On this page:
10.1 Errors
10.2 Meaning of Extort programs
10.3 A Compiler for Extort
8.6

10 Extort: when errors exist

image Source code.

The greatest mistake is to imagine that we never err.

    10.1 Errors

    10.2 Meaning of Extort programs

    10.3 A Compiler for Extort

10.1 Errors

We have added multiple, disjoint types, but mostly swept issues of errors under the rug by considering type mismatches as meaningless. Now let’s redesign the semantics to specify the error behavior of such programs.

We’ll call it Extort.

Nothing changes in the syntax of Extort from the previous language, although we will need to talk about two kinds of results from evaluating programs: values and errors. We will say that evaluation produces an answer, which is either a value or error:

image

10.2 Meaning of Extort programs

Languages adopt several approaches to type mismatches:

We’ve previously seen the last approach. Now let’s do what Racket does and signal an error.

The meaning of Extort programs that have type errors will now be defined as 'err:

There are three ways in which an error can be introduced:

image    image    image

And there are four rules for propagating errors from subexpressions:

image    image    image    image

Now what does the semantics say about (add1 #f)? What about (if 7 #t -2)?

The signature of the interpreter is extended to produce answers. Each use of a Racket primitive is guarded by checking the type of the arguments and an error is produced if the check fails. Errors are also propagated when a subexpression produces an error:

extort/interp.rkt

  #lang racket
  (provide interp)
  (require "ast.rkt" "interp-prim.rkt")
   
  ;; type Answer = Value | 'err
   
  ;; type Value =
  ;; | Integer
  ;; | Boolean
  ;; | Character
  ;; | Eof
  ;; | Void
   
  ;; Expr -> Answer
  (define (interp e)
    (match e
      [(Int i)  i]
      [(Bool b) b]
      [(Char c) c]
      [(Eof)    eof]
      [(Prim0 p)
       (interp-prim0 p)]
      [(Prim1 p e0)
       (match (interp e0)       
         ['err 'err]
         [v (interp-prim1 p v)])]
      [(If e1 e2 e3)
       (match (interp e1)
         ['err 'err]
         [v
          (if v
              (interp e2)
              (interp e3))])]
      [(Begin e1 e2)
       (match (interp e1)
         ['err 'err]
         [_ (interp e2)])]))
   

extort/interp-prim.rkt

  #lang racket
  (provide interp-prim0 interp-prim1)
   
  ;; Op0 -> Answer
  (define (interp-prim0 op)
    (match op
      ['read-byte (read-byte)]
      ['peek-byte (peek-byte)]
      ['void      (void)]))
   
  ;; Op1 Value -> Answer
  (define (interp-prim1 op v)
    (match op
      ['add1          (if (integer? v) (add1 v) 'err)]
      ['sub1          (if (integer? v) (sub1 v) 'err)]
      ['zero?         (if (integer? v) (zero? v) 'err)]
      ['char?         (char? v)]
      ['char->integer (if (char? v) (char->integer v) 'err)]
      ['integer->char (if (codepoint? v) (integer->char v) 'err)]
      ['eof-object?   (eof-object? v)]
      ['write-byte    (if (byte? v) (write-byte v) 'err)]))
   
  ;; Any -> Boolean
  (define (codepoint? v)
    (and (integer? v)
         (or (<= 0 v 55295)
             (<= 57344 v 1114111))))
   

We can confirm the interpreter computes the right result for the examples given earlier:

Examples

> (interp (Prim1 'add1 (Bool #f)))

'err

> (interp (Prim1 'zero? (Bool #t)))

'err

> (interp (If (Prim1 'zero? (Bool #f)) (Int 1) (Int 2)))

'err

The statement of correctness stays the same, but now observe that there is no way to crash the interpreter with any Expr value.

10.3 A Compiler for Extort

Suppose we want to compile (add1 #f), what needs to happen? Just as in the interpreter, we need to check the integerness of the argument’s value before doing the addition operation.

We extend the run-time system with a C function called raise_error that prints "err" and exits with a non-zero status to indicate something has gone wrong.

The runtime system is written with a level of indirection between raise_error and the code that prints and exits in error_exit; this is done so that the testing framework can intercede and replace the error function, but it can be ignored.

extort/main.c

#include <stdio.h>
#include <stdlib.h>
#include "values.h"
#include "print.h"
#include "runtime.h"

FILE* in;
FILE* out;
void (*error_handler)();

void error_exit()
{
  printf("err\n");
  exit(1);
}

void raise_error()
{
  return error_handler();
}

int main(int argc, char** argv)
{
  in = stdin;
  out = stdout;
  error_handler = &error_exit;
  
  val_t result;

  result = entry();
  print_result(result);
  if (val_typeof(result) != T_VOID)
    putchar('\n');

  return 0;
}

Most of the work of error checking happens in the code emitted for primitive operations. Whenever an error is detected, control jumps to a label called 'err that immediately calls raise_error:

extort/compile-ops.rkt

  #lang racket
  (provide (all-defined-out))
  (require "ast.rkt" "types.rkt" a86/ast)
   
  (define rax 'rax) ; return
  (define rdi 'rdi) ; arg
  (define r9  'r9)  ; scratch
   
  ;; Op0 -> Asm
  (define (compile-op0 p)
    (match p
      ['void      (seq (Mov rax (value->bits (void))))]
      ['read-byte (seq (Call 'read_byte))]
      ['peek-byte (seq (Call 'peek_byte))]))
   
  ;; Op1 -> Asm
  (define (compile-op1 p)
    (match p
      ['add1
       (seq (assert-integer rax)
            (Add rax (value->bits 1)))]
      ['sub1
       (seq (assert-integer rax)
            (Sub rax (value->bits 1)))]
      ['zero?
       (seq (assert-integer rax)
            (Cmp rax 0)
            (if-equal))]
      ['char?
       (type-pred mask-char type-char)]
      ['char->integer
       (seq (assert-char rax)
            (Sar rax char-shift)
            (Sal rax int-shift))]
      ['integer->char
       (seq (assert-codepoint)
            (Sar rax int-shift)
            (Sal rax char-shift)
            (Xor rax type-char))]
      ['eof-object? (eq-value eof)]
      ['write-byte
       (seq (assert-byte)
            (Mov rdi rax)
            (Call 'write_byte))]))
   
  
  ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
   
  (define (assert-type mask type)
    (λ (arg)
      (seq (Mov r9 arg)
           (And r9 mask)
           (Cmp r9 type)
           (Jne 'err))))
   
  (define (type-pred mask type)
    (seq (And rax mask)
         (Cmp rax type)
         (if-equal)))
   
  (define assert-integer
    (assert-type mask-int type-int))
  (define assert-char
    (assert-type mask-char type-char))
   
  (define (assert-codepoint)
    (let ((ok (gensym)))
      (seq (assert-integer rax)
           (Cmp rax (value->bits 0))
           (Jl 'err)
           (Cmp rax (value->bits 1114111))
           (Jg 'err)
           (Cmp rax (value->bits 55295))
           (Jl ok)
           (Cmp rax (value->bits 57344))
           (Jg ok)
           (Jmp 'err)
           (Label ok))))
   
  (define (assert-byte)
    (seq (assert-integer rax)
         (Cmp rax (value->bits 0))
         (Jl 'err)
         (Cmp rax (value->bits 255))
         (Jg 'err)))
   
  ;; -> Asm
  ;; set rax to #t or #f if comparison flag is equal
  (define (if-equal)
    (seq (Mov rax (value->bits #f))
         (Mov r9  (value->bits #t))
         (Cmove rax r9)))
   
  ;; Value -> Asm
  (define (eq-value v)
    (seq (Cmp rax (value->bits v))
         (if-equal)))
   

All that’s left for the top-level compile function to declare an external label 'raise_error that will be defined by the run-time system and to emit a label called 'err that calls raise_error, otherwise this part of the compiler doesn’t change:

extort/compile.rkt

  #lang racket
  (provide (all-defined-out))
  (require "ast.rkt" "types.rkt" "compile-ops.rkt" a86/ast)
   
  ;; Registers used
  (define rax 'rax) ; return
  (define rsp 'rsp) ; stack
   
  ;; Expr -> Asm
  (define (compile e)
    (prog (Extern 'peek_byte)
          (Extern 'read_byte)
          (Extern 'write_byte)
          (Extern 'raise_error)
          (Global 'entry)
          (Label 'entry)
          (Sub 'rsp 8)
          (compile-e e)
          (Add 'rsp 8)
          (Ret)
          ;; Error handler
          (Label 'err)
          (Call 'raise_error)))
   
  ;; Expr -> Asm
  (define (compile-e e)
    (match e
      [(Int i)            (compile-value i)]
      [(Bool b)           (compile-value b)]
      [(Char c)           (compile-value c)]
      [(Eof)              (compile-value eof)]
      [(Prim0 p)          (compile-prim0 p)]
      [(Prim1 p e)        (compile-prim1 p e)]
      [(If e1 e2 e3)      (compile-if e1 e2 e3)]
      [(Begin e1 e2)      (compile-begin e1 e2)]))
   
  ;; Value -> Asm
  (define (compile-value v)
    (seq (Mov rax (value->bits v))))
   
  ;; Op0 -> Asm
  (define (compile-prim0 p)
    (compile-op0 p))
   
  ;; Op1 Expr -> Asm
  (define (compile-prim1 p e)
    (seq (compile-e e)
         (compile-op1 p)))
   
  ;; Expr Expr Expr -> Asm
  (define (compile-if e1 e2 e3)
    (let ((l1 (gensym 'if))
          (l2 (gensym 'if)))
      (seq (compile-e e1)
           (Cmp rax (value->bits #f))
           (Je l1)
           (compile-e e2)
           (Jmp l2)
           (Label l1)
           (compile-e e3)
           (Label l2))))
   
  ;; Expr Expr -> Asm
  (define (compile-begin e1 e2)
    (seq (compile-e e1)
         (compile-e e2)))
   

Here’s the code we generate for '(add1 #f):

Examples

> (define (show e)
    (displayln (asm-string (compile-e (parse e)))))
> (show '(add1 #f))

        mov rax, 7

        mov r9, rax

        and r9, 1

        cmp r9, 0

        jne _err

        add rax, 2

Here are some examples running the compiler:

Examples

> (define (tell e)
    (match (asm-interp (compile (parse e)))
      ['err 'err]
      [b (bits->value b)]))
> (tell #t)

#t

> (tell #f)

#f

> (tell '(zero? 0))

#t

> (tell '(zero? -7))

#f

> (tell '(if #t 1 2))

1

> (tell '(if #f 1 2))

2

> (tell '(if (zero? 0) (if (zero? 0) 8 9) 2))

8

> (tell '(if (zero? (if (zero? 2) 1 0)) 4 5))

4

> (tell '(add1 #t))

'err

> (tell '(sub1 (add1 #f)))

'err

> (tell '(if (zero? #t) 1 2))

'err

Since the interpreter and compiler have well defined specifications for what should happen when type errors occur, we can test in the usual way again:

Examples

> (define (check-correctness e)
    (check-equal? (match (asm-interp (compile e))
                    ['err 'err]
                    [b (bits->value b)])
                  (interp e)
                  e))
> (check-correctness (Prim1 'add1 (Int 7)))

--------------------

ERROR

name:       check-equal?

location:   eval:395:0

check-equal?: contract violation

  expected: (or/c #f string?)

  given: '#s(Prim1 add1 #s(Int 7))

--------------------

> (check-correctness (Prim1 'add1 (Bool #f)))

--------------------

ERROR

name:       check-equal?

location:   eval:395:0

check-equal?: contract violation

  expected: (or/c #f string?)

  given: '#s(Prim1 add1 #s(Bool #f))

--------------------