Difference between revisions of "DDT"
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== Command list for the MOS portable DDT == | == Command list for the MOS portable DDT == | ||
− | In the list below, '$' means the [[ASCII]] character 'ESCAPE' (i.e. | + | In the list below, '$' means the [[ASCII]] character 'ESCAPE' (i.e. CTRL-[). This command set was derived from, but not identical to, those of the originals. |
<pre> | <pre> |
Revision as of 01:52, 8 October 2019
DDT (Dynamic Debugging Technique - the name is a 'backronym' on the insecticide) is a family of debuggers with some common characteristics:
- Most commands are invoked with a single key, plus modifiers.
- Altmode or Escape is used as a prefix modifier.
- Arguments are commonly prefixed to the command.
DDT was first implemented at MIT for a PDP-1 computer. It was then implemented for PDP-6, -10, and -11 computers at MIT. It was also widely used at DEC.
Contents
Implementations
Implementations found on ITS
- Exec DDT, also known as NTS DDT, for the PDP-6 and 10.
- Timesharing DDT for the PDP-6 and 10.
- KLDDT specifically for the KL10.
- RUG for the PDP-11.
- URUG, or micro RUG, for the GT40.
- KLRUG for the KL10 front end.
- 11DDT for the PDP-11.
- CARPET remote PDP-11 debugger hosted on a PDP-10.
- HALI target resident counterpart to CARPET.
- MAT resident debugger for PDP-11.
- Timesharing DDT for SITS.
- IMDDT for Imlac PDS-1.
DEC implementations
Implementations under MOS
The original debugger used with the MOS operating system was a DDT written in PDP-11 assembly language (like the OS itself); it is not known if that was written from scratch, or came from elsewhere.
Later, a version was written in portable C, and used with MOS (similarly re-written) the on PDP-11's, various Motorola M68000 Family machines, and AMD 29000 machines.
Command list for the MOS portable DDT
In the list below, '$' means the ASCII character 'ESCAPE' (i.e. CTRL-[). This command set was derived from, but not identical to, those of the originals.
n/ Open loc n, type contents in current mode / Retype loc pointed to by last address n<CR> Modify currently opened loc to be n, close loc <CR> Reset modes, go to command level n<LF> Modify, close, open next loc <LF> Advance to next item and display n^ Modify, close, open previous loc ^ Reverse to previous item n<TAB> Modify, close, open loc pointed to by last typed value <TAB> Open loc pointed to by last typed value @ Synonym for <TAB> n_ Open location n, type as instr _ Set temporary mode to instr, retype location n{ Open location n, type as a numeric { Set temporary mode to numeric, retype location n[ Open location n, type as symbolic [ Set temporary mode to symbolic, retype location n! Open location n, don't type n= Type value as numeric = Retype value as numeric n\ Examine display block at n \ Examine display block pointed to by last address $A Addresses will be typed as absolute numbers $R Addresses will be typed relative to symbols $I Change current mode to instruction type out $N Change current mode to numeric type out $S Change current mode to symbolic type out $T Change current mode to ASCII text output $Z Change current mode/length to .ASCIZ $H Change to halfword (byte) mode $W Change to (short)word mode $L Change to longword mode $mI Change current input radix to m $mO Change current output radix to m $mR Change input and output radix $mD Change current display block size Note that the initial modes are $S and $W. These can be temporarily changed by the above commands and will return to the permanent setting by a carriage return. The settings can be permanently changed by using two altmodes in the mode setting command (e.g. $$T sets permanent ASCII mode) $mS Change maximum symbol offset This mode is 'permanent' i.e. once set, it stays at that value. n$iM Set machine dependant mode i to n. The actual argument syntax may vary from machine to machine. n$iB Set breakpoint i at address n (i from 0 to 7 or can be omitted) $iB Remove breakpoint i $B Remove all breakpoints $V List (view) all breakpoints Note that breakpoints should only be set at the start of extended instructions. Setting a breakpoint in the middle of an instruction will cause undefined randomness. % $P Proceed from breakpoint % m$P Proceed from breakpoint m times (without halting) % ^P Single step the processor % n^P Single step n times (without halting) % ^X 'Execute' step the processor - treats JSR as an atomic % n^X Execute step n times (without halting) % $G Start execution at address in JOBSA (start of program) % n$G Start executing program at location n. Commands marked with a '%' can be executed only in the hard-core debugger with the [operating system] halted. Numbers 'm' may be typed either before or after the '$'; numbers 'n' or 'i' must be typed where shown. Where a value is called for, if the value is typed before the '$' (if any), the value may be typed as a string of tokens, which may be either numbers or known symbols (i.e. findable in the DDT symbol table) separated by operators; the available operators are +, - and *. If the value is typed after the '$' only a single number may be used; these are read in decimal unless preceeded by a 0.