[Tom Almy comments: The program did not correctly handle RETURN (as reported by Martin Glanvill, mcg@waikato.ac.nz). In the process of fixing the problem it was discovered that the nexting printout did not work properly for all return, return-from, throw, and many cases of go. This version has been fixed for hopefully all of the above, although go will still not produce proper printout if the jump is outside the most enclosing tagbody, and the tag arguments of catch/throw must either be symbols or quoted symbols. I'm making no attempt here to correctly handle tracing of unwind-protect, either! Tom Almy 5/92 ] This is the latest version of my stepper. I posted an early version of it about a year ago; this differs from the old one as follows: o May change both print depth and print length of forms (old version only allowed print depth to be changed) o Uses 'get-key' for user input, (in particular this is PC specific, I only use XLISP on PC's; I use KCL on real computers) o New 'u' command (execute until enclosing form returns) o New 'r' command (use a given expression as the return value for the current form) o Correct handling of '(go label)' statements o Uses *debug-io* to determine output stream The attached listing is a step debugger inspired by the "step.lsp" stepper included with XLISP 2.1, originally written by Jonathan Engdahl (jengdahl on BIX). This version has the ability to set/reset breakpoints, and a few bells and whistles. To invoke the stepper: (step (form with args)) The stepper will stop and print every form, then wait for user input. Forms are printed compressed, i.e. to a depth and length of 3. This may be changed by assigning the desired depth and length values to *pdepth* and *plen* before invoking the stepper, or from within the stepper via the . and # commands. For example, suppose you have the following defined: (defun fib (n) (if (or (eql n 1) (eql n 2)) 1 (+ (fib (- n 2)) (fib (- n 1))))) Then (step (fib 4)) will produce the following: 0 >==> (fib 4) 1 >==> (if (or (eql n 1) (eql n 2)) 1 ...) : The colon is the stepper's prompt. For a list of commands, type h. this produces: Stepper Commands ---------------- n or space - next form s or - step over form f FUNCTION - go until FUNCTION is called b FUNCTION - set breakpoint at FUNCTION b - set breakpoint at each function in list c FUNCTION - clear breakpoint at FUNCTION c - clear breakpoint at each function in list c *all* - clear all breakpoints g - go until a breakpoint is reached u - go up; continue until enclosing form is done w - where am I? -- backtrace t - toggle trace on/off q - quit stepper, continue execution p - pretty-print current form (uncompressed) e - print environment x - execute expression in current environment r - execute and return expression # nn - set print depth to nn . nn - set print length to nn h - print this summary Breakpoints may be set with the b command. You may set breakpoints at one function, e.g. b FOO sets a breakpoint at the function FOO, or at various functions at once, e.g. b (FOO FIE FUM) sets breakpoints at the functions FOO, FIE, and FUM. Breakpoints are cleared with the c command in an analogous way. Furthermore, a special form of the c command, c *all* , clears all previously set breakpoints. Breakpoints are remembered from one invocation of step to the next, so it is only neccessary to set them once in a debugging session. The g command causes execution to proceed until a breakpoint is reached, at which time more stepper commands can be entered. The f command sets a temporary breakpoint at one function, and causes execution to proceed until that function is called. The u command continues execution until the form enlosing the current form is done, then re-enters the stepper. The w command prints a back trace. The q command quits and causes execution to continue uninterrupted. Entry and exit to functions are traced after a g, f, u, or q command. To turn off tracing, use the t command which toggles the trace on/off. Also, with trace off, the values of function parameters are not printed. The s command causes the current form to be evaluated. The n command steps into the current form. The . and # commands change the compression of displayed forms. E.g. in the previous example: 1 >==> (if (or (eql n 1) (eql n 2)) 1 ...) : . 2 1 >==> (if (or (eql n ...) ...) ...) : changes the print length to 2, and 1 >==> (if (or (eql n ...) ...) ...) : # 2 1 >==> (if (or #\# ...) ...) : changes the print depth to 2. To print the entire form use the p command, which pretty-prints the entire form. The e command causes the current environment to be printed; The x command causes an expression to be executed in the current environment. Note that this permits the user to alter values while the program is running, and may affect execution of the program. The r command causes the value of the given expression to be returned, i.e. makes it the return value of the current form. Enjoy, Ray