426 lines
15 KiB
Plaintext
426 lines
15 KiB
Plaintext
.TL
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The ACK Modula-2 Compiler
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.AU
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Ceriel J.H. Jacobs
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.AI
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Department of Mathematics and Computer Science
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Vrije Universiteit
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Amsterdam
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The Netherlands
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.AB no
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.AE
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.NH
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Introduction
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.PP
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This document describes the implementation-specific features of the
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ACK Modula-2 compiler. It is not intended to teach Modula-2 programming.
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For a description of the Modula-2 language, the reader is referred to [1].
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.PP
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The ACK Modula-2 compiler is currently available for use with the VAX,
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Motorola MC68020, Motorola MC68000,
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PDP-11, and Intel 8086 code-generators.
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For the 8086, MC68000, and MC68020,
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floating point emulation is used. This is made available with the \fI-fp\fP
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option, which must be passed to \fIack\fP[4,5].
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.NH
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The language implemented
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.PP
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This section discusses the deviations from the Modula-2 language as described
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in the "Report on The Programming Language Modula-2", as it appeared in [1],
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from now on referred to as "the Report".
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Also, the Report sometimes leaves room for interpretation. The section numbers
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mentioned are the section numbers of the Report.
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.NH 2
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Syntax (section 2)
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.PP
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The syntax recognized is that of the Report, with some extensions to
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also recognize the syntax of an earlier definition, given in [2].
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Only one compilation unit per file is accepted.
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.NH 2
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Vocabulary and Representation (section 3)
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.PP
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The input "\f(CW10..\fP" is parsed as two tokens: "\f(CW10\fP" and "\f(CW..\fP".
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.PP
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The empty string \f(CW""\fP has type
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.DS
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.ft CW
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ARRAY [0 .. 0] OF CHAR
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.ft P
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.DE
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and contains one character: \f(CW0C\fP.
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.PP
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When the text of a comment starts with a '\f(CW$\fP', it may be a pragma.
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Currently, the following pragmas exist:
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.DS
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.ft CW
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(*$F (F stands for Foreign) *)
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(*$R[+|-] (Runtime checks, on or off, default on) *)
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(*$A[+|-] (Array bound checks, on or off, default off) *)
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(*$U (Allow for underscores within identifiers) *)
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.ft P
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.DE
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The Foreign pragma is only meaningful in a \f(CWDEFINITION MODULE\fP,
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and indicates that this
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\f(CWDEFINITION MODULE\fP describes an interface to a module written in another
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language (for instance C, Pascal, or EM).
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Runtime checks that can be disabled are:
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range checks,
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\f(CWCARDINAL\fP overflow checks,
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checks when assigning a \f(CWCARDINAL\fP to an \f(CWINTEGER\fP and vice versa,
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and checks that \f(CWFOR\fP-loop control-variables are not changed
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in the body of the loop.
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Array bound checks can be enabled, because many EM implementations do not
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implement the array bound checking of the EM array instructions.
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When enabled, the compiler generates a check before generating an
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EM array instruction.
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Even when underscores are enabled, they still may not start an identifier.
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.PP
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Constants of type \f(CWLONGINT\fP are integers with a suffix letter \f(CWD\fP
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(for instance \f(CW1987D\fP).
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Constants of type \f(CWLONGREAL\fP have suffix \f(CWD\fP if a scale factor is missing,
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or have \f(CWD\fP in place of \f(CWE\fP in the scale factor (f.i. \f(CW1.0D\fP,
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\f(CW0.314D1\fP).
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This addition was made, because there was no way to indicate long constants,
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and also because the addition was made in Wirth's newest Modula-2 compiler.
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.NH 2
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Declarations and scope rules (section 4)
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.PP
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Standard identifiers are considered to be predeclared, and valid in all
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parts of a program. They are called \fIpervasive\fP.
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Unfortunately, the Report does not state how this pervasiveness is accomplished.
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However, page 87 of [1] states: "Standard identifiers are automatically
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imported into all modules". Our implementation therefore allows
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redeclarations of standard identifiers within procedures, but not within
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modules.
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.NH 2
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Constant expressions (section 5)
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.PP
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Each operand of a constant expression must be a constant:
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a string, a number, a set, an enumeration literal, a qualifier denoting a
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constant expression, a typetransfer with a constant argument, or
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one of the standard procedures
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\f(CWABS\fP, \f(CWCAP\fP, \f(CWCHR\fP, \f(CWLONG\fP, \f(CWMAX\fP, \f(CWMIN\fP,
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\f(CWODD\fP, \f(CWORD\fP,
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\f(CWSIZE\fP, \f(CWSHORT\fP, \f(CWTSIZE\fP, or \f(CWVAL\fP, with constant argument(s);
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\f(CWTSIZE\fP and \f(CWSIZE\fP may also have a variable as argument.
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.PP
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Floating point expressions are never evaluated compile time, because
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the compiler basically functions as a cross-compiler, and thus cannot
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use the floating point instructions of the machine on which it runs.
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Also, \f(CWMAX(REAL)\fP and \f(CWMIN(REAL)\fP are not allowed.
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.NH 2
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Type declarations (section 6)
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.NH 3
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Basic types (section 6.1)
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.PP
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The type \f(CWCHAR\fP includes the ASCII character set as a subset.
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Values range from
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\f(CW0C\fP to \f(CW377C\fP, not from \f(CW0C\fP to \f(CW177C\fP.
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.NH 3
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Enumerations (section 6.2)
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.PP
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The maximum number of enumeration literals in any one enumeration type
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is \f(CWMAX(INTEGER)\fP.
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.NH 3
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Record types (section 6.5)
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.PP
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The syntax of variant sections in [1] is different from the one in [2].
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Our implementation recognizes both, giving a warning for the older one.
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However, see section 3.
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.NH 3
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Set types (section 6.6)
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.PP
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The only limitation imposed by the compiler is that the base type of the
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set must be a subrange type, an enumeration type, \f(CWCHAR\fP, or
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\f(CWBOOLEAN\fP.
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So, the lower bound may be negative.
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However, if a negative lower bound is used,
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the compiler gives a warning of the \fIrestricted\fP class (see the manual
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page of the compiler).
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.PP
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The standard type \f(CWBITSET\fP is defined as
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.DS
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.ft CW
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TYPE BITSET = SET OF [0 .. 8*SIZE(INTEGER)-1];
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.ft P
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.DE
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.NH 2
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Expressions (section 8)
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.NH 3
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Operators (section 8.2)
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.NH 4
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Arithmetic operators (section 8.2.1)
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.PP
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The Report does not specify the priority of the unary
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operators \f(CW+\fP or \f(CW-\fP:
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It does not specify whether
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.DS
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.ft CW
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- 1 + 1
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.ft P
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.DE
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means
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.DS
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.ft CW
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- (1 + 1)
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.ft P
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.DE
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or
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.DS
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.ft CW
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(-1) + 1
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.ft P
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.DE
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I have seen some compilers that implement the first alternative, and others
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that implement the second. Our compiler implements the second, which is
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suggested by the fact that their priority is not specified, which might
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indicate that it is the same as that of their binary counterparts.
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And then the rule about left to right decides for the second.
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On the other hand, one might argue that, since the grammar only allows
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for one unary operator in a simple expression, it must apply to the
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whole simple expression, not just the first term.
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.NH 2
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Statements (section 9)
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.NH 3
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Assignments (section 9.1)
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.PP
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The Report does not define the evaluation order in an assignment.
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Our compiler certainly chooses an evaluation order, but it is explicitly
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left undefined. Therefore, programs that depend on it, may cease to
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work later.
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.PP
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The types \f(CWINTEGER\fP and \f(CWCARDINAL\fP are assignment-compatible with
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\f(CWLONGINT\fP, and \f(CWREAL\fP is assignment-compatible with \f(CWLONGREAL\fP.
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.NH 3
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Case statements (section 9.5)
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.PP
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The size of the type of the case-expression must be less than or equal to
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the word-size.
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.PP
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The Report does not specify what happens if the value of the case-expression
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does not occur as a label of any case, and there is no \f(CWELSE\fP-part.
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In our implementation, this results in a runtime error.
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.NH 3
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For statements (section 9.8)
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.PP
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The Report does not specify the legal types for a control variable.
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Our implementation allows the basic types (except \f(CWREAL\fP),
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enumeration types, and subranges.
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A runtime warning is generated when the value of the control variable
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is changed by the statement sequence that forms the body of the loop,
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unless runtime checking is disabled.
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.NH 3
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Return and exit statements (section 9.11)
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.PP
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The Report does not specify which result-types are legal.
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Our implementation allows any result type.
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.NH 2
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Procedure declarations (section 10)
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.PP
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Function procedures must exit through a RETURN statement, or a runtime error
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occurs.
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.NH 3
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Standard procedures (section 10.2)
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.PP
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Our implementation supports \f(CWNEW\fP and \f(CWDISPOSE\fP
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for backwards compatibility,
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but issues warnings for their use. However, see section 3.
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.PP
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Also, some new standard procedures were added, similar to the new standard
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procedures in Wirth's newest compiler:
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.IP \-
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\f(CWLONG\fP converts an argument of type \f(CWINTEGER\fP or \f(CWREAL\fP to the
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types \f(CWLONGINT\fP or \f(CWLONGREAL\fP.
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.IP \-
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\f(CWSHORT\fP performs the inverse transformation, without range checks.
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.IP \-
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\f(CWFLOATD\fP is analogous to \f(CWFLOAT\fP, but yields a result of type
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\f(CWLONGREAL\fP.
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.IP \-
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\f(CWTRUNCD\fP is analogous to \f(CWTRUNC\fP, but yields a result of type
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\f(CWLONGINT\fP.
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.NH 2
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System-dependent facilities (section 12)
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.PP
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The type \f(CWBYTE\fP is added to the \f(CWSYSTEM\fP module.
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It occupies a storage unit of 8 bits.
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\f(CWARRAY OF BYTE\fP has a similar effect to \f(CWARRAY OF WORD\fP, but is
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safer. In some obscure cases the \f(CWARRAY OF WORD\fP mechanism does not quite
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work properly.
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.PP
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The procedure \f(CWIOTRANSFER\fP is not implemented.
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.NH 1
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Backwards compatibility
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.PP
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Besides recognizing the language as described in [1], the compiler recognizes
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most of the language described in [2], for backwards compatibility.
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It warns the user for old-fashioned
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constructions (constructions that [1] does not allow).
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If the \fI-Rm2-3\fP option (see [6]) is passed to \fIack\fP, this backwards
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compatibility feature is disabled. Also, it may not be present on some
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smaller machines, like the PDP-11.
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.NH 1
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Compile time errors
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.PP
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The compile time error messages are intended to be self-explanatory,
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and not listed here. The compiler also sometimes issues warnings,
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recognizable by a warning-classification between parentheses.
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Currently, there are 3 classifications:
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.IP "(old-fashioned use)"
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.br
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These warnings are given on constructions that are not allowed by [1], but are
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allowed by [2].
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.IP (strict)
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.br
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These warnings are given on constructions that are supported by the
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ACK Modula-2 compiler, but might not be supported by others.
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Examples: functions returning structured types, SET types of subranges with
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negative lower bound.
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.IP (warning)
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.br
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The other warnings, such as warnings about variables that are never assigned,
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never used, etc.
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.NH 1
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Runtime errors
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.PP
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The ACK Modula-2 compiler produces code for an EM machine as defined in [3].
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Therefore, it depends on the implementation
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of the EM machine for detection some of the runtime errors that could occur.
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.PP
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The \fITraps\fP module enables the user to install his own runtime
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error handler.
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The default one just displays what happened and exits.
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Basically, a trap handler is just a procedure that takes an INTEGER as
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parameter. The INTEGER is the trap number. This INTEGER can be one of the
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EM trap numbers, listed in [3], or one of the numbers listed in the
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\fITraps\fP definition module.
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.PP
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The following runtime errors may occur:
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.IP "array bound error"
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.br
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The detection of this error depends on the EM implementation.
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.IP "range bound error"
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.br
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Range bound errors are always detected, unless runtime checks are disabled.
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.IP "set bound error"
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.br
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The detection of this error depends on the EM implementation.
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The current implementations detect this error.
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.IP "integer overflow"
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.br
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The detection of this error depends on the EM implementation.
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.IP "cardinal overflow"
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.br
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This error is detected, unless runtime checks are disabled.
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.IP "cardinal underflow"
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.br
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This error is detected, unless runtime checks are disabled.
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.IP "real overflow"
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.br
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The detection of this error depends on the EM implementation.
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.IP "real underflow"
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.br
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The detection of this error depends on the EM implementation.
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.IP "divide by 0"
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.br
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The detection of this error depends on the EM implementation.
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.IP "divide by 0.0"
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.br
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The detection of this error depends on the EM implementation.
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.IP "undefined integer"
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.br
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The detection of this error depends on the EM implementation.
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.IP "undefined real"
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.br
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The detection of this error depends on the EM implementation.
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.IP "conversion error"
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.br
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This error occurs when assigning a negative value of type INTEGER to a
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variable of type CARDINAL,
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or when assigning a value of CARDINAL, that is > MAX(INTEGER), to a
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variable of type INTEGER.
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It is detected, unless runtime checking is disabled.
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.IP "stack overflow"
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.br
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The detection of this error depends on the EM implementation.
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.IP "heap overflow"
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.br
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The detection of this error depends on the EM implementation.
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Might happen when ALLOCATE fails.
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.IP "case error"
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.br
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This error occurs when non of the cases in a CASE statement are selected,
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and the CASE statement has no ELSE part.
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The detection of this error depends on the EM implementation.
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All current EM implementations detect this error.
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.IP "stack size of process too large"
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.br
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The current implementation limits the stack size of processes to 1024 bytes.
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.IP "too many nested traps + handlers"
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.br
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This error can only occur when the user has installed his own trap handler.
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It means that during execution of the trap handler another trap has occurred,
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and that several times.
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In some cases, this is an error because of overflow of some internal tables.
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.IP "no RETURN from procedure function"
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.br
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This error occurs when a procedure function does not return properly
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("falls" through).
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.IP "illegal instruction"
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.br
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This error might occur when you use floating point operations on an
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implementation that does not have floating point.
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.PP
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In addition, some of the library modules may give error messages.
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The \fBTraps\fP-module has a suitable mechanism for this.
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.NH 1
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Calling the compiler
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.PP
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See [4,5,6] for a detailed explanation.
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.PP
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Ths compiler itself has no version checking mechanism. A special linker
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would be needed to do that. Therefore, a makefile generator is included [7].
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.NH 1
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The procedure call interface
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.PP
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Parameters are pushed on the stack in reversed order, so that the EM AB
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(argument base) register indicates the first parameter.
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For VAR parameters, its address is passed, for value parameters its value.
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The only exception to this rule is with conformant arrays.
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For conformant arrays, the address is passed, and an array descriptor is
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passed. The descriptor is an EM array descriptor. It consists of three
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fields: the lower bound (always 0), upper bound - lower bound, and the
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size of the elements.
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The descriptor is pushed first.
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If the parameter is a value parameter, the called routine must make sure
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that its value is never changed, for instance by making its own copy
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of the array. The Modula-2 compiler does exactly this.
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.NH 1
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References
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.IP [1]
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Niklaus Wirth,
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.I
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Programming in Modula-2, third, corrected edition,
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.R
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Springer-Verlag, Berlin (1985)
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.IP [2]
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Niklaus Wirth,
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.I
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Programming in Modula-2,
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.R
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Stringer-Verlag, Berlin (1983)
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.IP [3]
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A.S.Tanenbaum, J.W.Stevenson, Hans van Staveren, E.G.Keizer,
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.I
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Description of a machine architecture for use with block structured languages,
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.R
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Informatica rapport IR-81, Vrije Universiteit, Amsterdam
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.IP [4]
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UNIX manual \fIack\fP(1)
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.IP [5]
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UNIX manual \fImodula-2\fP(1)
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.IP [6]
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UNIX manual \fIem_m2\fP(6)
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.IP [7]
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UNIX manual \fm2mm\fP(1)
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