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164 lines
6.8 KiB
Plaintext
164 lines
6.8 KiB
Plaintext
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@node Convex,,, Top
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@appendix Convex-specific info
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@cindex Convex notes
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Scalar registers are 64 bits long, which is a pain since
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left half of an S register frequently contains noise.
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Therefore there are two ways to obtain the value of an S register.
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@table @kbd
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@item $s0
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returns the low half of the register as an int
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@item $S0
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returns the whole register as a long long
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@end table
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You can print the value in floating point by using @samp{p/f $s0} or @samp{p/f $S0}
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to print a single or double precision value.
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@cindex vector registers
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Vector registers are handled similarly, with @samp{$V0} denoting the whole
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64-bit register and @kbd{$v0} denoting the 32-bit low half; @samp{p/f $v0}
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or @samp{p/f $V0} can be used to examine the register in floating point.
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The length of the vector registers is taken from @samp{$vl}.
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Individual elements of a vector register are denoted in the obvious way;
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@samp{print $v3[9]} prints the tenth element of register @kbd{v3}, and
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@samp{set $v3[9] = 1234} alters it.
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@kbd{$vl} and @kbd{$vs} are int, and @kbd{$vm} is an int vector.
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Elements of @kbd{$vm} can't be assigned to.
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@cindex communication registers
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@kindex info comm-registers
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Communication registers have names @kbd{$C0 .. $C63}, with @kbd{$c0 .. $c63}
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denoting the low-order halves. @samp{info comm-registers} will print them
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all out, and tell which are locked. (A communication register is
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locked when a value is sent to it, and unlocked when the value is
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received.) Communication registers are, of course, global to all
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threads, so it does not matter what the currently selected thread is.
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@samp{info comm-reg @var{name}} prints just that one communication
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register; @samp{name} may also be a communication register number
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@samp{nn} or @samp{0xnn}.
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@samp{info comm-reg @var{address}} prints the contents of the resource
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structure at that address.
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@kindex info psw
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The command @samp{info psw} prints the processor status word @kbd{$ps}
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bit by bit.
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@kindex set base
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GDB normally prints all integers in base 10, but the leading
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@kbd{0x80000000} of pointers is intolerable in decimal, so the default
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output radix has been changed to try to print addresses appropriately.
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The @samp{set base} command can be used to change this.
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@table @code
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@item set base 10
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Integer values always print in decimal.
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@item set base 16
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Integer values always print in hex.
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@item set base
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Go back to the initial state, which prints integer values in hex if they
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look like pointers (specifically, if they start with 0x8 or 0xf in the
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stack), otherwise in decimal.
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@end table
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@kindex set pipeline
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When an exception such as a bus error or overflow happens, usually the PC
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is several instructions ahead by the time the exception is detected.
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The @samp{set pipe} command will disable this.
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@table @code
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@item set pipeline off
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Forces serial execution of instructions; no vector chaining and no
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scalar instruction overlap. With this, exceptions are detected with
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the PC pointing to the instruction after the one in error.
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@item set pipeline on
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Returns to normal, fast, execution. This is the default.
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@end table
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@cindex parallel
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In a parallel program, multiple threads may be executing, each
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with its own registers, stack, and local memory. When one of them
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hits a breakpoint, that thread is selected. Other threads do
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not run while the thread is in the breakpoint.
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@kindex 1cont
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The selected thread can be single-stepped, given signals, and so
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on. Any other threads remain stopped. When a @samp{cont} command is given,
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all threads are resumed. To resume just the selected thread, use
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the command @samp{1cont}.
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@kindex thread
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The @samp{thread} command will show the active threads and the
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instruction they are about to execute. The selected thread is marked
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with an asterisk. The command @samp{thread @var{n}} will select thread @var{n},
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shifting the debugger's attention to it for single-stepping,
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registers, local memory, and so on.
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@kindex info threads
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The @samp{info threads} command will show what threads, if any, have
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invisibly hit breakpoints or signals and are waiting to be noticed.
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@kindex set parallel
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The @samp{set parallel} command controls how many threads can be active.
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@table @code
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@item set parallel off
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One thread. Requests by the program that other threads join in
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(spawn and pfork instructions) do not cause other threads to start up.
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This does the same thing as the @samp{limit concurrency 1} command.
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@item set parallel fixed
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All CPUs are assigned to your program whenever it runs. When it
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executes a pfork or spawn instruction, it begins parallel execution
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immediately. This does the same thing as the @samp{mpa -f} command.
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@item set parallel on
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One or more threads. Spawn and pfork cause CPUs to join in when and if
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they are free. This is the default. It is very good for system
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throughput, but not very good for finding bugs in parallel code. If you
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suspect a bug in parallel code, you probably want @samp{set parallel fixed.}
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@end table
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@subsection Limitations
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WARNING: Convex GDB evaluates expressions in long long, because S
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registers are 64 bits long. However, GDB expression semantics are not
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exactly C semantics. This is a bug, strictly speaking, but it's not one I
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know how to fix. If @samp{x} is a program variable of type int, then it
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is also type int to GDB, but @samp{x + 1} is long long, as is @samp{x + y}
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or any other expression requiring computation. So is the expression
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@samp{1}, or any other constant. You only really have to watch out for
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calls. The innocuous expression @samp{list_node (0x80001234)} has an
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argument of type long long. You must explicitly cast it to int.
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It is not possible to continue after an uncaught fatal signal by using
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@samp{signal 0}, @samp{return}, @samp{jump}, or anything else. The difficulty is with
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Unix, not GDB.
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I have made no big effort to make such things as single-stepping a
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@kbd{join} instruction do something reasonable. If the program seems to
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hang when doing this, type @kbd{ctrl-c} and @samp{cont}, or use
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@samp{thread} to shift to a live thread. Single-stepping a @kbd{spawn}
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instruction apparently causes new threads to be born with their T bit set;
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this is not handled gracefully. When a thread has hit a breakpoint, other
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threads may have invisibly hit the breakpoint in the background; if you
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clear the breakpoint gdb will be surprised when threads seem to continue
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to stop at it. All of these situations produce spurious signal 5 traps;
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if this happens, just type @samp{cont}. If it becomes a nuisance, use
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@samp{handle 5 nostop}. (It will ask if you are sure. You are.)
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There is no way in GDB to store a float in a register, as with
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@kbd{set $s0 = 3.1416}. The identifier @kbd{$s0} denotes an integer,
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and like any C expression which assigns to an integer variable, the
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right-hand side is casted to type int. If you should need to do
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something like this, you can assign the value to @kbd{@{float@} ($sp-4)}
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and then do @kbd{set $s0 = $sp[-4]}. Same deal with @kbd{set $v0[69] = 6.9}.
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