENTLOG_TYPE\fR
940 Sets the type of event log provider to use (for System.Diagnostics.EventLog).
947 Persists event logs and entries to the local file system.
949 The directory in which to persist the event logs, event sources and entries
950 can be specified as part of the value.
952 If the path is not explicitly set, it defaults to "/var/lib/mono/eventlog"
953 on unix and "%APPDATA%\mono\eventlog" on Windows.
958 Uses the native win32 API to write events and registers event logs and
959 event sources in the registry. This is only available on Windows.
961 On Unix, the directory permission for individual event log and event source
962 directories is set to 777 (with +t bit) allowing everyone to read and write
963 event log entries while only allowing entries to be deleted by the user(s)
968 Silently discards any events.
971 The default is "null" on Unix (and versions of Windows before NT), and
972 "win32" on Windows NT (and higher).
975 \fBMONO_EXTERNAL_ENCODINGS\fR
976 If set, contains a colon-separated list of text encodings to try when
977 turning externally-generated text (e.g. command-line arguments or
978 filenames) into Unicode. The encoding names come from the list
979 provided by iconv, and the special case "default_locale" which refers
980 to the current locale's default encoding.
982 When reading externally-generated text strings UTF-8 is tried first,
983 and then this list is tried in order with the first successful
984 conversion ending the search. When writing external text (e.g. new
985 filenames or arguments to new processes) the first item in this list
986 is used, or UTF-8 if the environment variable is not set.
988 The problem with using MONO_EXTERNAL_ENCODINGS to process your
989 files is that it results in a problem: although its possible to get
990 the right file name it is not necessarily possible to open the file.
991 In general if you have problems with encodings in your filenames you
992 should use the "convmv" program.
995 When using Mono with the SGen garbage collector this variable controls
996 several parameters of the collector. The variable's value is a comma
997 separated list of words.
1001 \fBnursery-size=\fIsize\fR
1002 Sets the size of the nursery. The size is specified in bytes and must
1003 be a power of two. The suffixes `k', `m' and `g' can be used to
1004 specify kilo-, mega- and gigabytes, respectively. The nursery is the
1005 first generation (of two). A larger nursery will usually speed up the
1006 program but will obviously use more memory. The default nursery size
1009 \fBmajor=\fIcollector\fR
1010 Specifies which major collector to use. Options are `marksweep' for
1011 the Mark&Sweep collector, `marksweep-par' for parallel Mark&Sweep,
1012 `marksweep-fixed' for Mark&Sweep with a fixed heap,
1013 `marksweep-fixed-par' for parallel Mark&Sweep with a fixed heap and
1014 `copying' for the copying collector. The Mark&Sweep collector is the
1017 \fBmajor-heap-size=\fIsize\fR
1018 Sets the size of the major heap (not including the large object space)
1019 for the fixed-heap Mark&Sweep collector (i.e. `marksweep-fixed' and
1020 `marksweep-fixed-par'). The size is in bytes, with optional suffixes
1021 `k', `m' and `g' to specify kilo-, mega- and gigabytes, respectively.
1022 The default is 512 megabytes.
1024 \fBwbarrier=\fIwbarrier\fR
1025 Specifies which write barrier to use. Options are `cardtable' and
1026 `remset'. The card table barrier is faster but less precise, and only
1027 supported for the Mark&Sweep major collector on 32 bit platforms. The
1028 default is `cardtable' if it is supported, otherwise `remset'. The cardtable
1029 write barrier is faster and has a more stable and usually smaller
1030 memory footprint. If the program causes too much pinning during
1031 thread scan, it might be faster to enable remset.
1033 \fBevacuation-threshold=\fIthreshold\fR
1034 Sets the evacuation threshold in percent. This option is only available
1035 on the Mark&Sweep major collectors. The value must be an
1036 integer in the range 0 to 100. The default is 66. If the sweep phase of
1037 the collection finds that the occupancy of a specific heap block type is
1038 less than this percentage, it will do a copying collection for that block
1039 type in the next major collection, thereby restoring occupancy to close
1040 to 100 percent. A value of 0 turns evacuation off.
1042 \fB(no-)concurrent-sweep\fR
1043 Enables or disables concurrent sweep for the Mark&Sweep collector. If
1044 enabled, the sweep phase of the garbage collection is done in a thread
1045 concurrently with the application. Concurrent sweep is disabled by
1048 \fBstack-mark=\fImark-mode\fR
1049 Specifies how application threads should be scanned. Options are
1050 `precise` and `conservative`. Precise marking allow the collector
1051 to know what values on stack are references and what are not.
1052 Conservative marking threats all values as potentially references
1053 and leave them untouched. Precise marking reduces floating garbage
1054 and can speed up nursery collection and allocation rate, it has
1055 the downside of requiring a significant extra memory per compiled
1056 method. The right option, unfortunately, requires experimentation.
1061 When using Mono with the SGen garbage collector this environment
1062 variable can be used to turn on various debugging features of the
1063 collector. The value of this variable is a comma separated list of
1064 words. Do not use these options in production.
1069 Sets the debug level to the specified number.
1071 \fBcollect-before-allocs\fR
1073 \fBcheck-at-minor-collections\fR
1074 This performs a consistency check on minor collections and also clears
1075 the nursery at collection time, instead of the default, when buffers
1076 are allocated (clear-at-gc). The consistency check ensures that
1077 there are no major to minor references that are not on the remembered
1080 \fBxdomain-checks\fR
1081 Performs a check to make sure that no references are left to an
1085 This clears the nursery at GC time instead of doing it when the thread
1086 local allocation buffer (TLAB) is created. The default is to clear
1087 the nursery at TLAB creation time.
1090 Don't do minor collections. If the nursery is full, a major collection
1091 is triggered instead, unless it, too, is disabled.
1094 Don't do major collections.
1096 \fBconservative-stack-mark\fR
1097 Forces the GC to scan the stack conservatively, even if precise
1098 scanning is available.
1100 \fBcheck-scan-starts\fR
1101 If set, does a plausibility check on the scan_starts before and after each collection
1103 \fBheap-dump=\fIfile\fR
1104 Dumps the heap contents to the specified file. To visualize the
1105 information, use the mono-heapviz tool.
1107 \fBbinary-protocol=\fIfile\fR
1108 Outputs the debugging output to the specified file. For this to
1109 work, Mono needs to be compiled with the BINARY_PROTOCOL define on
1110 sgen-gc.c. You can then use this command to explore the output
1112 sgen-grep-binprot 0x1234 0x5678 < file
1117 \fBMONO_GAC_PREFIX\fR
1118 Provides a prefix the runtime uses to look for Global Assembly Caches.
1119 Directories are separated by the platform path separator (colons on
1120 unix). MONO_GAC_PREFIX should point to the top directory of a prefixed
1121 install. Or to the directory provided in the gacutil /gacdir command. Example:
1122 .B /home/username/.mono:/usr/local/mono/
1125 Enables some filename rewriting support to assist badly-written
1126 applications that hard-code Windows paths. Set to a colon-separated
1127 list of "drive" to strip drive letters, or "case" to do
1128 case-insensitive file matching in every directory in a path. "all"
1129 enables all rewriting methods. (Backslashes are always mapped to
1130 slashes if this variable is set to a valid option).
1133 For example, this would work from the shell:
1136 MONO_IOMAP=drive:case
1140 If you are using mod_mono to host your web applications, you can use
1143 directive instead, like this:
1146 MonoIOMAP <appalias> all
1149 See mod_mono(8) for more details.
1151 Additionally. Mono includes a profiler module which allows one to track what
1152 adjustements to file paths IOMAP code needs to do. The tracking code reports
1153 the managed location (full stack trace) from which the IOMAP-ed call was made and,
1154 on process exit, the locations where all the IOMAP-ed strings were created in
1155 managed code. The latter report is only approximate as it is not always possible
1156 to estimate the actual location where the string was created. The code uses simple
1157 heuristics - it analyzes stack trace leading back to the string allocation location
1158 and ignores all the managed code which lives in assemblies installed in GAC as well as in the
1159 class libraries shipped with Mono (since they are assumed to be free of case-sensitivity
1160 issues). It then reports the first location in the user's code - in most cases this will be
1161 the place where the string is allocated or very close to the location. The reporting code
1162 is implemented as a custom profiler module (see the "PROFILING" section) and can be loaded
1163 in the following way:
1168 mono --profile=iomap yourapplication.exe
1171 Note, however, that Mono currently supports only one profiler module
1175 When Mono is using the LLVM code generation backend you can use this
1176 environment variable to pass code generation options to the LLVM
1179 \fBMONO_MANAGED_WATCHER\fR
1180 If set to "disabled", System.IO.FileSystemWatcher will use a file watcher
1181 implementation which silently ignores all the watching requests.
1182 If set to any other value, System.IO.FileSystemWatcher will use the default
1183 managed implementation (slow). If unset, mono will try to use inotify, FAM,
1184 Gamin, kevent under Unix systems and native API calls on Windows, falling
1185 back to the managed implementation on error.
1187 \fBMONO_MESSAGING_PROVIDER\fR
1188 Mono supports a plugin model for its implementation of System.Messaging making
1189 it possible to support a variety of messaging implementations (e.g. AMQP, ActiveMQ).
1190 To specify which messaging implementation is to be used the evironement variable
1191 needs to be set to the full class name for the provider. E.g. to use the RabbitMQ based
1192 AMQP implementation the variable should be set to:
1195 Mono.Messaging.RabbitMQ.RabbitMQMessagingProvider,Mono.Messaging.RabbitMQ
1198 If set causes the mono process to be bound to a single processor. This may be
1199 useful when debugging or working around race conditions.
1202 Disable inlining of thread local accesses. Try setting this if you get a segfault
1203 early on in the execution of mono.
1206 Provides a search path to the runtime where to look for library
1207 files. This is a tool convenient for debugging applications, but
1208 should not be used by deployed applications as it breaks the assembly
1209 loader in subtle ways.
1211 Directories are separated by the platform path separator (colons on unix). Example:
1212 .B /home/username/lib:/usr/local/mono/lib
1214 Alternative solutions to MONO_PATH include: installing libraries into
1215 the Global Assembly Cache (see gacutil(1)) or having the dependent
1216 libraries side-by-side with the main executable.
1218 For a complete description of recommended practices for application
1220 http://www.mono-project.com/Guidelines:Application_Deployment
1223 Experimental RTC support in the statistical profiler: if the user has
1224 the permission, more accurate statistics are gathered. The MONO_RTC
1225 value must be restricted to what the Linux rtc allows: power of two
1226 from 64 to 8192 Hz. To enable higher frequencies like 4096 Hz, run as root:
1229 echo 4096 > /proc/sys/dev/rtc/max-user-freq
1236 MONO_RTC=4096 mono --profiler=default:stat program.exe
1240 \fBMONO_SHARED_DIR\fR
1241 If set its the directory where the ".wapi" handle state is stored.
1242 This is the directory where the Windows I/O Emulation layer stores its
1243 shared state data (files, events, mutexes, pipes). By default Mono
1244 will store the ".wapi" directory in the users's home directory.
1246 \fBMONO_SHARED_HOSTNAME\fR
1247 Uses the string value of this variable as a replacement for the host name when
1248 creating file names in the ".wapi" directory. This helps if the host name of
1249 your machine is likely to be changed when a mono application is running or if
1250 you have a .wapi directory shared among several different computers.
1252 Mono typically uses the hostname to create the files that are used to
1253 share state across multiple Mono processes. This is done to support
1254 home directories that might be shared over the network.
1256 \fBMONO_STRICT_IO_EMULATION\fR
1257 If set, extra checks are made during IO operations. Currently, this
1258 includes only advisory locks around file writes.
1261 The name of the theme to be used by Windows.Forms. Available themes today
1262 include "clearlooks", "nice" and "win32".
1264 The default is "win32".
1266 \fBMONO_TLS_SESSION_CACHE_TIMEOUT\fR
1267 The time, in seconds, that the SSL/TLS session cache will keep it's entry to
1268 avoid a new negotiation between the client and a server. Negotiation are very
1269 CPU intensive so an application-specific custom value may prove useful for
1270 small embedded systems.
1272 The default is 180 seconds.
1274 \fBMONO_THREADS_PER_CPU\fR
1275 The maximum number of threads in the general threadpool will be
1276 20 + (MONO_THREADS_PER_CPU * number of CPUs). The default value for this
1279 \fBMONO_XMLSERIALIZER_THS\fR
1280 Controls the threshold for the XmlSerializer to produce a custom
1281 serializer for a given class instead of using the Reflection-based
1282 interpreter. The possible values are `no' to disable the use of a
1283 custom serializer or a number to indicate when the XmlSerializer
1284 should start serializing. The default value is 50, which means that
1285 the a custom serializer will be produced on the 50th use.
1287 \fBMONO_X509_REVOCATION_MODE\fR
1288 Sets the revocation mode used when validating a X509 certificate chain (https,
1289 ftps, smtps...). The default is 'nocheck', which performs no revocation check
1290 at all. The other possible values are 'offline', which performs CRL check (not
1291 implemented yet) and 'online' which uses OCSP and CRL to verify the revocation
1292 status (not implemented yet).
1293 .SH ENVIRONMENT VARIABLES FOR DEBUGGING
1295 \fBMONO_ASPNET_NODELETE\fR
1296 If set to any value, temporary source files generated by ASP.NET support
1297 classes will not be removed. They will be kept in the user's temporary
1301 If set, enables some features of the runtime useful for debugging.
1302 This variable should contain a comma separated list of debugging options.
1303 Currently, the following options are supported:
1307 \fBbreak-on-unverified\fR
1308 If this variable is set, when the Mono VM runs into a verification
1309 problem, instead of throwing an exception it will break into the
1310 debugger. This is useful when debugging verifier problems
1313 This option can be used to get more detailed information from
1314 InvalidCast exceptions, it will provide information about the types
1317 \fBcollect-pagefault-stats\fR
1318 Collects information about pagefaults. This is used internally to
1319 track the number of page faults produced to load metadata. To display
1320 this information you must use this option with "--stats" command line
1323 \fBdont-free-domains\fR
1324 This is an Optimization for multi-AppDomain applications (most
1325 commonly ASP.NET applications). Due to internal limitations Mono,
1326 Mono by default does not use typed allocations on multi-appDomain
1327 applications as they could leak memory when a domain is unloaded.
1329 Although this is a fine default, for applications that use more than
1330 on AppDomain heavily (for example, ASP.NET applications) it is worth
1331 trading off the small leaks for the increased performance
1332 (additionally, since ASP.NET applications are not likely going to
1333 unload the application domains on production systems, it is worth
1334 using this feature).
1336 \fBdyn-runtime-invoke\fR
1337 Instructs the runtime to try to use a generic runtime-invoke wrapper
1338 instead of creating one invoke wrapper.
1341 Equivalent to setting the \fBMONO_XDEBUG\fR variable, this emits
1342 symbols into a shared library as the code is JITed that can be loaded
1343 into GDB to inspect symbols.
1345 \fBgen-seq-points\fR
1346 Automatically generates sequence points where the
1347 IL stack is empty. These are places where the debugger can set a
1350 \fBexplicit-null-checks\fR
1351 Makes the JIT generate an explicit NULL check on variable dereferences
1352 instead of depending on the operating system to raise a SIGSEGV or
1353 another form of trap event when an invalid memory location is
1357 Captures the interrupt signal (Control-C) and displays a stack trace
1358 when pressed. Useful to find out where the program is executing at a
1359 given point. This only displays the stack trace of a single thread.
1362 Instructs the runtime to initialize the stack with
1363 some known values (0x2a on x86-64) at the start of a method to assist
1364 in debuggin the JIT engine.
1366 \fBkeep-delegates\fR
1367 This option will leak delegate trampolines that are no longer
1368 referenced as to present the user with more information about a
1369 delegate misuse. Basically a delegate instance might be created,
1370 passed to unmanaged code, and no references kept in managed code,
1371 which will garbage collect the code. With this option it is possible
1372 to track down the source of the problems.
1374 \fBreverse-pinvoke-exceptions
1375 This option will cause mono to abort with a descriptive message when
1376 during stack unwinding after an exception it reaches a native stack
1377 frame. This happens when a managed delegate is passed to native code,
1378 and the managed delegate throws an exception. Mono will normally try
1379 to unwind the stack to the first (managed) exception handler, and it
1380 will skip any native stack frames in the process. This leads to
1381 undefined behaviour (since mono doesn't know how to process native
1382 frames), leaks, and possibly crashes too.
1384 \fBno-gdb-backtrace\fR
1385 This option will disable the GDB backtrace emitted by the runtime
1386 after a SIGSEGV or SIGABRT in unmanaged code.
1388 \fBsuspend-on-sigsegv\fR
1389 This option will suspend the program when a native SIGSEGV is received.
1390 This is useful for debugging crashes which do not happen under gdb,
1391 since a live process contains more information than a core file.
1395 \fBMONO_LOG_LEVEL\fR
1396 The logging level, possible values are `error', `critical', `warning',
1397 `message', `info' and `debug'. See the DEBUGGING section for more
1401 Controls the domain of the Mono runtime that logging will apply to.
1402 If set, the log mask is changed to the set value. Possible values are
1403 "asm" (assembly loader), "type", "dll" (native library loader), "gc"
1404 (garbage collector), "cfg" (config file loader), "aot" (precompiler),
1405 "security" (e.g. Moonlight CoreCLR support) and "all".
1406 The default value is "all". Changing the mask value allows you to display only
1407 messages for a certain component. You can use multiple masks by comma
1408 separating them. For example to see config file messages and assembly loader
1409 messages set you mask to "asm,cfg".
1412 Used for runtime tracing of method calls. The format of the comma separated
1421 disabled Trace output off upon start.
1424 You can toggle trace output on/off sending a SIGUSR2 signal to the program.
1426 \fBMONO_TRACE_LISTENER\fR
1427 If set, enables the System.Diagnostics.DefaultTraceListener, which will
1428 print the output of the System.Diagnostics Trace and Debug classes.
1429 It can be set to a filename, and to Console.Out or Console.Error to display
1430 output to standard output or standard error, respectively. If it's set to
1431 Console.Out or Console.Error you can append an optional prefix that will
1432 be used when writing messages like this: Console.Error:MyProgramName.
1433 See the System.Diagnostics.DefaultTraceListener documentation for more
1436 \fBMONO_WCF_TRACE\fR
1437 This eases WCF diagnostics functionality by simply outputs all log messages from WCF engine to "stdout", "stderr" or any file passed to this environment variable. The log format is the same as usual diagnostic output.
1439 \fBMONO_XEXCEPTIONS\fR
1440 This throws an exception when a X11 error is encountered; by default a
1441 message is displayed but execution continues
1443 \fBMONO_XMLSERIALIZER_DEBUG\fR
1444 Set this value to 1 to prevent the serializer from removing the
1445 temporary files that are created for fast serialization; This might
1446 be useful when debugging.
1449 This is used in the System.Windows.Forms implementation when running
1450 with the X11 backend. This is used to debug problems in Windows.Forms
1451 as it forces all of the commands send to X11 server to be done
1452 synchronously. The default mode of operation is asynchronous which
1453 makes it hard to isolate the root of certain problems.
1455 \fBMONO_GENERIC_SHARING\fR
1456 This environment variable controls the kind of generic sharing used.
1457 This variable is used by internal JIT developers and should not be
1458 changed in production. Do not use it.
1460 The variable controls which classes will have generic code sharing
1463 Permissible values are:
1467 All generated code can be shared.
1470 Only the classes in System.Collections.Generic will have its code
1471 shared (this is the default value).
1474 Only code in corlib will have its code shared.
1477 No generic code sharing will be performed.
1480 Generic code sharing by default only applies to collections. The
1481 Mono JIT by default turns this on.
1484 When the the MONO_XDEBUG env var is set, debugging info for JITted
1485 code is emitted into a shared library, loadable into gdb. This enables,
1486 for example, to see managed frame names on gdb backtraces.
1488 \fBMONO_VERBOSE_METHOD\fR
1489 Enables the maximum JIT verbosity for the specified method. This is
1490 very helpfull to diagnose a miscompilation problems of a specific
1493 If you want to use Valgrind, you will find the file `mono.supp'
1494 useful, it contains the suppressions for the GC which trigger
1495 incorrect warnings. Use it like this:
1497 valgrind --suppressions=mono.supp mono ...
1500 On some platforms, Mono can expose a set of DTrace probes (also known
1501 as user-land statically defined, USDT Probes).
1503 They are defined in the file `mono.d'.
1505 .B ves-init-begin, ves-init-end
1507 Begin and end of runtime initialization.
1509 .B method-compile-begin, method-compile-end
1511 Begin and end of method compilation.
1512 The probe arguments are class name, method name and signature,
1513 and in case of method-compile-end success or failure of compilation.
1517 Begin and end of Garbage Collection.
1519 To verify the availability of the probes, run:
1521 dtrace -P mono'$target' -l -c mono
1524 Mono's Ping implementation for detecting network reachability can
1525 create the ICMP packets itself without requiring the system ping
1526 command to do the work. If you want to enable this on Linux for
1527 non-root users, you need to give the Mono binary special permissions.
1529 As root, run this command:
1531 # setcap cap_net_raw=+ep /usr/bin/mono
1534 On Unix assemblies are loaded from the installation lib directory. If you set
1535 `prefix' to /usr, the assemblies will be located in /usr/lib. On
1536 Windows, the assemblies are loaded from the directory where mono and
1539 .B ~/.mono/aot-cache
1541 The directory for the ahead-of-time compiler demand creation
1542 assemblies are located.
1544 .B /etc/mono/config, ~/.mono/config
1546 Mono runtime configuration file. See the mono-config(5) manual page
1547 for more information.
1549 .B ~/.config/.mono/certs, /usr/share/.mono/certs
1551 Contains Mono certificate stores for users / machine. See the certmgr(1)
1552 manual page for more information on managing certificate stores and
1553 the mozroots(1) page for information on how to import the Mozilla root
1554 certificates into the Mono certificate store.
1556 .B ~/.mono/assemblies/ASSEMBLY/ASSEMBLY.config
1558 Files in this directory allow a user to customize the configuration
1559 for a given system assembly, the format is the one described in the
1560 mono-config(5) page.
1562 .B ~/.config/.mono/keypairs, /usr/share/.mono/keypairs
1564 Contains Mono cryptographic keypairs for users / machine. They can be
1565 accessed by using a CspParameters object with DSACryptoServiceProvider
1566 and RSACryptoServiceProvider classes.
1568 .B ~/.config/.isolatedstorage, ~/.local/share/.isolatedstorage, /usr/share/.isolatedstorage
1570 Contains Mono isolated storage for non-roaming users, roaming users and
1571 local machine. Isolated storage can be accessed using the classes from
1572 the System.IO.IsolatedStorage namespace.
1574 .B <assembly>.config
1576 Configuration information for individual assemblies is loaded by the
1577 runtime from side-by-side files with the .config files, see the
1578 http://www.mono-project.com/Config for more information.
1580 .B Web.config, web.config
1582 ASP.NET applications are configured through these files, the
1583 configuration is done on a per-directory basis. For more information
1584 on this subject see the http://www.mono-project.com/Config_system.web
1587 Mailing lists are listed at the
1588 http://www.mono-project.com/Mailing_Lists
1590 http://www.mono-project.com
1593 certmgr(1), csharp(1), mcs(1), mdb(1), monocov(1), monodis(1),
1594 mono-config(5), mozroots(1), mprof-report(1), pdb2mdb(1), xsp(1), mod_mono(8).
1596 For more information on AOT:
1597 http://www.mono-project.com/AOT
1599 For ASP.NET-related documentation, see the xsp(1) manual page