Assembly Language Processor (ALP) Assembler Reference

Reprint Courtesy of International Business Machines Corporation, © International Business Machines Corporation

About this Reference

The following notations are used in this reference:

KEYWORD	Commands and language keywords.
KEYWORD	The default value for a command or language keyword when multiple values are possible but none are actually specified.
Phrase	Typically indicates a hypertext link to a separate panel containing a description for that phrase.
Parameter	Parameters whose actual names or values are to be supplied by the programmer.
Definition	A term being defined for the first time, or special emphasis.
Subscript	Subscripted text.
Superscript	Superscripted text (other than ý).
<Name>	A text value represented by "Name" is to be substituted in place of <Name> typically at assembler run-time.

Assembly Language Processor (ALP) Overview

The Assembly Language Processor (ALP) is an assembler that runs under OS/2 Warp. ALP is a functional replacement for the Microsoft Macro Assembler (MASM) and accepts:

The full syntax of the Intel 80X86 architecture
The full syntax of the MASM 5.10 high-level directive language
A subset of the MASM 6.00 high-level directive language

ALP generates standard Object Module Format (OMF) files that can be linked to produce DOS or OS/2 executables. It can also generate symbolic debugging information compatible with the IBM family of source code debuggers. A MASM 5.10-compatible command line utility (MASM2ALP) is also provided to enable use of ALP with little or no change to existing build environments.

ALP also offers a rich set of command line options, as well as a comprehensive listing output cabability that is highly configurable, allowing a visual perspective not possible with other assemblers.

Installation

Understanding ALP

Using ALP

Language Elements

Description

The following sections describe the elements you use to build an ALP program source file.

Character Set

All elements in an assembler language source file are built from collections of characters contained in the character set, which are defined as:

The uppercase and lowercase letters of the English alphabet
The decimal digits 0 through 9
The following graphic characters:

~   !   "   #   $   %   ^   &   '   (   )   | 
*   +   ,   -   .   /   :   ;   =   <   >   ? 
[   \   ]   _   {   }   @

The space and horizontal tab characters
The end of line character(s)

White Space

White space is a character or contiguous stream of characters that is ignored or removed from the input stream by the ALP preprocessor.

White space characters are any contiguous sequence of one or more space or tab characters not enclosed in single or double quotes. White space characters are significant only in that they serve to separate language tokens from one another; they are removed from the input stream by the scanner.

Syntax

Token:

Reserved-Word

Identifier

Literal

Punctuator

Reserved Words

Description

This section describes all of the assembler reserved words.

Syntax

Reserved-Word:

Preprocessor-Directive

Assembler-Directive

Processor-Mnemonic

Processor-Register

Scalar-TypeName

Distance-TypeName

Language-Name

Anonymous-Label-Alias

Location-Counter-Alias

Indeterminate-Value-Alias

Directive-Keyword

Operator-Keyword

Preprocessor Directives

Description

Preprocessor Directives are symbolic names that describe the various assembly-time text processing instructions interpreted by the preprocessor phase of the assembler.

Syntax

Preprocessor-Directive: one of

CATSTR      COMMENT     ELSE        ELSEIF
ELSEIF1     ELSEIF2     ELSEIFB     ELSEIFDEF
ELSEIFDIF   ELSEIFDIFI  ELSEIFE     ELSEIFIDN
ELSEIFIDNI  ELSEIFNB    ELSEIFNDEF  ENDIF
ENDM        EQU         EXITM       FOR
FORC        IF          IF1         IF2
IFB         IFDEF       IFDIF       IFDIFI
IFE         IFIDN       IFIDNI      IFNB
IFNDEF      INCLUDE     INSTR       IRP
IRPC        LOCAL       MACRO       PURGE
REPEAT      REPT        SIZESTR     SUBSTR

Assembler Directives

Description

Assembler Directives are symbolic names that describe the various assembly-time instructions interpreted by the assembler itself.

Syntax

Assembler-Directive: one of

.186          .286          .286C         .286P
.287          .386          .386C         .386P
.387          .486          .486C         .486P
.586          .586P         .686          .686P
.8086         .8087          ALIGN        .ALPHA
 ASSUME       %BIN          .CODE          COMM
.CONST        .CREF         .DATA         .DATA?
 DB            DD            DF            DOSSEG
.DOSSEG        DQ            DT            DW
 ECHO          END           ENDP          ENDS
 EQU          .ERR          .ERR1         .ERR2
.ERRB         .ERRDEF       .ERRDIF       .ERRDIFI
.ERRE         .ERRIDN       .ERRIDNI      .ERRNB
.ERRNDEF      .ERRNZ         EVEN          EXTERN
 EXTERNDEF     EXTRN        .FARDATA      .FARDATA?
 GROUP         INCLUDELIB    LABEL        .LALL
.LFCOND       .LIST         .LISTALL      .LISTIF
.LISTMACRO    .LISTMACROALL  LOCAL        .MMX
.MODEL         NAME         .NOCREF       .NOLIST
.NOLISTIF     .NOLISTMACRO  .NOMMX         OPTION
 ORG          %OUT           PAGE          PROC
 PUBLIC       .RADIX         RECORD       .SALL
 SEGMENT      .SEQ          .SFCOND       .STACK
 STRUC         STRUCT        SUBTITLE      SUBTTL
.TFCOND        TITLE         TYPEDEF       UNION
.XALL         .XCREF        .XLIST

Processor Mnemonics

Description

Processor Mnemonics are symbolic names given to the various instructions in the processor instruction set.

Syntax

Processor-Mnemonic: one of

AAA        AAD        AAM        AAS        ADC
ADD        AND        ARPL       BOUND      BSF
BSR        BSWAP      BT         BTC        BTR
BTS        CALL       CBW        CDQ        CLC
CLD        CLI        CLTS       CMC        CMOVA
CMOVAE     CMOVB      CMOVBE     CMOVC      CMOVE
CMOVG      CMOVGE     CMOVL      CMOVLE     CMOVNA
CMOVNAE    CMOVNB     CMOVNBE    CMOVNC     CMOVNE
CMOVNG     CMOVNGE    CMOVNL     CMOVNLE    CMOVNO
CMOVNP     CMOVNS     CMOVNZ     CMOVO      CMOVP
CMOVPE     CMOVPO     CMOVS      CMOVZ      CMP
CMPS       CMPSB      CMPSD      CMPSW      CMPXCHG
CMPXCHG8B  CPUID      CWD        CWDE       DAA
DAS        DEC        DIV        EMMS       ENTER
ESC        F2XM1      FABS       FADD       FADDP
FBLD       FBSTP      FCHS       FCLEX      FCMOVB
FCMOVBE    FCMOVE     FCMOVNB    FCMOVNBE   FCMOVNE
FCMOVNU    FCMOVU     FCOM       FCOMI      FCOMIP
FCOMP      FCOMPP     FCOS       FDECSTP    FDISI
FDIV       FDIVP      FDIVR      FDIVRP     FENI
FFREE      FIADD      FICOM      FICOMP     FIDIV
FIDIVR     FILD       FIMUL      FINCSTP    FINIT
FIST       FISTP      FISUB      FISUBR     FLD
FLD1       FLDCW      FLDENV     FLDENVD    FLDENVW
FLDL2E     FLDL2T     FLDLG2     FLDLN2     FLDPI
FLDZ       FMUL       FMULP      FNCLEX     FNDISI
FNENI      FNINIT     FNOP       FNSAVE     FNSAVED
FNSAVEW    FNSTCW     FNSTENV    FNSTENVD   FNSTENVW
FNSTSW     FPATAN     FPREM      FPREM1     FPTAN
FRNDINT    FRSTOR     FRSTORD    FRSTORW    FSAVE
FSAVED     FSAVEW     FSCALE     FSETPM     FSIN
FSINCOS    FSQRT      FST        FSTCW      FSTENV
FSTENVD    FSTENVW    FSTP       FSTSW      FSUB
FSUBP      FSUBR      FSUBRP     FTST       FUCOM
FUCOMI     FUCOMIP    FUCOMP     FUCOMPP    FWAIT
FXAM       FXCH       FXTRACT    FYL2X      FYL2XP1
HLT        IDIV       IMUL       IN         INC
INS        INSB       INSD       INSW       INT
INTO       INVD       INVLPG     IRET       IRETD
IRETDF     IRETF      JA         JAE        JB
JBE        JC         JCXZ       JE         JECXZ
JG         JGE        JL         JLE        JMP
JNA        JNAE       JNB        JNBE       JNC
JNE        JNG        JNGE       JNL        JNLE
JNO        JNP        JNS        JNZ        JO
JP         JPE        JPO        JS         JZ
LAHF       LAR        LDS        LEA        LEAVE 
LES        LFS        LGDT       LGS        LIDT 
LLDT       LMSW       LOCK       LODS       LODSB 
LODSD      LODSW      LOOP       LOOPD      LOOPE 
LOOPED     LOOPEW     LOOPNE     LOOPNED    LOOPNEW 
LOOPNZ     LOOPNZD    LOOPNZW    LOOPW      LOOPZ 
LOOPZD     LOOPZW     LSL        LSS        LTR 
MOV        MOVD       MOVQ       MOVS       MOVSB 
MOVSD      MOVSW      MOVSX      MOVZX      MUL 
NEG        NOP        NOT        OR         OUT 
OUTS       OUTSB      OUTSD      OUTSW      PACKSSDW 
PACKSSWB   PACKUSWB   PADDB      PADDD      PADDSB 
PADDSW     PADDUSB    PADDUSW    PADDW      PAND 
PANDN      PCMPEQB    PCMPEQD    PCMPEQW    PCMPGTB 
PCMPGTD    PCMPGTW    PMADDWD    PMULHW     PMULLW 
POP        POPA       POPAD      POPD       POPF 
POPFD      POPW       POR        PSLLD      PSLLQ 
PSLLW      PSRAD      PSRAW      PSRLD      PSRLQ 
PSRLW      PSUBB      PSUBD      PSUBSB     PSUBSW 
PSUBUSB    PSUBUSW    PSUBW      PUNPCKHBW  PUNPCKHDQ 
PUNPCKHWD  PUNPCKLBW  PUNPCKLDQ  PUNPCKLWD  PUSH 
PUSHA      PUSHAD     PUSHD      PUSHF      PUSHFD 
PUSHW      PXOR       RCL        RCR        RDMSR 
RDPMC      RDTSC      REP        REPE       REPNE 
REPNZ      REPZ       RET        RETF       RETN 
ROL        ROR        RSM        SAHF       SAL 
SAR        SBB        SCAS       SCASB      SCASD 
SCASW      SETA       SETAE      SETB       SETBE 
SETC       SETE       SETG       SETGE      SETL 
SETLE      SETNA      SETNAE     SETNB      SETNBE 
SETNC      SETNE      SETNG      SETNGE     SETNL 
SETNLE     SETNO      SETNP      SETNS      SETNZ 
SETO       SETP       SETPE      SETPO      SETS 
SETZ       SGDT       SHL        SHLD       SHR 
SHRD       SIDT       SLDT       SMSW       STC 
STD        STI        STOS       STOSB      STOSD 
STOSW      STR        SUB        TEST       UC2 
VERR       VERW       WAIT       WBINVD     WRMSR 
XADD       XCHG       XLAT       XLATB      XOR

Processor Registers

Description

Processor Registers are the symbolic names assigned to the various internal processor registers. They are normally used as operands to processor instructions.

Syntax

Processor-Register:

General-Purpose-Register

Segment-Register

Control-Register

Debug-Register

Test-Register

MMX-Register

Floating-Point-Register

General-Purpose-Register:

8-Bit-Register

16-Bit-Register

32-Bit-Register

8-Bit-Register: one of

AL AH BL BH CL CH DL DH

16-Bit-Register: one of

AX BX CX DX DI SI BP SP

32-Bit-Register: one of

EAX EBX ECX EDX EDI ESI EBP ESP

Segment-Register: one of

CS DS ES FS GS SS

Control-Register: one of

CR0 CR2 CR3 CR4

Debug-Register: one of

DR0 DR1 DR2 DR3 DR4 DR5 DR6 DR7

Test-Register: one of

TR3 TR4 TR5 TR6 TR7

MMX-Register: one of

MM0 MM1 MM2 MM3 MM4 MM5 MM6 MM7

Floating-Point-Register: ST

Scalar Type Names

Description

Scalar Type Names are the symbolic names given to the integral data types. These are the fundamental types of data upon which the processor can directly operate.

Syntax

Scalar-TypeName:

BYTE

SBYTE

WORD

SWORD

DWORD

SDWORD

REAL4

FWORD

QWORD

REAL8

TBYTE

REAL10

Distance Type Names

Description

Distance Type Names are the symbolic names given to the integral types of pointers directly supported by the processor. Their names reflect a fundamental property of the Intel processor architecture known as distance. The type of pointer is defined by the distance required to reach the information to which it points.

Syntax

Distance-TypeName:

NEAR

NEAR16

NEAR32

FAR

FAR16

FAR32

Language Names

Description

Language Names refer to the various high level programming languages (or more specifically, the calling conventions used by such languages) with which the assembler has the ability to interface.

Syntax

Language-Name:

C

SYSCALL

STDCALL

PASCAL

FORTRAN

BASIC

OPTLINK

Anonymous Label Aliases

Description

The Anonymous Label Aliases are reserved symbolic names that return a context-sensitive value when referenced in expressions.

The reserved name @B (backward reference) returns the internally generated name representing the nearest @@: code label appearing before the current location in the input stream.

The reserved name @F (forward reference) returns the internally generated name representing the nearest @@: code label appearing after the current location in the input stream.

Syntax

Anonymous-Label-Alias:

@B

@F

Location Counter Alias

Description

The Location Counter Alias is a reserved name used in expressions to return the offset within the current segment or structure being assembled.

Syntax

Location-Counter-Alias:

$

Indeterminate Value Alias

Description

The Indeterminate Value Alias is a reserved name used in expressions to represent an uninitialized value.

Syntax

Indeterminate-Value-Alias:

?

Directive Keywords

Description

Directive Keywords are symbolic names recognized and used in the body of various assembler directives.

Syntax

Directive-Keyword:

ABS         AT            BASIC         C
CASEMAP     CODE          COMMON        DOTNAME
EMULATOR    EPILOGUE      ERROR         EXPORT
EXPR16      EXPR32        FARSTACK      FLAT
FORTRAN     HUGE          LANGUAGE      LARGE
LJMP        MEDIUM        NEARSTACK     NODOTNAME
NOEMULATOR  NOKEYWORD     NOLANGUAGE    NOLJMP
NONE        NOOLDMACROS   NOOLDSTRUCTS  NOREADONLY
NOSCOPED    NOSIGNEXTEND  NOTHING       NOTPUBLIC
OLDMACROS   OLDSTRUCTS    OPTLINK       OS_DOS
OS_OS2      PAGE          PARA          PASCAL
PRIVATE     PROC          PROLOGUE      PUBLIC
READONLY    SCOPED        SEGMENT       SIGNEXTEND
SMALL       STACK         STDCALL       SYSCALL
TINY        USE16         USE32         USES

Operator Keywords

Description

Operator Keywords are symbolic names used in expressions to denote an operation to be performed on one or more operands.

Syntax

Operator-Keyword:

AND         DUP         EQ          GE
GT          HIGH        HIGHWORD    LE
LENGTH      LENGTHOF    LOW         LOWWORD
LT          MASK        MOD         NE
NOT         OFFSET      OPATTR      OR
PTR         SEG         SHL         SHORT
SHR         SIZE        SIZEOF      THIS
.TYPE       TYPE        WIDTH       XOR

Identifiers

Description

This section describes the syntax for identifiers and the various types of information they can be made to represent.

Syntax

Identifier:

Normal-Identifier

Dot-Identifier

Normal-Identifier

NonDigit

Normal-Identifier Identifer-Character

Dot-Identifier . Normal-Identifier

Identifier-Character NonDigit Digit

NonDigit: one of

_ $ @ ?
a b c d e f g h i j k l m
n o p q r s t u v w x y z
A B C D E F G H I J K L M
N O P Q R S T U V W X Y Z

Digit: one of

0 1 2 3 4 5 6 7 8 9

Identifier Types

Description

This section describes the various types of identifiers that the assembler will create and manipulate.

Definition

Identifier-Type:

EquateName

FieldName

GroupName

LabelName

MacroName

SegmentName

UserDefined-TypeName

Equate Name

Definition

EquateName:

Numeric-EquateName

Text-EquateName

Description

An EquateName is a symbolic identifier that is associated with an expression or a body of text. The assembler substitutes the value of the EquateName at the point of reference.

Numeric Equate Name

An identifier becomes a Numeric-EquateName when it is defined in a EQU or = directive. Procedure parameter names and local variable names are also created as Numeric-EquateNames, but are visible only from within the procedure where they are defined. All other Numeric-EquateNames are globally-scoped identifiers visible across the entire module.

A Numeric-EquateName may only be referenced from within expressions, as its replacement value is itself an expression.

Text Equate Name

A Text-EquateName is a globally-scoped identifier created during the processing of a EQU preprocessor directive. A Text-EquateName is associated with a body of text whose content may not span across line breaks. In certain contexts the assembler replaces the Text-EquateName with the text that it represents and recursively evaluates the result.

Field Name

Definition

FieldName:

Record-FieldName

Structure-FieldName

Union-FieldName

Description

An identifier becomes a FieldName when it is defined within a RECORD, STRUCT, or UNION directive.

Record Field Name

A Record-FieldName is a globally-scoped identifier created during the processing of a RECORD directive. It is a special variation of a Numeric-EquateName and can be used in the same contexts.

Structure Field Name

An identifier becomes a Structure-FieldName when it is defined in a STRUCT directive. If the assembler is operating in M510 mode, or if the OPTION OLDSTRUCTS directive has been specified, then a Structure-FieldName is a globally-scoped identifier treated as a special variation of a Numeric-EquateName and can be used in the same contexts. Otherwise, a Structure-FieldName is private to the defining structure and is only accessible in expressions through use of the Structure/Union Field Selection (. Operator).

Union Field Name

An identifier becomes a Union-FieldName when it is defined in a UNION directive. A Union-FieldName is private to the defining union and is only accessible in expressions through use of the Structure/Union Field Selection (. Operator).

Group Name

A GroupName is a globally-scoped identifier created during the processing of a GROUP directive. It is referenced from within expressions.

Label Name

Definition

LabelName:

Code-LabelName

Data-LabelName

Description

A LabelName is globally-scoped identifier that is associated with a program address at application run-time. It has an explicit or inherited Type-Declaration, and an optional Language-Attribute. These attributes are described in the following sections.

Type Declaration

The type declaration associated with a label name depends on how the label was defined. See the Code-LabelName and Data-LabelName sections for descriptions on how this attribute is assigned.

Language Attribute

A LabelName can have an assigned Language-Attribute, set either implicitly through the use of a Language-Name keyword in the body of a .MODEL or OPTION directive, or explicitly through the use of an overriding Language-Name keyword in the body of a EXTERN/EXTRN, EXTERNDEF, PROC, or PUBLIC directive. The Language-Attribute determines the exact spelling of the LabelName identifier when it is written to the object file. According to the Language-Attribute, identifier spellings are modified from their appearance in the assembly language source module as follow:

LANGUAGE ATTRIBUTE	IDENTIFIER SPELLING
OPTLINK, SYSCALL	No modifications are made to the identifier when written to the object file.
C, STDCALL	A leading underscore character is appended to the front of the name.
BASIC, FORTRAN, PASCAL	All characters in the identifier are converted to uppercase.

Code Label Name

Definition

Code-LabelName:

Target-LabelName

Procedure-LabelName

Description

A Code-LabelName is an identifier that is associated with an executable code address at application run-time. There are two types of Code-LabelNames: Target-LabelNames and Procedure-LabelNames.

Target Label Name

An identifier becomes a Target-LabelName when it is defined with a :, ::, or LABEL directive.

If a Target-LabelName created with a single colon (:) is defined within the body of a procedure, then the name is visible only from within that procedure unless operating in M510 mode (and no .MODEL directive with a Language-Name has been specified), or unless the OPTION NOSCOPED directive has been specified.

A Target-LabelName defined outside the body of a procedure is visible to the entire module, and may also be given PUBLIC visibility.

Procedure Label Name

An identifier becomes a Procedure-LabelName when it is defined in a PROC directive.

Data Label Name

A Data-LabelName is an identifier that is the address of a program variable at application run-time. An identifier becomes a Data-LabelName when it is named in a data allocation statement, or when a scalar, aggregate, or vector type is associated with the identifier named in a LABEL, EXTERN/ EXTRN, EXTERNDEF, or COMM directive.

Macro Name

A MacroName is a globally-scoped identifier created during the processing of a MACRO directive. It is associated with a multi-line body of text. A MacroName may only be used in contexts where a normal assembler directive is expected.

Macro Parameter Name

An identifier becomes a Macro-ParameterName when it is named as a parameter to a macro in a MACRO directive. It is associated with a body of text whose content may not span across line breaks. It is only recognized and acted upon from within the body of a macro expansion.

Segment Name

A SegmentName is a globally-scoped identifier created during the processing of a SEGMENT directive. It may be referenced from within expressions or in the body of a GROUP directive.

User-Defined Type Name

Definition

UserDefined-TypeName:

Record-TypeName

Structure-TypeName

Typedef-TypeName

Union-TypeName

Description

An identifier becomes a UserDefined-TypeName when it is defined within a RECORD, STRUCT, TYPEDEF, or UNION directive.

Record Type Name

A Record-TypeName is a globally-scoped identifier created during the processing of a RECORD directive. It is recognized from within Expressions, Type-Declarations, or as a pseudo-directive in a data allocation statement.

Structure Type Name

A Structure-TypeName is a globally-scoped identifier created during the processing of a STRUCT directive. It is recognized from within Expressions, Type-Declarations, or as a pseudo-directive in a data allocation statement.

Typedef Type Name

A Typedef-TypeName is a globally-scoped identifier created during the processing of a TYPEDEF directive. It is recognized from within Expressions, Type-Declarations, or as a pseudo-directive in a data allocation statement.

Union Type Name

A Union-TypeName is a globally-scoped identifier created during the processing of a UNION directive. It is recognized from within Expressions, Type-Declarations, or as a pseudo-directive in a data allocation statement.

Predefined Identifiers

The following sections describe the predefined identifiers created by the assembler. When a case-sensitive assembly is being performed, the predefined identifiers must be spelled exactly as they appear in the following descriptions with respect to uppercase and lowercase characters.

Segment Information

The following sections describe the predefined identifiers created by the assembler in support of segment manipulation.

@code

The @code identifier is a Text-EquateName created by the assembler when a .MODEL directive is encountered, at which time the assembler performs an automatic ASSUME CS:@code operation. The @code symbol is not defined if a .MODEL directive has not been issued.

Under MASM 5.10 emulation, the @code symbol is set to the name of the implicitly-defined default code segment (the segment opened when a .CODE directive is used) and its value is never changed. In other modes, the @code symbol is updated to reflect whatever segment is opened by using .CODE, whether defined implicitly or as an explicit parameter to the .CODE directive.

The value assigned to the @code symbol when the default code segment is opened is determined by the memory model as follows:

Memory Model Value for @code

TINY DGROUP

SMALL _TEXT

MEDIUM module _TEXT

COMPACT_TEXT

LARGE module _TEXT

HUGE module _TEXT

FLAT CODE32

The module entry is replaced with base file name of the top-level module being assembled.

@CodeSize

The @CodeSize identifier is a Numeric-EquateName created by the assembler when a .MODEL directive is encountered. @CodeSize indicates whether code segments created by the .CODE directive are named such that the linker will combine them into a single (NEAR) segment or into multiple (FAR) segments. The @CodeSize symbol is set to 0 (NEAR) for the TINY, SMALL, COMPACT, and FLAT memory models, and to 1 (FAR) for the MEDIUM, LARGE, and HUGE memory models. The @CodeSize symbol is not defined if a .MODEL directive has not been issued.

@CurSeg

The @CurSeg identifier is a Text-EquateName defined by the assembler to hold the name of the currently opened segment. If no segment is currently open, @CurSeg will expand into an empty string.

@data

The @data identifier is a Text-EquateName created by the assembler when a .MODEL directive is encountered. It expands to the group name shared by all of the near data segments. If a .MODEL FLAT has been issued, the @data identifier expands to FLAT. For all other memory models, it expands to DGROUP.

@DataSize

The @DataSize identifier is a Numeric-EquateName created by the assembler when a .MODEL directive is encountered, and represents the default data distance. Depending on the currently selected memory model, the @DataSize identifier is set to the following values:

TINY 0

SMALL 0

COMPACT 1

MEDIUM 1

LARGE 1

HUGE 2

FLAT 0

@Model

The @Model identifier is a Numeric-EquateName created by the assembler when a .MODEL directive is encountered, and is set to a unique value for each memory model. The values are as follows:

TINY 1

SMALL 2

COMPACT 3

MEDIUM 4

LARGE 5

HUGE 6

FLAT 7

@WordSize

The @WordSize identifier is a Numeric-EquateName that reflects the address size attribute of the current segment. It is set to 2 for a USE16 segment, and 4 for a USE32 segment. If no segment is currently open, it reflects the default address size as determined by the currently selected processor.

Version Information

These identifiers offer methods of testing the various operating modes of the assembler to determine what features are activated or disabled, or how the assembler will behave under various conditions.

@Alp

The @Alp identifier is a Text-EquateName that can be tested to determine if ALP is assembling the source file (versus some other assembler). It is always set to the string 100.

@AlpMajor

The @AlpMajor identifier is a Text-EquateName that reflects the major portion of the three-part assembler version number. It is padded on the right with zeros to allow major version number comparisions independant of the minor version and revisions numbers. See @AlpVersion for more information.

This identifier is only defined in ALP mode.

@AlpMinor

The @AlpMinor identifier is a Text-EquateName that reflects the minor portion of the three-part assembler version number. It is padded on the right with zeros to allow minor version number comparisions independant of the major version and revisions numbers. See @AlpVersion for more information.

This identifier is only defined in ALP mode.

@AlpRevision

The @AlpRevision identifier is a Text-EquateName that reflects the revision portion of the three-part assembler version number. It allows revision number comparisions independant of the major and minor version numbers. See @AlpVersion for more information.

This identifier is only defined in ALP mode.

@AlpVersion

The @AlpVersion identifier is a Text-EquateName that reflects the full three-part assembler version number. This is an encoding of the version number printed in the program banner when the assembler is invoked. This number and its requisite parts may be tested to determine the presence or absence of features provided by the assembler.

The assembler version number consists of three parts:

The major version number (one digit)
The minor version number (two digits)
The revision number (three digits)

In the assembler banner, the numbers are separated by the period (.) character; the period is removed from the text defined by the predefined identifiers.

For example, if the major version number is 1, the minor version number is 2, and the revision number is 3, then the full version number is printed in the assembler banner as 1.02.003, and the various predefined version identifers would be set as follows:

@AlpVersion   102003
@AlpMajor     100000
@AlpMinor       2000
@AlpRevision     003

This identifier is only defined in ALP mode.

@Cpu

The @Cpu identifier is a Numeric-EquateName that reflects the currently selected processor for which ALP is assembling instructions. This value is affected by issuing a Processor-Control-Directive, and is a bit map that indicates the currently active processor instruction set(s).

B	A	9	8	7	6	5	4	3	2	1	0	BIT SET IF ASSEMBLING FOR
											1	8086/8088
										1		80186
									1			80286
								1				80386
							1					80486
						1						80586 (Pentium)
					1							80686 (Pentium Pro)
				1								Privileged mode
			1									8087
		1										MMX Extensions
	1											80287
1												80387

@Version

The @Version identifier is a Text-EquateName that reflects the MASM-compatible version number. The current emulation mode of the assembler affects the value of this symbol as follows:

M510 510

M600 600

ALP 4294967295 (the highest possible value for an unsigned 32-bit integer)

Date and Time Information

These identifiers allow the programmer to query the system date or time during the assembly. Each time they are referenced, a new system request for the current date and time is made and the values held in the identifiers are refreshed.

@Date

The @Date identifier is a Text-EquateName that is set to the current system date. If the current operating mode is M600, the date is returned in the MM/DD/YY format. In native ALP mode, the date is returned in the MM/DD/YYYY format.

The @Date identifier is not available in M510 mode.

@Time

The @Time identifier is a Text-EquateName that is set to the current system time in 24-hour HH:MM:SS format.

The @Time identifier is not available in M510 mode.

File Information

These identifiers return information about the file(s) being assembled.

@FileName

The @FileName identifier is a Text-EquateName that is set to the base name of the main file being assembled (as it appears on the command line).

@Line

The @Line identifier is a Numeric-EquateName that is set to the current source line number in the file currently being assembled.

The @Line identifier is not available in M510 mode.

Literals

Description

Literals are the notational method whereby numeric values or strings of character data are represented in the source stream. Literals are also commonly referred to as constants (especially in the context of high level languages) because they typically represent objects whose values do not change throughout the life of the assembly or compilation. However, literals should not be confused with run-time "constants"; ("read-only"; data items allocated by the programmer); they are assembly-time tokens used by the assembler to represent numeric values or character strings.

Syntax

Literal:

Floating-Point-Literal

Integer-Literal

String-Literal

Integer Literals

Description

An integer literal represents a fixed-point numeric value. An integer literal must begin with one of the numeric digits 0 - 9, and may be optionally terminated with a suffix character called a radix specifier. The radix specifier tells the assembler whether the literal is to be interpreted as a base 2 (binary), 8 (octal), 10 (decimal), or 16 ( hexadecimal) number. If the literal is not suffixed with a radix specifier , the assembler uses the value of the current radix to determine the base of the number. The default radix is 10 (decimal), but the .RADIX directive can be used to specify an alternate radix.

Syntax

Integer-Literal:

Binary-Integer-Literal

Octal-Integer-Literal

Decimal-Integer-Literal

Hexadecimal-Integer-Literal

Binary Integer Literals

Syntax

Binary-Integer-Literal:

Unqualified-Binary-Integer-Literal

Qualified-Binary-Integer-Literal

Unqualified-Binary-Integer-Literal:

Binary-Digit

Binary-Integer-Literal Binary-Digit

Qualified-Binary-Integer-Literal:

Unqualified-Binary-Integer-Literal Binary-Radix

Binary-Digit:

0

1

Binary-Radix:

b

B

y

Y

Description

A base-2 number containing either of the digits 0 and 1.

Examples

The following are examples of unqualified binary integer literals:

10101
0
000001
1111000010101010

The following are examples of qualified binary integer literals:

00001111b
1111Y
00y
1111000010101010B

Octal Integer Literals

Syntax

Octal-Integer-Literal:

Unqualified-Octal-Integer-Literal

Qualified-Octal-Integer-Literal

Unqualified-Octal-Integer-Literal:

Octal-Digit

Octal-Integer-Literal Octal-Digit

Qualified-Octal-Integer-Literal:

Unqualified-Octal-Integer-Literal Octal-Radix

Octal-Digit: one of:

0 1 2 3 4 5 6 7

Octal-Radix:

o

O

q

Q

Description

A base-8 number containing any of the digits 0 through 7.

Examples

The following are examples of unqualified octal integer literals:

01234567
27
765

The following are examples of qualified octal integer literals:

Decimal Integer Literals

Syntax

Decimal-Integer-Literal:

Unqualified-Decimal-Integer-Literal

Qualified-Decimal-Integer-Literal

Unqualified-Decimal-Integer-Literal:

Decimal-Digit

Decimal-Integer-Literal Decimal-Digit

Qualified-Decimal-Integer-Literal:

Unqualified-Decimal-Integer-Literal Decimal-Radix

Decimal-Digit: one of:

0 1 2 3 4 5 6 7 8 9

Decimal-Radix:

d

D

t

T

Description

A base-10 number containing any of the digits 0 through 9.

Examples

The following are examples of unqualified decimal integer literals:

0123456789
19
090

The following are examples of qualified decimal integer literals:

01d
89t
4567D
0123456789T

Hexadecimal Integer Literals

Syntax

Hexadecimal-Integer-Literal:

Unqualified-Hexadecimal-Integer-Literal

Qualified-Hexadecimal-Integer-Literal

Unqualified-Hexadecimal-Integer-Literal:

Decimal-Digit

Hexadecimal-Integer-Literal Decimal-Digit

Hexadecimal-Integer-Literal Hexadecimal-Digit

Qualified-Hexadecimal-Integer-Literal:

Unqualified-Hexadecimal-Integer-Literal Hexadecimal-Radix

Decimal-Digit: one of:

0 1 2 3 4 5 6 7 8 9

Hexadecimal-Digit: one of:

a b c d e f
A B C D E F

Hexadecimal-Radix:

h

H

Description

A base-16 number using any combination of the digits 0 through 9 and the lowercase letters a through f or the uppercase letters A through F. The lowercase and uppercase representations of any given hexadecimal letter are equivalent.

Constraints

A hexadecimal integer literal may not begin with any of the alphabetic hexadecimal characters or it will be interpreted as an identifier; such numbers must be prefixed with the 0 digit.

Examples

The following are examples of unqualified hexadecimal integer literals:

01BD
9A
0AB

The following are examples of qualified hexadecimal integer literals:

1234ABCDh
01DH
0bh
1111FFFFH

Floating-Point Literals

Description

A floating-point literal is a notation for representing real numbers. The assembler provides both decimal and hexadecimal floating-point notations for representing real numbers.

Syntax

Floating-Point-Literal:

Decimal-Floating-Point-Literal

Hexadecimal-Floating-Point-Literal

Decimal Floating-Point Literals

Syntax

Decimal-Floating-Point-Literal:
Significand-Part
Significand-Part Exponent-Part

Significand-Part:
Digit-Sequence.Digit-Sequence
Digit-Sequence.

Exponent-Part:
E-Character Digit-Sequence
E-Character Sign Digit-Sequence

E-Character:
e
E

Sign:
-
+

Digit-Sequence:
Digit
Digit-Sequence Digit

Digit:one of:
0 1 2 3 4 5 6 7 8 9

Description

A decimal floating-point literal has a significand part that may be followed by an exponent part. The significand part consists of a digit sequence representing the whole-number part, followed by a period (.), followed by a digit sequence representing the fraction part. The exponent part consists of an introductory character (eor E), followed by an optional sign character (+or -), followed by a digit sequence representing the exponent.

Constraints

The introductory Digit-Sequence in the Significand-Part must be specified ( the literal cannot begin with a ".").

Examples

25.23 
2.523E1 
2523.0E-2

Hexadecimal Floating-Point Literals

Syntax

Hexadecimal-Floating-Point-Literal:
Hexadecimal-Literal Float-Radix

Hexadecimal-Literal:
Decimal-Digit
Hexadecimal-Literal Decimal-Digit
Hexadecimal-Literal Hexadecimal-Digit

Decimal-Digit:one of:
0 1 2 3 4 5 6 7 8 9

Hexadecimal-Digit:one of:
a b c d e f
A B C D E F

Float-Radix:
r
R

Description

A hexadecimal floating-point literal provides a means of initializing floating point values using a notation more closely tied to the internal machine representation than that of the Decimal-Floating-Point-Literal. Such literals are coded in a fashion similar to that of a normal Hexadecimal-Integer-Literal, but a different radix suffix is used to inform the assembler that the value is to be used in the allocation of real numbers rather than integers.

Constraints

A hexadecimal floating-point literal may not begin with any of the alphabetic hexadecimal characters or it will be interpreted as an identifier; such numbers must be prefixed with the 0 digit.

The literal must specify the correct number of hexadecimal digits according to the size of the real-number data-type to which it will be assigned. For REAL4, REAL8, and REAL10 variables, the respective number of digits in the literal must be 8, 16, and 20. For literals encoded with a leading zero, the respective number of digits must be 9, 17, and 21.

Examples

3F800000r

String Literals

Syntax

String-Literal:
D-String
S-String

D-String:
D-Quote D-Quote
D-Quote D-Char-Sequence D-Quote

S-String:
S-Quote S-Quote
S-Quote S-Char-Sequence S-Quote

D-Char-Sequence:
any printable character except D-Quote
D-Quote D-Quote

S-Char-Sequence:
any printable character except S-Quote
S-Quote S-Quote

D-Quote:
"

S-Quote:

Description

A string literal contains a sequence of zero or more characters enclosed in quotation mark symbols. Either a single (') or double (") quotation mark symbol may be used as the quote character that opens and closes the string literal. If a single quotation mark symbol is used as the quote character, then double quotation mark symbols may appear as data characters within the string literal, and vice versa. If the quote character must also appear as a character within the string literal, use two adjacent quote characters; this will allow a single occurrence of the quote character to be inserted into the string literal.

A quote character must be used to terminate the string literal before the end of the line is reached, otherwise an error message is issued and the literal is terminated by the end of line character. A string literal may span multiple lines only if a backslash (\) appears as the last non- whitespace character on the line, in which case the backslash, all surrounding whitespace characters, and the end of line character are deleted and the literal is continued with the first character on the next line.

Examples

'Hello, world'
"That's the way it is"
'Unless its not'
"SuperStringCon \
catenated"

Punctuators

Description

Punctuators are used as operators and separator characters.

Syntax

Punctuator:one of
[ ] ( ) { } * , : = ; %

Declarations

A Type Declaration is a language construct that specifies the characteristics of code and data objects used in a program.

Type Declarations

Description

A Type-Declaration is a common construct used in various assembler directives to establish type attribute information for a program object. A Type-Declaration is needed to determine the data type of a variable or labeled address. The TYPEDEF directive offers a method of assigning a name to a Type-Declaration.

Syntax

Type-Declaration:

TypeName

TypeName Array-Spec

Pointer-Spec

Pointer-Spec TypeName

Pointer-Spec TypeName Array-Spec

Pointer-Spec:

PTR

Distance-TypeName PTR

Pointer-Spec Array-Spec

Array-Spec:

[ Expression ]

Array-Spec [ Expression ]

TypeName:

Distance-TypeName

Scalar-TypeName

UserDefined-TypeName

Examples

The TYPEDEF directive is used to illustrate the type declaration syntax:

CHAR        typedef   byte               ;   Alias of intrinsic TypeName
PBYTE       typedef   ptr  byte          ;   Pointer to intrinsic TypeName
PCHAR       typedef   ptr  CHAR          ;   Pointer to TypeDef-TypeName
PPCHAR      typedef   ptr  PCHAR         ;   Pointer to a pointer to a CHAR
PPBYTE      typedef   ptr  ptr byte      ;   Similar to PPCHAR
PVOID       typedef   ptr                ;   Pointer to nothing (pointer to code)
PCODE       typedef   ptr  PROC          ;   Similar to PVOID
PFCODE      typedef   far  ptr far       ;   Far pointer to far code address

; vector declarations

ACHAR       typedef   CHAR[16]          ;   Array of 16 characters
AAWORD      typedef   word[2][2]        ;   multi-dimensional array
APBYTE      typedef   ptr[8] byte       ;   Array of 8 pointers to byte
APACHAR     typedef   ptr[4] ACHAR      ;   Array of 4 ptrs to arrays of 16 chars

SIZES_T     struct                     ;   define an intrinsic structure type
   little   byte      ?
   Medium   word      ? 
   BIG      dword     ? 
SIZES_T     ends 

SIZES       typedef   SIZES_T           ;   alias for intrinsic structure type
PSIZES      typedef   ptr SIZES_T       ;   and a type to point to it

PFORWARD    typedef   ptr FORWARD       ;   Pointers to forward-referenced types
FORWARD     struct                     ;   are assumed to be pointers to structs
   blah      word     ?
FORWARD     ends

Expressions

An expression is a sequence of operators and operands that are evaluated to derive a numeric result, an effective address, or a register operand.

Expressions are specified using standard infix notation, which is recursive in nature, ie., expressions may be nested within other expressions. The evaluation of an expression occurs in a left to right manner, and is influenced by the rules of operator precedence and associativity. The order in which expressions are evaluated can be controlled by grouping operands and operators together using parentheses ().

Expression Syntax

Description

This section describes the complete expression syntax.

Syntax

Expression:

Duplicative-Expression

Duplicative-Expression:

Attribute-Expression

Attribute-Expression DUP ( Initializer-List )

Attribute-Expression:

OR-Expression SHORT Additive-Expression

.TYPE OR-Expression

OPATTR OR-Expression

OR-Expression:

AND-Expression

OR-Expression OR AND-Expression

OR-Expression XOR AND-Expression

AND-Expression]]:

NOT-Expression]]

AND-Expression]] AND NOT-Expression

NOT-Expression]]:

Relational-Expression NOT Relational-Expression

Relational-Expression:

Additive-Expression

Relational-Expression EQ Additive-Expression

Relational-Expression NE Additive-Expression

Relational-Expression GT Additive-Expression

Relational-Expression GE Additive-Expression

Relational-Expression LT Additive-Expression

Relational-Expression LE Additive-Expression

Additive-Expression:'

Multiplicative-Expression

Additive-Expression + Multiplicative-Expression

Additive-Expression - Multiplicative-Expression

Multiplicative-Expression:

Narrowed-Expression

Multiplicative-Expression * Narrowed-Expression

Multiplicative-Expression / Narrowed-Expression

Multiplicative-Expression MOD Narrowed-Expression

Multiplicative-Expression SHL Narrowed-Expression

Multiplicative-Expression SHR Narrowed-Expression

Narrowed-Expression:

Cast-Expression

HIGH Cast-Expression

HIGHWORD Cast-Expression

LOW Cast-Expression

LOWWORD Cast-Expression

Cast-Expression:

Element-Selection-Expression

OFFSET Cast-Expression

SEG Cast-Expression

THIS Element-Selection-Expression

TYPE Element-Selection-Expression

Cast-Expression PTR Cast-Expression

Cast-Expression : Cast-Expression

Element-Selection-Expression:

Sign-Expression

Element-Selection-Expression

Sign-Expression

Element-Selection-Expression . Sign-Expression

Sign-Expression:

Primary-Expression

- Primary-Expression

+ Primary-Expression

Primary-Expression:

Literal-Operand

Record-Constant

Identifier-Operand

Register-Operand

Integral-TypeName-Operand

Value-Substitution-Operand

LENGTH Identifier-Operand

LENGTHOF Identifier-Operand

MASK Identifier-Operand

SIZE Element-Selection-Expression

SIZEOF Element-Selection-Expression

WIDTH Identifier-Operand

Parenthesized-Expression

Indirected-Expression

Compound-Initializer

Literal-Operand:

Floating-Point-Literal

Integer-Literal

String-Literal]]

Record-Constant:

Identifier-Operand < Field-List >

Identifier-Operand { Field-List }

Field-List:

Attribute-Expression

Field-List , Attribute-Expression

Identifier-Operand:

Identifier

Register-Operand:

Processor-Register

Integral-TypeName-Operand:

Scalar-TypeName

Distance-TypeName

Value-Substitution-Operand:

Anonymous-Label-Alias

Location-Counter-Alias

Indeterminate-Value-Alias

FLAT

Parenthesized-Expression:

( Attribute-Expression )

Indirected-Expression:

[ Attribute-Expression ]

Compound-Initializer:

< Initializer-List >

{ Initializer-List }

Initializer-List:

Duplicative-Expression

Initializer-List , Duplicative-Expression

Duplicative Initialization Expression

Description

A Duplicative Initialization Expression is one that can be optionally used during the initialization of variables such that the operand is duplicated a specified number of times.

Syntax

Duplicative-Expression:

Attribute-Expression

#DUP ( Initializer-List )

Initializer-List:

Duplicative-Expression

Initializer-List , Duplicative-Expression

Duplicative Initialization (DUP Operator)

Description

The DUP operator creates a Duplicated-ExpressionType from the Initializer-List enclosed in parentheses. This construct can be used to create arrays of information during data allocation.

Syntax

Attribute-Expression DUP (Initializer-List) Initializer-List: Duplicative-Expression Initializer-List,|Duplicative-Expression

Constraints

The left hand operand of the DUP operator must evaluate to an Absolute-ExpressionType.

Each Duplicative-Expression in the Initializer-List must evaluate to an Initializer-ExpressionType.

Examples

STR   STRUCT 
 One   BYTE  0
 Two   BYTE  0
STR   ENDS

Array1  WORD 4 DUP (1,2,3,4)         ; allocates 16 words
Array2  STR  8 DUP (<1,2>)           ; 8 structures

Attribute Expression

Description

An Attribute Expression is one that optionally extracts or modifies one or more of the basic properties of its operand.

Syntax

Attribute-Expression:

OR-Expression

SHORT Additive-Expression

.TYPE OR-Expression

OPATTR OR-Expression

Expression Descriptor Bitmap (.TYPE Operator)

Description

The .TYPE operator is considered obsolete. The #OPATTR operator should be used instead.

The .TYPE operator returns a byte value bitmap that describes various attributes of its operand. The return value is 0 if the expression could not be correctly parsed or evaluated, otherwise the bitmap returned is formatted according to the following table:

7	6	5	4	3	2	1	0	BIT SET IF EXPRESSION
							1	Is a Direct-ExpressionType
						1		Is a Indirect-ExpressionType, an Indexed-ExpressionType, or a combination of both
					1			Is an Immediate-ExpressionType
				1				Is an Indirect-ExpressionType
			1					Is a Register-ExpressionType
		1						Was parsed and evaluated without error (no undefined symbols, etc.)
	1							Is relative to the SS Segment-Register
1								Contains an External Reference

.TYPE OR-Expression

Syntax

.TYPE OR-Expression

Examples

BumpCounter macro bump 
  if (((.TYPE (bump)) and 07h) eq 04h)
     Counter = Counter + bump
  else
     .err <Non-constant value passed to BumpCounter>
  endif
endm

Extended Descriptor Bitmap (OPATTR Operator)

OPATTR OR-Expression

Syntax

OPATTR OR-Expression'

Description

The OPATTR operator returns a superset of the information returned by the .TYPE operator, which should be considered obsolete.

The OPATTR operator returns a word value bitmap that describes various attributes of its operand. The return value is 0 if the expression could not be correctly parsed or evaluated, otherwise the bitmap returned is formatted according to the following table:

A98	7	6	5	4	3	2	1	0	BIT SET IF EXPRESSION
								1	Is a Direct-ExpressionType
							1		Is a Indirect-ExpressionType, an Indexed-ExpressionType, or a combination of both
						1			Is an Immediate-ExpressionType
					1				Is an Indirect-ExpressionType
				1					Is a Register-ExpressionType
			1						Was parsed and evaluated without error (no undefined symbols, etc.)
		1							Is relative to the SS Segment-Register
	1								Contains an External Reference
LLL									Language encoding (described below)

The LLL field (bits 8, 9, and A) comprise an enumerated value that describes the language attribute assigned to the expression as follows:

000 No language attribute used in expression
001 C
010 SYSCALL
011 STDCALL
100 PASCAL
101 FORTRAN
110 BASIC
111 OPTLINK

Constraints

This operator is not available in M510 mode.

Examples

L_MASK     equ 011100000000y               ; mask to isolate language bits
L_OPTLINK  equ 011100000000y               ; setting for OptLink calling convention
VerifyCallBack   macro   ProcName 
  if (((OPATTR (ProcName)) and L_MASK) ne L_OPTLINK)
     .err <Call-back routine must have OptLink linkage>
  endif
endm

Force Short Relative Address (SHORT Operator)

Syntax

SHORT Additive-Expression

Description

The SHORT operator forces the assembler to calculate the distance from the start of the next instruction to the target specified by the operand (given by Additive-Expression) to be less than 128 bytes away. This can cause the assembler to generate more efficient control transfer instructions when the target is a forward reference. By default, the assembler assumes that the code-relative target is of NEAR distance when the target is an unqualified forward reference.

Constraints

The Additive-Expression must evaluate to a Direct-ExpressionType.

Examples

  JMP     Forward                ; target unknown, NEAR jump generated
  JMP     SHORT Forward          ; force SHORT encoding
  .
  .                      ; fewer than 128 bytes of instructions
  .
Forward:                 ; definition of target

Bitwise OR Expression

Description

A Bitwise OR Expression is one where an optional binary bitwise OR operation between the left and right operands is performed and the result returned.

Syntax

OR-Expression: AND-Expression OR-Expression OR AND-Expression OR-Expression XOR AND-Expression

Bitwise Inclusive OR (OR Operator)

Syntax

OR-Expression OR AND-Expression

Description

The OR operator performs a binary bitwise OR operation on the left and right hand operands.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

One  EQU  1
Two  EQU  2

MOV  AX, One OR Two        ; moves 3 into AX

Bitwise Exclusive OR (XOR Operator)

Syntax

OR-Expression XOR AND-Expression

Description

The XOR operator performs a binary bitwise XOR operation on the left and right hand operands.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

Lower  EQU  0101y          ; 7h - binary radix suffix
Upper  EQU  1100y          ; Eh - binary radix suffix

MOV  AX, Upper XOR Lower   ; moves 1001 into AX

Bitwise AND Expression

Description

A Bitwise AND Expression is one where an optional binary bitwise AND operation between the left and right operands is performed and the result returned.

Syntax

AND-Expression:

NOT-Expression

AND-Expression AND NOT-Expression

Bitwise AND (AND Operator)

Syntax

AND-Expression AND NOT-Expression

Description

The AND operator performs a binary bitwise AND operation on the left and right hand operands.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

Lower  EQU  0111y           ; 7h - binary radix suffix
Upper  EQU  1110y           ; Eh - binary radix suffix

MOV  AX, Upper XOR Lower    ; moves 0110 into AX

Bitwise One's Complement Expression

Description

A Bitwise One's Complement Expression is one that performs an optional unary bitwise negation of its operand and returns the result.

Syntax

NOT-Expression: Relational-Expression NOT Relational-Expression

Bitwise One's Complement (NOT Operator)

Syntax

NOT Relational-Expression

Description

The NOT operator performs a unary bitwise negation on its operand.

Constraints

The operand must evaluate to a Constant-ExpressionType.

Examples

  Value  EQU 0111y          ; 7h - binary radix suffix

  MOV    EAX, NOT Value     ; moves FFFFFFF8 into EAX

Relational Expression

Description

A Relational Expression is one where an optional binary comparision operation between the left and right operands is performed and the result returned.

Syntax: Relational-Expression:; Additive-Expression; Relational-Expression EQ Additive-Expression; Relational-Expression NE Additive-Expression; Relational-Expression GT Additive-Expression; Relational-Expression GE Additive-Expression; Relational-Expression LT Additive-Expression; Relational-Expression LE Additive-Expression

Equal To (EQ Operator)

Syntax: Relational-Expression EQ Additive-Expression

Description

The EQ operator performs a binary logical comparision on the left and right hand operands. It returns true (all bits on) if they are equal, and false (all bits off) if they are not equal.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

  IF 1234 EQ 5678
    TRUE = 1
  ELSE
    TRUE = 0                ; Sets TRUE to 0
  ENDIF

Not Equal To (NE Operator)

Syntax: Relational-Expression NE Additive-Expression

Description

The NE operator performs a binary logical comparision on the left and right hand operands. It returns true (all bits on) if they are not equal, and false (all bits off) if they are equal.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

IF 1234 NE 5678
    TRUE = 1                ; Sets TRUE to 1
ELSE
    TRUE = 0
ENDIF

Greater Than (GT Operator)

Syntax: Relational-Expression GT Additive-Expression

Description

The GT operator performs a binary logical comparision on the left and right hand operands. It returns true (all bits on) if the left operand is greater than the right operand, and false (all bits off) if it is not.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

IF 1234 GT 5678 
  TRUE = 1 
ELSE 
  TRUE = 0              ; Sets TRUE to 0
ENDIF

Greater Than or Equal To (GE Operator)

Syntax: Relational-Expression GE Additive-Expression

Description

The GE operator performs a binary logical comparision on the left and right hand operands. It returns true (all bits on) if the left operand is greater than or equal to the right operand, and false (all bits off) if it is not.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

IF 1234 GE 1234 
    TRUE = 1                ; Sets TRUE to 1
ELSE 
    TRUE = 0 
ENDIF

Less Than (LT Operator)

Syntax: Relational-Expression LT Additive-Expression

Description

The LT operator performs a binary logical comparision on the left and right hand operands. It returns true (all bits on) if the left operand is less than the right operand, and false (all bits off) if it is not.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

  IF 1234 LT 5678
      TRUE = 1               ; Sets TRUE to 1
  ELSE
      TRUE = 0
  ENDIF

Less Than or Equal To (LE Operator)

Syntax: Relational-Expression LE Additive-Expression

Description

The LE operator performs a binary logical comparision on the left and right hand operands. It returns true (all bits on) if the left operand is less than or equal to the right operand, and false (all bits off) if it is not.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

  IF 1234 LE 1234
    TRUE = 1                  ; Sets TRUE to 1
  ELSE 
    TRUE = 0
  ENDIF

Additive Expression

Description

A Additive Expression is one where an optional binary additive arithmetic operation between the left and right operands is performed and the result returned.

Syntax: Additive-Expression:; Multiplicative-Expression; Additive-Expression + Multiplicative-Expression; Additive-Expression - Multiplicative-Expression

Addition (+ Operator)

Syntax: Additive-Expression + Multiplicative-Expression

Description

The + operator performs a binary addition operation on the left and right hand operands, and returns the result.

Constraints

One of the operands must evaluate to a Constant-ExpressionType. If one of the operands references an external identifier, then the other operand must be a Constant-ExpressionType without an external reference. Both operands must be of scalar type.

Examples

 VALUE = 100 + 11          ; sets VALUE to 111

Subtraction (- Operator)

Syntax: Additive-Expression - Multiplicative-Expression

Description

The - operator performs a binary subtraction operation on the left and right hand operands, and returns the result.

Constraints

The right operand must evaluate to a Constant-ExpressionType and reference no external identifiers. If both operands are relocatable, they must reside within the same segment, in which case the result is converted to a Absolute-ExpressionType. Both operands must be of scalar type.

Examples

 VALUE = 111 - 11           ; sets VALUE to 100

Multiplicative Expression

Description

A Multiplicative Expression is one where an optional binary multiplicative arithmetic operation between the left and right operands is performed and the result returned.

Syntax: Multiplicative-Expression:; Narrowed-Expression; Multiplicative-Expression * Narrowed-Expression; Multiplicative-Expression / Narrowed-Expression; Multiplicative-Expression MOD Narrowed-Expression; Multiplicative-Expression SHL Narrowed-Expression; Multiplicative-Expression SHR Narrowed-Expression

Multiplication (* Operator)

Syntax: Multiplicative-Expression * Narrowed-Expression

Description

The * operator performs a binary multiplication operation on the left and right hand operands, and returns the result.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

 VALUE = 9 * 3                 ; sets VALUE to 27

Division (/ Operator)

Syntax: Multiplicative-Expression / Narrowed-Expression

Description

The / operator performs a binary division operation on the left and right hand operands, and returns the result.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

 VALUE = 27 / 9                ; sets VALUE to 3

Remainder (MOD Operator)

Syntax: Multiplicative-Expression MOD Narrowed-Expression

Description

The MOD operator performs a binary modulus division operation on the left and right hand operands, and returns the remainder as the result.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

 VALUE = 18 MOD 4              ; sets VALUE to 2

Bitwise Left Shift (SHL Operator)

Syntax: Multiplicative-Expression SHL Narrowed-Expression

Description

The SHL operator shifts the bits in the left hand operand to the left by the number of bits specified in the right hand operand, and returns the result.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

 VALUE = 1111y SHL 4          ; sets VALUE to 11110000y

Bitwise Right Shift (SHR Operator)

Syntax: Multiplicative-Expression SHR Narrowed-Expression

Description

The SHR operator shifts the bits in the left hand operand to the right by the number of bits specified in the right hand operand, and returns the result.

Constraints

Each operand must evaluate to a Constant-ExpressionType.

Examples

 VALUE = 11110000y SHR 4      ; sets VALUE to 00001111y

Narrowed Expression

Description

A Narrowed Expression is one that performs an optional unary narrowing operation on its operand and returns the result.

Syntax

Narrowed-Expression:

Cast-Expression HIGH Cast-Expression

HIGHWORD Cast-Expression

LOW Cast-Expression

LOWWORD Cast-Expression

Upper 8 Bits of WORD Expression (HIGH Operator)

Syntax: HIGH Cast-Expression

Description

The HIGH operator returns the upper 8 bits of a 16-bit expression. Only bits 8-15 are returned, even if the magnitude of the operand exceeds 16 bits.

Constraints

The operand must evaluate to a Constant-ExpressionType.

Examples

 FIRST  = 1234h
 SECOND = HIGH FIRST        ; Sets SECOND to 12h

Upper 16 Bits of DWORD Expression (HIGHWORD Operator)

Syntax: HIGHWORD Cast-Expression

Description

The HIGHWORD operator returns the upper 16 bits of a 32-bit expression. Only bits 16-31 are returned, even if the magnitude of the operand exceeds 32 bits.

Constraints

The operand must evaluate to a Constant-ExpressionType.

This operator is not available in M510 mode.

Examples

 FIRST  = 12345678h 
 SECOND = HIGHWORD FIRST    ; Sets SECOND to 1234h

Lower 8 Bits of WORD Expression (LOW Operator)

Syntax: LOW Cast-Expression

Description

The LOW operator returns the lower 8 bits of its operand.

Constraints

The operand must evaluate to a Constant-ExpressionType.

Examples

 FIRST  = 1234h
 SECOND = LOW FIRST         ; Sets SECOND to 34h

Lower 16 Bits of DWORD Expression (LOWWORD Operator)

Syntax: LOWWORD Cast-Expression

Description

The LOWWORD operator returns the lower 16 bits of its operand.

Constraints

The operand must evaluate to a Constant-ExpressionType.

This operator is not available in #M510 mode.

Examples

 FIRST  = 12345678h
 SECOND = LOWWORD FIRST     ; Sets SECOND to 5678h

Type Conversion Expression

Description

A Type Conversion Expression is one that performs an optional type conversion operation on its operand and returns the result.

Syntax

Cast-Expression:

Element-Selection-Expression

OFFSET Cast-Expression

SEG Cast-Expression

THIS Element-Selection-Expression

TYPE Element-Selection-Expression

Cast-Expression PTR Cast-Expression

Cast-Expression : Cast-Expression

Address Offset (OFFSET Operator)

Description

The OFFSET operator returns the offset portion of its operand. For relocatable values, this is the offset into the segment or group to which the expression is relative.

Syntax

OFFSET Cast-Expression

Constraints

The operand may evaluate to any one of the following #ExpressionTypes:

Absolute-ExpressionType
Constant-ExpressionType
Immediate-ExpressionType
Direct-ExpressionType
Indirect-ExpressionType

Examples

CodeLabel:
       MOV   AX, CodeLabel            ; illegal, no data at address 
       MOV   AX, OFFSET   CodeLabel   ; we want the address itself

Address Segment (SEG Operator)

Syntax

SEG Cast-Expression

Description

The SEG operator returns the segment or group to which a relocatable expression is relative.

Constraints

The operand must evaluate to one of the following ExpressionTypes:

Immediate-ExpressionType
Direct-ExpressionType
Indirect-ExpressionType
Indexed-ExpressionType

Examples

DATA    SEGMENT 
Stuff   DB    ? 
        MOV   AX, SEG Stuff    ; This construct is
        MOV   AX, DATA         ; equivalent to this
DATA    ENDS

Address Alias (THIS Operator)

Syntax

THIS Element-Selection-Expression

Description

The THIS operator returns an operand whose:

Relative Frame attribute is set to that of the current segment
Displacement attribute is set to the current location counter
Type Declaration attribute is set to that of the expression given by the Element-Selection-Expression operand.

Constraints

The operand must evaluate to a Type-ExpressionType.

Examples

DATA      SEGMENT

ALIAS   EQU   THIS BYTE        ; reference this address as a byte
Stuff   DB    ? 
        MOV   AL, ALIAS        ; This construct is
        MOV   AL, Stuff        ; equivalent to this
DATA    ENDS

Datatype Extraction (TYPE Operator)

Syntax

TYPE Element-Selection-Expression

Description

The TYPE operator returns the Type-ExpressionType attribute of its operand.

Constraints

None

Examples

CODE    SEGMENT 
        ASSUME  CS:CODE, DS:CODE
Stuff   DB      ?                        ; TYPE Stuff is BYTE
        MOV     [BX],(TYPE Stuff) PTR 1  ; stores 1 as a BYTE at [BX]
CODE    ENDS

Type Conversion (PTR Operator)

Syntax

Cast-Expression PTR Cast-Expression

Description

The PTRoperator converts the right operand to the type specified by the left operand.

Constraints

The left operand must be a Type-ExpressionType.

Examples

CODE     SEGMENT 
         MOV  BYTE PTR [BX], 1    ; stores 1 as a BYTE at [BX]
CODE     ENDS

Segment Override (: Operator)

Syntax

Cast-Expression : Cast-Expression

Description

The : (colon) operator forces the right operand to have the Relative Frame attribute of the left operand.

Constraints

The left operand must evaluate to one of the following #ExpressionTypes:

Register-ExpressionType where the Register Value attribute is that of a Segment-Register
Immediate-ExpressionType where the Relative Frame attribute is that of a GroupName or SegmentName.

Examples

DATA       SEGMENT
Variable   DW    ?
DATA       ENDS

DGROUP     GROUP DATA, CODE

CODE       SEGMENT
  ASSUME   CS:CODE, DS:DGROUP
  MOV      AX, DGROUP:Variable         ; insure Variable is relative to DGROUP
  ASSUME   DS:NOTHING
  MOV      BX, CS:Variable             ; access Variable through CS register
CODE       ENDS

Element Selection Expression

Description

A Element Selection Expression is one that optionally selects a specific element of its operand and returns a reference to it.

Syntax

Element-Selection-Expression:

Sign-Expression]]

Element-Selection-Expression [Sign-Expression]

Element-Selection-Expression .Sign-Expression

Subscript ([] Operator)

Syntax

Element-Selection-Expression [ Sign-Expression ]

Description

The [] binary operator performs a subscripting (or indexing) operation between the operand to the left of the brackets and the operand enclosed within the brackets. This is a simple additive operation of BYTE granularity; the arithmetic performed is not influenced by the Operand Size of either operand.

The syntax for this operator describes a binary operation between the left hand expression and the bracketed expression. The bracketed expression is also subject to the same operations performed during the processing of a standalone Indirected-Expression as described in the section on Primary-Expressions.

Constraints

Only one of the operands may specify a relocatable value.

Examples

CODE    SEGMENT 
        ASSUME  CS:CODE, DS:CODE

Value    DB    0                         ;   Value [0]
         DB    1                         ;   Value [1]
         DB    2                         ;   Value [2]
         DB    3                         ;   Value [3]
         DB    4                         ;   Value [4]

  MOV      AL, Value [3]        ;   load AL with the fourth byte at Value (3)
  MOV      BX, offset Value     ;   get address of Value 
  MOV      AL, [BX] [1] [2]     ;   also gets the fourth byte ( 3 ) 

CODE     ENDS

Structure/Union Field Selection (. Operator)

Syntax

Element-Selection-Expression . Sign-Expression

Description

The . (period) operator selects a structure or union field entry. It adds the left and right hand operands together and returns the result. The left operand should be an Indirect-ExpressionType, Indexed-ExpressionType, or Type-ExpressionType whose Type Declaration attribute resolves to that of a Structure-TypeName or Union-TypeName. The right operand should refer to a FieldName defined within the referenced type.

The Operand Size attribute of the result depends on the operands involved. If both operands have an operand size, a Structure-FieldName appearing as the right hand operand would override the operand size of the left operand and would dictate the operand size of the resulting expression.

Constraints

Only one of the operands may specify a relocatable value.

Examples

Number   STRUC
  One    DB   1
  Two    DW   2
Number   ENDS

; The following line is only allowed in MASM 5.10 mode ( OPTION OLDSTRUCTS ) 

  MOV   AX,[BX] .Two         ;  BX points to a "Number", get the "Two" entry 

; In other modes, "Two" is private to the "Number" structure type, so 
; one of the following methods are required : 

  MOV   AX,(Number PTR[BX]).Two  ; Explicit override
  MOV   AX,[BX] + Number.Two     ; Fully qualified reference
  ASSUME BX:Number               ; Associate BX with "Number"
  MOV   AX,[BX].Two              ; then original syntax is allowed

Unary Arithmetic Expression

Description

A Unary Arithmetic Expression is one that optionally alters the sign of its operand and returns the result.

Syntax

Sign-Expression:

Primary-Expression

-Primary-Expression

+Primary-Expression

Unary Minus (- Operator)

Syntax

- Primary-Expression

Description

The - operator makes its operand into a negative number and returns the result.

Constraints

The operand must evaluate to a Constant-ExpressionType.

Examples

Value  EQU  1

MOV  AX, -Value     ; move -1 into AX

Unary Plus (+ Operator)

Syntax

+ Primary-Expression

Description

The + operator returns its operand.

Constraints

The operand must evaluate to a Constant-ExpressionType.

Examples

Value EQU 1 
MOV   AX,+Value  ; move 1 into AX

Primary Expression

Description

A Primary Expression is one that returns an expression operand.

Syntax

Primary-Expression:

Literal-Operand

Record-Constant

Identifier-Operand

Register-Operand

Integral-TypeName-Operand

Value-Substitution-Operand

LENGTH Identifier-Operand

LENGTHOF Identifier-Operand

MASK Identifier-Operand

SIZE Element-Selection-Expression

SIZEOF Element-Selection-Expression

WIDTH Identifier-Operand

Parenthesized-Expression

Indirected-Expression

Compound-Initializer

Literal Operand

Syntax

Literal-Operand:

Floating-Point-Literal

Integer-Literal

String-Literal

Description

The assembler accepts several types of literal values as operands within expressions. Literal-Operands are converted to #ExpressionTypes according to the following table:

Floating-Point-Literal	Floating-Point-ExpressionType
Integer-Literal	Absolute-ExpressionType
String-Literal	Absolute-ExpressionType if the string length is less than or equal to the current Address Size; a String-ExpressionType otherwise.

The context where the expression is used determines whether or not a particular type of literal is legal.

Constraints

Arithmetic operations cannot be performed on #Floating-Point-Literals, thus they cannot be the operand of a unary or binary operator.

Value Substitution Operand

Syntax

Value-Substitution-Operand:

Anonymous-Label-Alias

Location-Counter-Alias

Indeterminate-Value-Alias

FLAT

Description

These operands are used to retrieve specialized values that are calculated internally by the assembler.

The FLAT operator returns an expression whose #Relative Frame is set to that of the predefined FLAT pseudo-group.

Constraints

The FLAT operand is only active when a 32-bit processor has been selected.

Record Constant Operand

Syntax

Record-Constant:

Identifier-Operand < Field-List >

Identifier-Operand { Field-List }

Field-List:

Attribute-Expression

Field-List , Attribute-Expression

Description

A Record-Constant provides a method of calculating a single numeric result value from a list of Record-FieldName values, and combining them together according to the definition of the Record-TypeName given by the Identifier-Operand. The result value is a Constant-ExpressionType suitable for use as an instruction operand, or for assigning to a record variable.

The Record-TypeName given by the Identifier-operand determines how the Field-List will be evaluated. The Attribute-Expression entries are position-dependent, and are matched with the corresponding Record-FieldName entries from the Record-TypeName definition to determine their width and shift values. Attribute-Expression entries may be omitted, in which case the default values from the record definition are used in the calculation.

Constraints

The Identifier-Operand must resolve to a Record-TypeName.

Examples

 DATE_T   record   Year  : 7 = 0,   ; 0 is 1980
                   Month : 4 = 1,   ; January
                   Day   : 5 = 1    ; 1st
 
 CODE SEGMENT
   mov  AX,DATE_T  < >                       ; January 1st, 1980
   mov  AX,DATE_T  < 1996 - 1980, 12, 25 >   ; Christmas, 1996
   mov  AX,DATE_T  < 10h, 0Ch, 19h >         ; equivalent values in hex
   mov  AX,DATE_T  < 10000y, 1100y, 11001y > ; equivalent values in binary
   mov  AX,2199h                             ; equivalent value manually coded
   mov  AX,0010000110011001y                 ; and in binary
 ;         YYYYYYYMMMMDDDDD
 CODE   ENDS

Register Operand

Syntax

Register-Operand:

Processor-Register

Description

Processor registers are valid expression operands. The context where the expression is used determines the allowable register operands.

Constraints

The currently selected processor dictates whether or not a register is visible to the expression evaluator.

Identifier Operand

Syntax

Identifier-Operand:

Identifier

Description

When an Identifier is used in an expression, it returns a value according to its Identifier-Type, as shown in the following table:

Identifier-Type	VALUE RETURNED
Numeric-EquateName	The value originally assigned to the equate.
Structure-FieldName	The offset in bytes from the beginning of the structure.
Union-FieldName	The offset in bytes from the beginning of the union (always 0).
Record-FieldName	The shift-count required to reach the field within the record.
Record-TypeName	The mask-value that isolates defined record fields from undefined fields.
Structure-TypeName	Zero if mode is M510, otherwise the size of the structure in bytes (the operand size of the structure type).
Union-TypeName	The size of the union in bytes (the operand size of the union type).
Typedef-TypeName	The operand size of the underlying data-type represented by the Typedef-TypeName.
GroupName	A Relative Frame attribute that represents the group, and a Displacement value of zero.
SegmentName	A Relative Frame attribute that represents the segment (or the group to which it belongs), and a Displacement value of zero if the mode is M510, or the current segment offset otherwise.
LabelName	The Relative Frame attribute where the label is defined, and the segment offset value of the label.

Constraints

The Identifier must resolve to one of the following Identifier-Types:

Numeric-EquateName
FieldName
GroupName
LabelName
SegmentName
UserDefined-TypeName

Integral Type-Name Operand

Syntax

Integral-TypeName-Operand:

Scalar-TypeName

Distance-TypeName

Description

When an Integral-TypeName-Operandis used in an expression, it is converted to a Type-ExpressionType. If used in a numeric context, the following numeric values are returned:

Integral-TypeName-Operand	VALUE RETURNED
Scalar-TypeName	The operand-size of the type in bytes.
Distance-TypeName	If mode is M510, NEAR returns FFFF, and FAR returns FFFE. Otherwise, NEAR and FAR are resolved and the values returned are: NEAR16=FF02, NEAR32=FF04, FAR16=FF05, FAR32=FF06.

Constraints

The NEAR32 and FAR32 keywords are only valid if a 32-bit processor has been selected.

Number of Data Elements (LENGTH Operator)

Syntax

LENGTH Identifier-Operand

Description

The LENGTH operator returns the number of data elements allocated to the operand. When applied to a variable initialized with a series of comma-separated expressions (elements), only the length of the first element is considered.

Constraints

The operand must evaluate to a Data-LabelName.

Number of Data Elements (LENGTHOF Operator)

Syntax

LENGTHOF Identifier-Operand

Description

The LENGTHOF operator returns the number of data elements allocated to the operand.

Constraints

The operand must evaluate to a Data-LabelName.

This operator is not available in M510 mode.

Examples

<none>

Record or Field Bit-Mask (MASK Operator)

Syntax

MASK Identifier-Operand

Description

The MASK operator returns the bit mask required to isolate a field within a record.

Constraints

The Identifier-Operand must resolve to a Record-TypeName or Record-FieldName; otherwise the result is zero.

Size of Variable in Bytes (SIZE Operator)

Syntax

SIZE Element-Selection-Expression

Description

The SIZE operator returns the number of bytes allocated to the operand. When applied to a variable initialized with a series of comma-separated expressions (elements), only the size of the first element is considered.

Constraints

None

Size of Variable in Bytes (SIZEOF Operator)

Syntax

SIZEOF Element-Selection-Expression

Description

The SIZEOF operator returns the number of bytes allocated to the operand.

Constraints

This operator is not available in M510 mode.

Record or Field Width (WIDTH Operator)

Syntax

WIDTH Identifier-Operand

Description

The WIDTHoperator returns the width of a record or a record field name.

Constraints

The Identifier-Operand must resolve to a Record-TypeName or Record-FieldName; otherwise the result is zero.

Precedence (() Operator)

Syntax

Parenthesized-Expression:

( Attribute-Expression )

Description

Parentheses forces the Attribute-Expression operand to be evaluated at a higher precedence level.

Examples

Value =   2 + 3   * 4     ; Value = 14 
Value = ( 2 + 3 ) * 4     ; Value = 20

Indirection ([] Operator)

Syntax

Indirected-Expression:

[ Attribute-Expression ]

Description

During evaluation of the Attribute-Expression, the [](indirection) operator will convert a Register-ExpressionType to a Indexed-ExpressionType by moving the Register Value attribute to either the Base Register or Index Register attribute field as appropriate for the register(s) referenced in the expression. This operation allows values contained in the processor registers to be used during effective address calculation at application run time.

Constraints

See the Indexed-ExpressionType section for information on registers that are valid for use in this context.

Examples

CODE      SEGMENT 
          ASSUME   CS : CODE ,   DS : CODE 
Value     DW     0 
          MOV    BX , offset   Value        ; load the address of Value into BX
          MOV    [ BX ] , BX                ; store the contents of BX into the
                                            ; memory location addressed by [BX]
CODE       ENDS

Compound Initializer List (<> Operator)

Syntax

Compound-Initializer:

< Initializer-List >

{ Initializer-List }

Initializer-List:

Duplicative-Expression

Initializer-List , Duplicative-Expression

Description

The <> (or {}) operator provides a way of specifying a list of expressions to be used for initializing complex (multi-field) variables such as records or structures.

The <> operator encloses a list of comma-separated expressions; individual expressions are optional, but are also positional with respect to the record or structure fields they are intended to initialize. Commas must therefore be used to maintain field positions if empty expressions are encountered in the list.

The initializer list itself may also be left out entirely for those cases where a variable allocation will use the default initializers provided in the record or structure definition (the <>or {} themselves are still required).

Examples

Numbers   STRUCT
  One     DB     0
  Two     DW     0
  Three   DB     0
  Four    DD     0
Numbers   ENDS

First    Numbers   < >               ;  empty initializer list
Second   Numbers   < 1, 2, 3, 4 >    ;  override all defaults
Third    Numbers   < 1 >             ;  override first entry only
Fourth   Numbers   < 1, , , 4 >      ;  override first and last entries

Expression Evaluation

After an expression is parsed and checked for syntax errors, it is evaluated. During evaluation, all calculations and conversions are performed on the operands according to the operators that are applied to them. The final result is a collection of #Expression-Attributes, to which an ExpressionType is assigned.

Expression Attributes

This section describes the Expression-Attributesthat are associated with an expression after it is evaluated.

Address Size

If an expression refers to an effective address, then it also has an associated #address size. The following #ExpressionTypes normally reference an effective address, and thus have an associated address size:

Immediate-ExpressionType
Direct-ExpressionType
Indirect-ExpressionType
Indexed-ExpressionType

The address size can be either 2 (USE16) or 4 (USE32). For an expression that references a label, the address size of the segment where the label is defined determines the address size of the expression.

Operand Size

The Operand Size of an expression can be set explicitly using the #Type Conversion (PTR Operator), or it may be a side-effect inherited from the type of data referenced in the expression. The following table describes the operand sizes that will be assigned when an identifier is referenced in an expression:

REFERENCE	OPERAND SIZE
8-Bit-Register	1
16-Bit-Register	2
32-Bit-Register	4
Segment-Register	2
Control-Register	4
Debug-Register	4
Test-Register	4
MMX-Register	8
Floating-Point-Register	10
BYTE	1
SBYTE	1
WORD	2
SWORD	2
DWORD	4
SDWORD	4
REAL4	4
FWORD	6
QWORD	8
REAL8	8
TBYTE	10
REAL10	10
NEAR	2 or 4
NEAR16	2
NEAR32	4
FAR	4 or 6
FAR16	4
FAR32	6
Numeric-EquateName	Inherited from equate expression
GroupName	2
SegmentName	2
Code-LabelName	SIZE (TYPE Code-LabelName)
Data-LabelName	SIZE (TYPE Data-LabelName)
Structure-FieldName	SIZE Structure-FieldName
Record-TypeName	SIZE Record-TypeName
Structure-TypeName	SIZE Structure-TypeName
Union-TypeName	SIZE Union-TypeName

The Operand Size is 0 for all other identifier types.

Displacement

The Displacement value in an expression is the final calculated value of all numeric quantities, and must be a scalar value. It may also be a reference to a relocatable address, in which case the expression will also have a Relative Frame and/or an External Reference attribute. A Displacement may be used in the calculation of an effective address, either alone or in combination with a Base Register and/or an Index Register.

Relative Frame

The Relative Frame attribute will be present if the expression contains a direct or indirect reference to any of the following #Identifier-Types:

GroupName
LabelName
SegmentName

The Relative Frame attribute indicates that the expression is relocatable, and specifies the GroupName or SegmentName to which the expression is relative.

External Reference

The External Reference attribute will be present if the expression references any external identifiers.

Register Value

The Register Value attribute specifies the value of the Processor-Register referenced in a Register-ExpressionType.

Base Register

The Base Register attribute specifies the value for the base register used in an Indexed-ExpressionType.

Index Register

The Index Register attribute specifies the value for the index register used in an Indexed-ExpressionType.

Scale Factor

The Scale Factor attribute specifies the scaling value used (if any) in an Indexed-ExpressionType.

Type Declaration

The Type Declaration attribute specifies the type of data referenced in the expression. This is the value extracted from the expression when it is used as the left operand of the #Type Conversion (PTR Operator).

Expression Types

Description

An ExpressionType is assigned to every expression during evaluation. The ExpressionType is used to determine whether or not an expression is legal for the context in which it is used. The type of an expression is influenced primarily by the operands that are used, but the use of expression operators also play an important part in determining the type of an expression.

Definition

ExpressionType:

Absolute-ExpressionType

Constant-ExpressionType

Direct-ExpressionType

Floating-Point-ExpressionType

Immediate-ExpressionType

Indirect-ExpressionType

Indexed-ExpressionType

Register-ExpressionType

String-ExpressionType

Type-ExpressionType

Duplicated-ExpressionType

Compound-ExpressionType

Absolute Expression Type

An Absolute-ExpressionType is an expression that evaluates to an integer quantity. Its value must be representable using one of the following types of scalar data:

BYTE
SBYTE
WORD
SWORD
DWORD
SDWORD
FWORD
QWORD
TBYTE

The following restrictions apply to an Absolute-ExpressionType:

It cannot be relocatable (it may not contain references to a GroupName, SegmentName or LabelName).
It cannot reference any external symbols.
It cannot contain any forward references.

Constant Expression Type

A Constant-ExpressionType is an Absolute-ExpressionType with the following restrictions relaxed:

It may contain forward references to identifiers defined later in the source stream.
It may reference a single external symbol, provided that the symbol was declared in an EXTERN directive with the ABS attribute.

Immediate Expression Type

An Immediate-ExpressionType has all the properties of a Constant-ExpressionType with the following restrictions relaxed:

It may contain references to a GroupName, SegmentName or LabelName(it may be relocatable).
It may reference a relocatable external symbol.

An Immediate-ExpressionType must not be larger than 32 bits in magnitude; its value must be representable using one of the following types of scalar data:

BYTE
SBYTE
WORD
SWORD
DWORD
SDWORD

Direct Expression Type

A Direct-ExpressionType is an expression that references a Code-LabelName. It can be used directly in code-relative instructions without conversion. There is no data type associated with the address that a Direct-ExpressionType represents, therefore It may not be used in a data-relative instruction without first being explicitly converted to another expression type.

Indirect Expression Type

An Indirect-ExpressionType is an expression that references a Data-LabelName. It can be used directly in data-relative instructions without conversion to another expression type.

Indexed Expression Type

An Indexed-ExpressionType is an expression that calculates an effective memory address using the contents of a Base-Register, an Index-Register, or both. A Processor-Register must first be converted to a Base-Register or Index-Register by specifying it as the operand of the [[#Indirection ([] Operator)]]before the expression can be converted to an Indexed-ExpressionType.

When calculating a 16-bit effective address, only the BP and BX registers may be used as Base-Registers, and only the DI and SI registers may be used as Index-Registers.

When calculating a 32-bit effective address, only the EAX, EBX, ECX, EDX, EDI, ESI, EBP, and ESP registers may be used as Base-Registers, and only the EAX, EBX, ECX, EDX, EDI, ESI, and EBP registers may be used as Index-Registers.

Note: Only a single Base-Register and a single Index-Register may be used in a given expression.

On 80386 (and higher) processors, the #Multiplication (* Operator) may be used with an Index-Registeroperand and an Absolute-ExpressionType operand to establish a scaling factor that is applied to the Index-Register during effective address calculation. The scaling factor effectively causes the Index-Register to be multiplied by a fixed value at run time. The scaling Expression must evaluate to 1 (no scale factor), 2, 4, or 8.

A Direct-ExpressionType or an Indirect-ExpressionType may be a sub-expression of an Indexed-ExpressionType.

Register Expression Type

A Register-ExpressionType is an expression that specifies a single Processor-Register.

String Expression Type

A String-ExpressionType is an expression that specifies a single String- Literal.

Floating-Point Expression Type

A Floating-Point-ExpressionType is an expression that specifies a single Floating-Point-Literal.

Type Expression Type

A Type-ExpressionTypeis an expression that specifies one of the following:

A Scalar-TypeName
A Distance-TypeName
A UserDefined-TypeName

Compound Expression Type

A Compound-ExpressionType evaluates to a list of (possibly nested) expressions collected together as a unit by the #Compound Initializer List ( <> Operator). A Compound-ExpressionTypeis used to initialize #aggregate data types (such as records, structures, and unions) and #vector data types (arrays).

Duplicated Expression Type

A Duplicated-ExpressionType evaluates to an expression that is to be duplicated (repeated) a specified number of times. This type of expression is created using the #Duplicative Initialization (DUP Operator).

Operand Expression Type

An Operand-ExpressionType consists of those #ExpressionTypes that are valid for use as operands in processor instructions. The following ExpressionTypes are not valid for use as an Operand-ExpressionType:

Compound-ExpressionType
Duplicated-ExpressionType
A String-ExpressionType is only valid as an Operand-ExpressionType if it is short enough to be converted to an Absolute-ExpressionType having an Operand Size less than or equal to the current Address Size setting.

Operand-ExpressionType:

Absolute-ExpressionType

Constant-ExpressionType

Immediate-ExpressionType

Direct-ExpressionType

Indirect-ExpressionType

Indexed-ExpressionType

Register-ExpressionType

String-ExpressionType

Floating-Point-ExpressionType

Type-ExpressionType

Description

An Operand-ExpressionTypeconsists of those #ExpressionTypes that are valid for use as operands in processor instructions. The following ExpressionTypes are not valid for use as an Operand-ExpressionType:

Compound-ExpressionType
Duplicated-ExpressionType

A String-ExpressionType is only valid as an Operand-ExpressionType if it is short enough to be converted to an Absolute-ExpressionType having an Operand Size less than or equal to the current Address Size setting.

Definition

Operand-ExpressionType:

Absolute-ExpressionType

Constant-ExpressionType

Immediate-ExpressionType

Direct-ExpressionType

Indirect-ExpressionType

Indexed-ExpressionType

Register-ExpressionType

String-ExpressionType

Floating-Point-ExpressionType

Type-ExpressionType

Initializer Expression Type

An Initializer-ExpressionType consists of those #ExpressionTypes that are valid for use in initializing variables. The following ExpressionTypes are not valid Initializer-ExpressionTypes:

Indexed-ExpressionType
Register-ExpressionType

Initializer-ExpressionType:

Scalar-Initializer-ExpressionType

Compound-ExpressionType

Duplicated-ExpressionType

Scalar-Initializer-ExpressionType:

Absolute-ExpressionType

Constant-ExpressionType

Immediate-ExpressionType

Direct-ExpressionType

Indirect-ExpressionType

String-ExpressionType

Floating-Point-ExpressionType

Type-ExpressionType

Description

An Initializer-ExpressionType consists of those #ExpressionTypes that are valid for use in initializing variables. The following ExpressionTypes are not valid Initializer-ExpressionTypes:

Indexed-ExpressionType
Register-ExpressionType

Definition

Initializer-ExpressionType:

Scalar-Initializer-ExpressionType

Compound-ExpressionType

Duplicated-ExpressionType

Scalar-Initializer-ExpressionType:

Absolute-ExpressionType

Constant-ExpressionType

Immediate-ExpressionType

Direct-ExpressionType

Indirect-ExpressionType

String-ExpressionType

Floating-Point-ExpressionType

Type-ExpressionType

Text Preprocessor

The text preprocessor is a functional unit within the assembler that performs the text preprocessing translation phase. During text preprocessing, the following actions are performed:

Language Elements are recognized.
Text equates and macros are expanded.
Macro directives and conditional assembly directives are recognized and processed.
The preprocessed output is passed on to the assembler for final processing.

This section also describes the various types of preprocessor directives:

Type	Function	Directives
Conditional Assembly	Tests for a specified condition and assembles a block of statements if the condition is true.	IF IFB IFDEF IFDIFI IFE IFIDN IFNB IFNDEF IF1 IF2 ELSE ENDIF
Text Equate	Allows assignment of simple text strings to a symbolic name. Provides functions for expanding and operating on the values.	CATSTR EQU INSTR SIZESTR SUBSTR
Macro	Provides text processing that is done sequentially at assembly time. By the end of assembly, ALP expands all macros and assembles the resulting text into object code.	ENDM EXITM FOR FORC IRP IRPC LOCAL MACRO PURGE REPEAT REPT
Miscellaneous	Miscellaneous text processing functions.	COMMENT ECHO %OUT INCLUDE

Text Operators

Description

The #Text Preprocessor recognizes certain punctuator characters as text operators. The programmer may use these operators to force the Text Preprocessor to perform various operations such as delineating text, expanding arguments, and converting expressions into their text representations.

Syntax

Text-Operator:

Literal-Character-Operator

Literal-Text-Operator

Text-Expansion-Operator

Text-Substitution-Operator

Literal Character Operator (!)

Syntax

Literal-Character-Operator:

! any printable character

Description

When you use an exclamation point (!) in an operand, ALP treats the next character literally. (!) is typically used to prevent the assembler from recognizing and acting upon special characters such as the semicolon (;) or the ampersand (&), forcing them to appear as normal data characters.

Constraints

The Literal-Character-Operator has no effect when used inside of a String-Literal.

Examples

In this example, use of the ! in the second macro argument prevents the assembler from interpreting the rest of the line as a comment:

MACRONAME   First, !; NonComment, Third              ; Comment

Literal Text Operator (<>)

Syntax

Literal-Text-Operator:

< Char-Sequence >

Char-Sequence

any printable character

Char-Sequence any printable character

Description

The literal-text operator directs the assembler to treat Char-Sequence as a single literal element regardless of whether it contains commas, spaces, or other separators. The operator is most often used with macro calls and the FOR directive to ensure that values in a parameter list are treated as a single parameter.

The literal-text operator can also be used to force ALP to treat other special characters such as the semicolon (;) or the ampersand (&) literally. For example, the semicolon inside angle brackets (<>) becomes a semicolon, not a comment indicator.

ALP removes one set of angle brackets each time the parameter is used in a macro. When using nested macros, you will need to supply as many sets of angle brackets as there are levels of nesting. The assembler recognizes nested occurrences of text literals.

Examples

The following example illustrates how to pass arbitrary text to a macro as a single parameter:

MACRONAME   First, <Second Argument>, <Third, <Nested>, Argument>

The macro will receive three separate arguments:

First
Second Argument
Third, <Nested>, Argument

Notice that the outermost set of angle brackets were removed from the second and third arguments.

Text Expansion Operator (%)

Syntax

Text-Expansion-Operator:

% 2nd through Nth token on line

% Text-EquateName

% Expression

Description

The % Text-Expansion-Operator has different effects depending upon the context in which it is used. Its primary purpose is convert various sources of information into text literals that may in turn be passed to macros as arguments.

The % Text-Expansion-Operator causes the following types of conversions:

Line Expansion

When used as the first token on the line, the % operator forces expansion of Text-EquateNames in contexts where they would otherwise be left unexpanded. Text-EquateNames passed as arguments to macros are not automatically expanded; this is one context where the % operator is useful.

Expansion of a Text Equate Operand

As with Line Expansion, the % operator may be used within the body of a line to expand individual Text-EquateNames. This can be useful when expansion of all Text-EquateNames on the line is not desired.

Conversion of Numeric Expression to Text

If the Text-Expansion-Operatoris not the first token on the line or immediately followed by a Text-EquateName, then the argument of the % operator is assumed to be an Expression, which is evaluated and converted to the text representation of its value. This is useful when the need arises to pass the text representation of a number to a macro.

Constraints

When the % Expression form of the expansion operator is used, the Expression must evaluate to an Immediate-ExpressionType.

Examples

MakErr       MACRO       X 
LB           =           0 
             REPEAT      X 
LB           =           LB + 1 
             MakLib      % LB 
             ENDM        ; ; End of REPEAT
             ENDM        ; ; End of MACRO
MakLib       MACRO       Y 
Err & Y :    DB     ' Error    & Y ' ,0 
             ENDM 

             MakErr   3 
Err1 :    DB    ' Error   1 ' ,0
Err2 :    DB    ' Error   2 ' ,0
Err3 :    DB    ' Error   3 ' ,0

Text Substitution Operator (&)

Syntax

Text-Substitution-Operator:

Macro-ParameterName &

& Macro-ParameterName

Description

An ampersand (&) is used in the body of a macro to force the substitution of a Macro-ParameterName with the value of its argument during expansion of the macro.

Constraints

The assembler does not substitute a Macro-ParameterName that is in a quoted string or not preceded by a delimiter in the expansion unless it is immediately preceded by an ampersand (&).

It is necessary to separate a Macro-ParameterName from other Identifer-Characters with an ampersand (&) before any substitution or paste operations are performed.

Examples

ErrGen    MACRO     X 
Error &X: push      bx 
ABX       mov       BX, "A"; 
AB &X     mp        ERROR 
          ENDM

The statement ErrGen A produces this code:

ErrorA :   push     bx 
ABX        mov      BX , "A"; 
ABA        jmp      ERROR

Preprocessor Tokens

Syntax

Preprocessing-Token:

Identifier

Text-Literal

FileName

Comment

Description

During the text preprocessing translation phase, certain conditions will cause the preprocessor to convert raw #Language Elements (#Tokens) into Preprocessing-Tokens. The act of text preprocessing typically causes Preprocessing-Tokens to either be removed from the input stream or converted back into Tokens before being passed on to the assembler for final processing.

Text Literals

Syntax

Text-Literal:

operand of Literal-Character-Operator

operand of Literal-Text-Operator

Description

A Text-Literal is a single unit of text that is used by the #Text Preprocessor in many different text handling contexts. In some contexts ( such as the processing of arguments to be passed to a macro), normal language #Tokens are implicitly treated as Text-Literals, provided they are not a delimiter character such as a comma or a blank. In other contexts, it may be necessary to explicitly convert a unit of text to a Text-Literal using the Literal-Text-Operator.

Constraints

A normal language Token is never implicitly considered to be a Text-Literal if a Text-Literal is explicitly required in the syntax of the construct being parsed.

File Names

Syntax

FileName:

FileName-Text

Text-Literal

FileName-Text:

FileName-Character

FileName-Text FileName-Character

FileName-Character:

any printable character except blank (ASCII 32)

Description

FileName arguments may be coded as an arbitrary sequence of printable characters, or as a Text-Literal; use the Text-Literal form if the FileName is to contain embedded spaces or other special characters.

If path information is included in the FileName, you can separate the individual directory names with either the back slash (\) or the forward slash (/) and they will be treated identically by the assembler.

Examples

  INCLUDE      <inc\macros.inc> 
  INCLUDELIB   os2386.lib

Comments

Comments are language elements that have significance only to the programmer and not to the assembler. Comments are effectively removed from the input stream during the text preprocessing phase.

There are two classes of comments recognized by ALP:

Comments that start with a character sequence and continue to the end of the line (EndOfLine-Comment)

Comments that start with a character sequence and continue until the occurrence of another character sequence (Block-Comment). See the #COMMENT directive for a description of #Block-Comments.

There are two types of EndOfLine-Comments:

Macro-Comment

Macro-Comments (beginning with two semicolons) do not appear in the listing output even when the .LALL directive is used. Use of Macro-Comments can significantly reduce the amount of memory workspace used by the definition of a macro. As a macro definition is read, Macro-Comments are discarded and not entered into the macro definition, whereas NonMacro-Comments are treated as normal text and are retained.

NonMacro-Comment

NonMacro-Comment (beginning with a single semicolon) are preserved in macro definitions and appear in the listing output during macro expansions.

Syntax

Comment:

EndOfLine-Comment

Block-Comment

EndOfLine-Comment:

NonMacro-Comment

Macro-Comment

NonMacro-Comment:

; Char-Sequence

Macro-Comment:

;; Char-Sequence

Char-Sequence:

any printable character

Char-Sequence any printable character

#Block-Comment:

See the #COMMENT directive

Description

Comments are language elements that have significance only to the programmer and not to the assembler. Comments are effectively removed from the input stream during the text preprocessing phase.

There are two classes of comments recognized by ALP:

Comments that start with a character sequence and continue to the end of the line (EndOfLine-Comment)
Comments that start with a character sequence and continue until the occurrence of another character sequence (Block-Comment). See the #COMMENT directive for a description of #Block-Comments.

There are two types of EndOfLine-Comments:

Macro-Comment

Macro-Comments (beginning with two semicolons) do not appear in the listing output even when the .LALL directive is used. Use of Macro-Comments can significantly reduce the amount of memory workspace used by the definition of a macro. As a macro definition is read, Macro-Comments are discarded and not entered into the macro definition, whereas NonMacro-Comments are treated as normal text and are retained.

NonMacro-Comment

NonMacro-Comment (beginning with a single semicolon) are preserved in macro definitions and appear in the listing output during macro expansions.

Example

The following are examples of EndOfLine-Comments:

; Comments may be on a line all by themselves. They can be empty ... 
; 
                        ; They don't have to start in the first column
BumpCount MACRO Amount  ; They can appear to the right of statements
  Count = Count + Amount       ; This appears in macro expansions
  $Total = $Total + Amount     ;; This does not, discarded during definition
ENDM

Text Arguments

Many preprocessing directives operate on sequences of raw text characters called Text-Arguments. A Text-Argumentmay be specified using any one of several methods:

Specifying the text directly using a raw Text-Literal.
Using the Text-Expansion-Operator to convert a numeric expression to its text representation.
Using a Text-EquateName in those contexts where a Text-Argumentis expected. In this case the preprocessor will automatically resolve the Text-EquateName and use its value as the Text-Argument.

Text-Argument:

Text-Literal

% Expression

Text-EquateName

Description

Many preprocessing directives operate on sequences of raw text characters called Text-Arguments. A Text-Argumentmay be specified using any one of several methods:

Specifying the text directly using a raw Text-Literal.
Using the Text-Expansion-Operator to convert a numeric expression to its text representation.
Using a Text-EquateName in those contexts where a Text-Argument is expected. In this case the preprocessor will automatically resolve the Text-EquateName and use its value as the Text-Argument.

Syntax

Text-Argument:

Text-Literal

% Expression

Text-EquateName

Conditional Assembly Directives

At assembly time, ALP evaluates conditional assembly directives, assembling if the conditions are true. You can use conditional assembly directives when you want to test for a specified condition and assemble a block of statements if the condition is true. The #IFxx and #ENDIF directives enclose the statements to be considered for conditional assembly. The optional #ELSEIFxx and #ELSE blocks follow the #IFxx directive. There are many forms of the #IFxx and #ELSEIFxx directives.

This section describes the following conditional assembly directives:

IFxx (Begin Primary Conditional Block)

You can use each IFxxconditional directive with the #ELSExx, #ELSE and #ENDIF directives to provide the statements to be considered for conditional assembly. ALP assembles the statements following the #IFxx directive only if this condition is true.

Syntax

IFxx   operand
   .
   .
   .
[ ELSEIFxx ]   ( optional )
   .
   .
   .
[ ELSE ]   ( optional )
   .
   .
   .
ENDIF

Remarks

The following directives are members of the IFxx family:

IF
IFB
IFDEF
IFDIF
IFDIFI
IFE
IFIDN
IFIDNI
IFNB
IFNDEF
IF1
IF2

You can nest the conditional directives to any level. They are not limited to use within a macro. The assembler must know any operand to a conditional on pass one to avoid errors and incorrect evaluation.

IF (If Expression is True)

IF starts a conditional assembly statement, which is ended by the corresponding #ENDIF conditional assembly directive. Each IF directive must be ended by a matching ENDIF directive.

Syntax

IF Expression 
    .
    .
    .
[ ELSEIFxx ]   (optional)
    . 
    . 
    .
[ ELSE ]   (optional)
    .
    .
    .
ENDIF

Remarks

If the #IFxx conditional assembly statement is not ended by an #ENDIF directive, an unterminated conditional message is produced by the assembler. An ENDIF without a matching IF causes an error. ENDIF does not have an operand.

Note: The conditional directives can be nested to any level. They are not limited to use within a macro. Any operand to a conditional must be known on pass 1 to avoid errors and incorrect evaluation.

Example

IF   debug
     EXTERN   dump:FAR
     EXTERN   trace:FAR
     EXTERN   breakpoint:FAR
ENDIF

IFB (If Argument is Blank)

This is true if #Text-Argument is blank (contains no characters).

Syntax

IFB Text-Argument

Remarks

A #Text-Argument must be specified, the contents of which are checked for the presence of characters. An error is generated if a Text-Argument is not supplied.

IFDEF (If Identifier is Defined)

This is true if #Identifier has been defined as a label, variable, or symbol.

Syntax

IFDEF Identifier

IFDIF (If Arguments Are Different)

This is true if #Text-Argument-1 and Text-Argument-2 are different in a case-sensitive comparison.

Syntax

IFDIF Text-Argument-1, Text-Argument-2

Remarks

Both Text-Argument arguments must be specified. An error is generated if a either argument is not supplied.

Example

In the following example:

IFDIF <EAGLES>,<Eagles>;
  value = 1
ENDIF

the condition would be true; the arguments are different because they are compared with a case-sensitive algorithm.

IFDIFI (If Arguments Are Spelled Differently)

This is true if #Text-Argument-1 and Text-Argument-2 are different in a case-insensitive comparison.

Syntax

IFDIFI Text-Argument-1, Text-Argument-2

Remarks

Both Text-Argument arguments must be specified. An error is generated if a either argument is not supplied.

Example

In the following example:

IFDIFI <EAGLES>, <Eagles>
  value = 1
ENDIF

the condition would be false; the arguments are not different because they are compared using a case-insensitive algorithm.

IFE (If Expression is Not True)

This is true if expression is 0.

Syntax

IFE   Expression

IFIDN (If Arguments Are Identical)

This is true if #Text-Argument-1 and Text-Argument-2 are identical in a case -sensitive comparison.

Syntax

IFIDN   Text-Argument - 1, Text-Argument - 2

Remarks

Both Text-Argument arguments must be specified. An error is generated if a either argument is not supplied.

Example

In the following example:

IFIDN   <EAGLES>, <Eagles>; 
  value   =   1 
ENDIF

the condition would be false; the arguments are not identical because they are compared using a case-insensitive algorithm.

IFIDNI (If Arguments Are Spelled Identically)

This is true if #Text-Argument-1 and Text-Argument-2 are identical in a case -insensitive comparison.

Syntax

IFIDNI   Text-Argument - 1, Text-Argument - 2

Remarks

Both Text-Argument arguments must be specified. An error is generated if a either argument is not supplied.

Example

In the following example:

IFIDNI <EAGLES>, <Eagles>
  value = 1
ENDIF

the condition would be true; the arguments are identical because they are compared using a case-insensitive algorithm.

IFNB (If Argument is Not Blank)

This is true if Text-Argument is not blank (characters are present).

Syntax

IFNB Text-Argument

Remarks

A Text-Argument must be specified, the contents of which are checked for the presence of characters. An error is generated if a Text-Argument is not supplied.

IFNDEF (If Identifier is Not Defined)

This is true if symbol has not yet been defined as a label, variable, or symbol.

Syntax

IFNDEF symbol

IF1 (If Assembling On Pass 1)

This is true on pass one.

Syntax

IF1

Remarks

IF1 does not have an operand.

IF2 (If Assembling On Pass 2)

This is true on pass two.

Syntax

IF2

Remarks

IF2does not have an operand.

ELSEIFxx/ELSE (Begin Alternate Conditional Block)

Each conditional directive can be used with the ELSE directive to provide the statements to be considered for conditional assembly. The ELSE directive allows the assembly of the statements following it when the #IFxx condition or intervening ELSEIFxx conditions are false.

Syntax

IFxx 
    . 
    . 
    . 
[ ELSEIFxx ]   ( optional ) 
    . 
    . 
    . 
[ ELSE ]   ( optional ) 
    . 
    . 
    . 
ENDIF

Remarks

There is a corresponding ELSEIFxx directive to match all forms of the #IFxx family of directives:

#ELSEIF
#ELSEIFB
#ELSEIFDEF
#ELSEIFDIF
#ELSEIFDIFI
#ELSEIFE
#ELSEIFIDN
#ELSEIFIDNI
#ELSEIFNB
#ELSEIFNDEF
#ELSEIF1
#ELSEIF2

For information about the meaning of the conditional tests performed by the ELSEIFxx directives, refer to the definitions for the corresponding #IFxx directives.

Any number of ELSEIFxx blocks may be used within a given IFxx statement. Only one ELSE block is permitted for a given IFxx. A conditional directive with more than one ELSE or an ELSE without a conditional directive causes an error. ELSE does not have an operand.

Note: The conditional directives can be nested to any level. They are not limited to use within a macro. Any operand to a conditional must be known on pass 1 to avoid errors and incorrect evaluation.

Example

IF DEFBUF
  BUF DB 100 DUP(0)
ELSE 
  EXTERN BUF:BYTE
ENDIF

ENDIF (End a Conditional Assembly Statement)

ENDIF ends the conditional assembly statement begun by the corresponding #IFxx conditional assembly directive. Each IFxx directive must be ended by a matching ENDIF directive.

Syntax

IFxx 
    . 
    . 
    . 
[ ELSEIFxx ]   ( optional ) 
    . 
    . 
    . 
[ ELSE ]   ( optional ) 
    . 
    . 
    . 
ENDIF

Remarks

If the #IFxx conditional assembly statement is not ended by an ENDIF directive, an unterminated conditional message is produced by the assembler. An ENDIF without a matching IFxx causes an error. ENDIF does not have an operand.

Note: The conditional directives can be nested to any level. They are not limited to use within a macro. Any operand to a conditional must be known on pass 1 to avoid errors and incorrect evaluation.

Example

IF  debug
   EXTERN   dump:FAR
   EXTERN   trace:FAR
   EXTERN   breakpoint:FAR
ENDIF

Text Equate Directives

A Text Equate is a symbolic name you give to a series of characters. Text equates are used to expand text within a source statement. The directives described in this section create and manipulate text equates.

EQU
CATSTR
INSTR
SIZESTR
SUBSTR

CATSTR (Concatenate Strings)

CATSTR concatenates a list of text values specified by string into a single text value and assigns it to Name.

Syntax

Name CATSTR string[, string] ...

EQU Directive (Assign Text to a Symbolic Constant)

The EQU directive assigns the contents of a text literal to Name.

Syntax

Name EQU   Text - Literal

Remarks

The value of the Text-Literal is assigned to the Name entry. In normal contexts, subsequent references to Name will cause the preprocessor to replace Name with the value specified by the Text-Literal entry. This is a simple text substitution operation.

The Name entry is a globally-scoped Identifier that is converted to a Text-EquateName. The Name cannot have been previously defined as a different Identifier-Type. However, the Name entry can be redefined as many times as desired with different values for the Text-Literal entry.

INSTR (Search In String For Value)

INSTRsearches a specified String for an occurrence of a given Sub-String and assigns its position (1-based) to Name. The search is case sensitive. Startis the position in String to start the search for Sub-String. If Startis not given, it is assumed to be 1 (the start of the string). If Sub-String is not found, the position assigned to Name is 0.

Syntax

Name   INSTR   [ Start , ] String , Sub-String

Remarks

INSTRassigns the position value to a name as if it were a numeric equate.

Example

pos   INSTR   < person > , < son >

SIZESTR (Return Size Of String)

Assigns the number of characters given by the Text-Argument to Name.

Syntax

Name  SIZESTR  Text-Argument

SUBSTR (Extract a Sub-string From a String)

Assigns a substring of Text-Argument starting at Position to the symbol given by Name..

Syntax

Name SUBSTR Text-Argument,Position[,Length]

Remarks

The Position parameter indicates the starting character of the substring to extract from the Text-Argument, and must be 1 or greater. If specified, the Length parameter indicates how many characters are desired, otherwise the remainder of the string is extracted.

Macro Directives

A macro procedure or function, which is comprised of one or more statements.

Macro processing is text processing that is done sequentially at assembly time. By the end of assembly, ALP expands all macros and assembles the resulting text into object code.

This section describes the following types of macros:

Macro procedures, which expand to one or more complete statements and can optionally take parameters
Repeat blocks, which generate a group of statements a specified number of times or until a condition becomes true

This section describes the following macro directives:

ENDM

EXITM

FOR/IRP

FORC/IRPC

LOCAL

MACRO

PURGE

REPEAT/REPT

ENDM (End Current Macro Definition)

End each #MACRO, #REPEAT/REPT, #FOR/IRP, and #FORC/IRPC directive with the ENDMdirective.

Syntax

ENDM

Remarks

If the ENDM directive is not used with the #MACRO, #REPEAT/REPT, #FOR/IRP, and #FORC/IRPC directives, an error occurs. An unmatched ENDM also causes an error.

If the assembler produces an error message stating that it found the end-of -file on the source and cannot find an #END statement when there was an END, the likely cause is a missing ENDM or ENDIF statement. Without ENDM, the assembler treats the rest of the source as part of the #MACRO definition.

Note: The name field is not allowed. Do not confuse the ENDM directive with other ending directives that do require the name of the block being ended, such as ENDP or ENDS.

Example

addup   MACRO     ad1, ad2, ad3
        MOV       AX, ad1         ;; first parameter in AX
        ADD       AX, ad2         ;; add next two parameters 
        ADD       AX, ad3         ;; leave sum in AX
        ENDM

EXITM (End Current Macro Expansion)

Use the EXITM directive when a block contains a directive that tests for some condition and you want to end the current macro expansion when the test proves that the remainder of the expansion is not required. When an EXITM directive is run, the expansion is stopped immediately, and any remaining expansion or repetition is not produced.

Syntax

EXITM

Remarks

Only the block containing the EXITM directive is ended; outer levels of a nested macro expansion continue unaffected.

EXITM is executed at macro expansion time and is not a substitute for the #ENDM directive, which marks the end of the macro body and is recognized at macro definition time.

Example

DSEG   SEGMENT 
      . 
      . 
      . 
SYM   =   0 
    REPEAT 16
; ; Check for paragraph boundary
      IF   ( $ - DSEG ) MOD 16 EQ 0
      EXITM   ; ; quit if padded to boundary
      ENDIF 
SYM = SYM + 1 
      DB   SYM   ; ; produce numbered padding
      ENDM

FOR/IRP (Iterative Macro Expansion Using List of Arguments)

The FOR directive, used in combination with the #ENDM directive, designates a block of statements to be repeated, once for each argument in the list enclosed by angle brackets. Each repetition substitutes the next item in the <Argument-List> entry for every occurrence of Parameter in the block.

Syntax

FOR  Parameter , < Argument-List >
    .
    .
    .
ENDM

Remarks

The obsolete spelling for the FOR directive is IRP.

You must enclose the <Argument-List> entry in angle brackets. It has the following format:

< [ Argument   [ ,   Argument   . . . ] ] >

If an empty (<>) Argument is found in <Argument-List>, the Parameter name is replaced by a null value. If the argument list is empty, the FORdirective is ignored and no statements are copied. The assembler processes the block once for each Argumentin the <Argument-List>, replacing each occurrence of Parameterin the macro body with the current Argument value.

The #FOR/IRP-#ENDM block does not have to be within a macro definition.

Example

In this example, the assembler produces the code DB1 through DB10.

FOR     X ,   < 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 , 10 > 
DB      X 
ENDM

In the next example:

FOR      ARGUMENT , < " first   line " , 13 , 10 , 
" second   line " , 13 , 10 > 
DB      ARGUMENT 
ENDM

The assembler produces the code:

DB     " first   line " 
DB     13 
DB     10 
DB     " second   line " 
DB     13 
DB     10

FORC/IRPC (Iterative Macro Expansion Using List of Characters)

The assembler repeats the statements in the block once for each character in the string. Each repetition substitutes the next character in the string for every occurrence of Parameterin the block.

Syntax

FORC   Parameter ,   String   ( or   < String > ) 
    . 
    . 
    . 
ENDM

Remarks

The obsolete spelling for the FORCdirective is IRPC.

The FORCdirective is similar to the #FOR/IRP directive except that a String is used instead of <Argument-List>, and the angle brackets around the string are optional. The string should be enclosed with angle brackets (<>) if it contains spaces, commas, or other separating characters.

The FORC/IRPC-#ENDM block does not have to be within a macro definition.

Example

In this example, the assembler produces the code DB 1 through DB 8:

FORC      X, 12345678
DB        X
ENDM

LOCAL (Identify Names Local to a Macro Definition)

The LOCAL directive is used inside the body of a macro definition, and provides a method of automatically generating unique assembler labels each time the macro is expanded. The names appearing in the argument list of the LOCAL directive are known only to the enclosing macro, and each time they are referenced during a macro expansion a unique symbol is created. This prevents the assembler from issuing duplicate definition errors when the macro is expanded more than once and symbols contained therein are being used to create assembler labels.

Syntax

LOCAL Name [, Name .... ]

Remarks

The LOCAL directive is recognized only within the body of a macro given by a #MACRO, #FOR/IRP, #FORC/IRPC, or #REPEAT/REPT definition. The symbols created by the preprocessor are of the form ??nnnn, where nnnn is a hexadecimal number in the range 0000 through FFFF. You must avoid using identifiers of this form for your own purposes, because doing so can cause duplicate definition errors.

To insure that they have the proper effect, LOCAL statements should appear in the body of the macro before any other directives are used. It is acceptable for blank lines or comments to precede any LOCAL statements.

You can use multiple LOCAL statements if the argument list is too long to fit on one line, or if you want a vertical list of LOCAL symbols.

Example

DISPLAY MACRO TT

; Blank lines and comments are ok here
      LOCAL AGAIN 

;; DOS macro to display message addressed by BX TT times
      MOV     CX, TT
      MOV     AH, 9
      MOV     DX, BX
; Generate a unique label for AGAIN
AGAIN:
      INT     21H 
      LOOP    AGAIN 
      ENDM

MACRO (Assign a Body of Text to a Name)

This directive produces a given sequence of statements from various places in your program, even though different parameters may be required each time you call the sequence.

Macro processing consists of two separate and distinct phases: #Macro Definition and #Macro Expansion.

Macro Definition

A macro definition consists of three essential parts:

The MACRO directive, defining the Name and the Parameter-List
The body of the macro, containing the prototypes of statements to produce when you invoke the macro for expansion.
The #ENDM directive, ending the definition of the macro.

Syntax

Name MACRO [Parameter [, Parameter ...]]
  .
  .
  .
ENDM

Remarks

The Name field must be a valid preprocessor identifier and specifies the symbolic name that the user will refer to when invoking the macro for expansion. If Name is already defined, it must be that of a previous macro definition, otherwise an error message is issued. Macros may be redefined to have a different Parameter-Lists or macro body text; doing so causes the previous definition to be lost.

The optional Parameter-List is the complete comma-separated list of all Parameter valuess given in the macro definition statement. A parameter must be a valid symbol name according to the rules for naming preprocessor and assembler identifiers. Each parameter becomes a symbol that is local to the macro being defined and is recognized during macro expansion prior to searching the global name space. Thus, macro parameters need not have names unique from identifiers defined elsewhere in the program.

Macro Expansion

To expand the macro, the macro Name (defined in the Name field of the MACRO definition statement) is coded as you would any other assembler directive, followed by the list of arguments (if any) that you want to pass to the macro.

Syntax

Name [Argument [, Argument ...]]

Remarks

The Name field must be the name of a macro defined previously with a MACRO directive.

Each Argument field denotes a text value that you want to pass to the macro. The relative positions of the elements are important, because each Argument is associated in left-to-right fashion with the corresponding Parameter as defined in the Parameter-List during the macro definition.

The number of Argument entries given when the macro is invoked need not be the same as the number of Parameter entries. If you pass extra Arguments to the macro, they are ignored; if too few are supplied, empty text values are associated with the remaining Parameters. You may also associate an empty text value with a Parameter by passing an explicitly empty text literal <> as an Argument.

Commas are normally used to separate arguments, although blanks or tabs are also considered to be argument separators. For this reason, any argument that must contain an argument separator character (commas, blanks, or tabs) should be enclosed in angle brackets <>. For example:

PUSHVEC   MACRO   PARM1, PARM2
          MOV     AX, PARM1
          PUSH    AX
          MOV     AX, PARM2
          PUSH    AX
          ENDM
          .
          .
          .
          PUSHVEC   DS, <OFFSET VARNAME>
 ; PUSH DWORD VECTOR OF VARNAME ONTO STACK

You can also use angle brackets to produce variable lengths of results. For example:

STRING   MACRO     NUMBERS
         DB        NUMBERS
         ENDM
           . 
           . 
           . 
         STRING   <1,2,3,4>
         ; PRODUCE 4 BYTES OF INTEGER NUMBERS

Remarks

Each time a macro is invoked (expanded) by specifying its name, the preprocessor emits the statements contained in the body of the macro and passes them to the assembler for processing. During the expansion process, any replacement parameters encountered in the macro body (as named in the Parameter-List of the macro definition) are replaced with the corresponding Argument (if any) passed through the argument-list at the time the macro was invoked.

Example

GEN   MACRO   XX, YY, ZZ
      MOV     AX, XX
      ADD     AX, YY
      MOV     ZZ, AX
      ENDM

When the call is made, for example:

GEN   ED, KISER, SUM

The assembler produces the following code:

MOV     AX, ED
ADD     AX, KISER 
MOV     SUM, AX

PURGE (Remove Macro Definition)

The PURGE directive deletes the definition of a specified macro entry, letting you reuse space.

Syntax

PURGE Macro-Name [, ...]

Remarks

It is not necessary to purge a macro before redefining it. You may use PURGE to recover memory during assembly by deleting the contents of unreferenced macros. An Out of Memory condition can occur if a large, general-purpose macro library is included.

Example

The directive:

PURGE     MACRONAME

performs the same function as redefining the macro with no contents, as in:

MACRONAME MACRO
          ENDM

In the following example, assume that MAC1 is a macro included in MACRO.LIB:

INCLUDE   MACRO.LIB
PURGE     MAC1
MAC1      ; Calls the purged macro
          ; but produces nothing

REPEAT/REPT (Iterative Macro Expansion Using a Count Expression)

REPEAT specifies the number of times to generate the statements inside the macro.

Syntax

REPEAT Expression
 Statements
ENDM

Remarks

The Expression field must evaluate to an Absolute-ExpressionType (it cannot contain forward references). Because the repeat block will be expanded at assembler time, the number of iterations must be known then.

ECHO Directive (Display Message on Standard Output Device)

The ECHO directive displays progress through a long assembly or displays the value of conditional assembly parameters.

Syntax

ECHO Text

Remarks

The assembler lists the Text entry on the standard output device during assembly when the assembler encounters the ECHO directive.

ECHO is not available under MASM 5.10 emulation; you must use %OUT, which is the obsolete spelling for the ECHO directive.

Example

Example 1:

IF IBM
  ECHO IBM VERSION
ENDIF

IF2
  ECHO STARTING SECOND PASS
   . 
   . 
   . 
  ENDIF

Example 2:

INNER   MACRO    TEXT, VAL
        ECHO     TEXT  VAL 
        ENDM
        . 
        . 
        . 
HERE    =  $ - CSEG 
        INNER <CURRENT LOCATION>,%HERE

INCLUDE Directive (Insert File Contents into Input Stream)

The INCLUDE directive "stacks" the current source file and begins reading tokens from the source file given by the FileName argument. If you use the INCLUDE directive, you need not repeat a sequence of statements that are common to several source files.

Syntax

INCLUDE FileName

Remarks

The assembler uses the following search order when attempting to open the INCLUDE file:

If the FileName argument contains a fully qualified path name (one that begins with a back slash or forward slash), then the assembler attempts to open the file exactly as specified, and no other search is performed if the file is not found.
If the FileName begins with a relative path name or contains no path information, the assembler begins searching for the INCLUDE file by looking in the directory of the source file that issued the INCLUDE directive.
The assembler searches for FileName in the list of directories given by any #-Fdi or #-I options found on the command line.
The assembler searches for FileName in the list of directories given by the <BaseEXE>_INCLUDE environment variable.
The assembler searches for FileName in the list of directories given by the INCLUDE environment variable.
Lastly, the assembler searches for FileName in the current directory. If the named file is not found, the assembler issues a fatal error message and the assembler is ended.

In no case does the assembler strip relative path information from the FileName when performing search steps 2 through 6.

When the file named in the INCLUDE directive is located, the assembler opens it and assembles all of the statements contained therein until the end of the file is reached. The file is then closed and assembler resumes in the original module at the line following the INCLUDE directive.

An INCLUDE file should not contain an #END assembler directive to denote the end of the included module; the assembler closes the included module when its physical end of file is reached.

INCLUDE files may be nested to any reasonable level, and is limited only by the operating system's ability to provide the necessary resources.

Example

INCLUDE OS2.INC

COMMENT Directive (Program Information Block)

COMMENT lets you enter comments about your program without having to enter semicolons (;) for each line.

Syntax

COMMENT   Delimiter   Text   Delimiter

Remarks

The first non-blank character after COMMENT is the first delimiter. The COMMENT directive causes the assembler to treat all Text between Delimiter and Delimiter as a comment. The text must not contain the delimiter character. This directive is used for multiple-line comments. A COMMENT defined in the body of a macro does not appear unless .LALL is requested.

Example

COMMENT *You can enter as many lines
of text between the delimiters
   . 
   . 
   . 
as you need to describe your program.*

Assembler Messages

This section describes all the messages produced by ALP at run time. Messages issued by the assembler have the following format:

[Coordinates] [Severity Type] [Message Number] [Message Content]

The following sections describe the various fields common to all assembler messages, and a complete description of each individual message is included.

Message Coordinates

Message coordinates (if present) appear as the first field within a message, and have one of two forms:

[Path]Filename(LLLL:CCCC):

[Path]Filename(LLLL,Macroname(LLLL,CCCC)):

Coordinates are displayed as part of a message if ALP is parsing an input stream and the event which caused the message to be diplayed is directly related to a specific location in the input. The coordinates show the user exactly where to look if action is required. The fact the ALP is parsing an input stream does not mean that coordinates will appear in a message; some messages may occur during parsing that are not a reference to the input stream.

Filename

This is the name of the file containing the input token which caused the message to be generated. If this is the root source file whose name was passed on the assembler command line, the file name will be displayed exactly as specified by the user. If this is an INCLUDE file, it will be displayed exactly as specified in the INCLUDE directive, and the path name where the file was searched for and found (if any) will be prepended to the beginning. ALP does not query the operating system in an attempt to derive the full path name of a partially qualified file.

Macroname

If the assembler is currently parsing tokens within a macro expansion, the name of the macro currently being expanded will appear in the coordinates.

Line Number (LLLL)

The first number in parentheses is the line number within the source file where the referenced token is located; this refers to the outer-most point of invocation if a macro name is also given in the message coordinates. A line number value appearing within parentheses following a macro name refers to the innermost point of expansion (since macro expansions may be nested) and references the original definition of the macro.

Column Number (CCCC)

The second number in parentheses is the column number of the first character of the referenced token within the source file or macro definition.

Message Severity Types

Every message displayed by ALP is assigned a specific type, and the type of message dictates the severity level. The following is a list of message types produced by ALP showing the type name (as it appears in the actual message), followed by a description of what caused the message, how severe it is, and the action taken by ALP after the message is generated.

Info: Informational message only; processing continues normally.

Warning: Questionable syntax or semantics; input file may be incorrect, but processing continues.

Error: Syntax or semantic error in input; continue processing, object output file is discarded.

Fatal: Unrecoverable user or environment error; terminate assembly prematurely after releasing resources and closing files.

Internal: Internal program logic error, abort immediately.

Usage: Incorrect command line syntax, abort.

When the assembler begins processing, the display of all warning messages is enabled; informational messages do not display unless they are requested . The display of both warning and informational messages may be controlled with the command line option M - Control Individual Messages or Groups See Message Control Options for more information on the behavior of assembler messages.

Message Numbers and Message Content

Messages numbers displayed by ALP have the following format:

ALPnnnn:

Message numbers always have a three-letter prefix that designates the component issuing the message (ALP), followed by a four digit decimal number given by nnnn. All messages issued by the assembler are uniquely numbered; however, not all messages displayed by the assembler will be accompanied by a formatted message number (for instance, the assembler banner).

Messages issued during assembler initialization, command line processing, or exception handling are numbered from 0 to 999. Other messages occur during input stream processing and are grouped according to their severity type: 1000 through 1999 for fatal errors, 3000 through 3999 for regular errors, 4000 through 4999 for warnings, and 5000 through 5999 for informational messages.

It should be noted that messages are numbered for reference only; it is not guaranteed that messages will be numbered identically for each subsequent assembler release, or that individual messages will be retained or remain unmodified in future releases.

Message Numbers 0-999: Internal, Usage, and Special Case Messages

Messages in this section normally occur during assembler initialization, when errors are encountered during command line processing, or when exceptional conditions occur that prevent the assembler from completing initialization or execution.

ALP0004: <signal> received, <assembler-name> is shutting down: ALP has handled a request from the operating system to abort execution. The type of abort request is noted in the text of the message. All open files will be closed and any incomplete output files will be deleted.; Recovery: If termination was requested by the user, no further action is necessary. Otherwise, the operating system may have sent an abort signal because of insufficient system resources.
ALP0005: Assertion failure, <reason>: This message is displayed when an internal self-check condition has been violated, and indicates an error in the internal programming logic of the assembler. This message should never occur.; Recovery: Note the conditions under which the error occurred, and if possible isolate a minimal test case that will reproduce the problem. Contact IBM.
ALP0942: -Lo:xxxxxxxxxxxx must be one each of "XYZLMICFOGDS": This option specifies the sort order for the individual vertical listing file columns. Not all single character tags that uniquely identify each individual column were specified.; Recovery: All column tags must be specified in the argument field of this option, even when the display of one or more columns has been disabled.
ALP0981: Invalid or missing include path: The list of INCLUDE file directories was incorrectly specified.
ALP0991: Invalid option "<option>": The command line parser encountered a character sequence on the command line that was interpreted as an option, but the option identifier itself was not recognized.
ALP0992: Option "<option>" not valid in global scope: An attempt was made to use an option in a situation that would cause ambiguities. As coded by the user, the option is only legal when applied to an individual filename.; Recovery: If the option syntax is correct, insure that it follows the filename to which it applies.
ALP0993: Option "<option>" not valid in local scope: An attempt was made to apply a global assembler option to an individual file.; Recovery: Global options must appear before any filenames; in most cases the usage of global options and filenames is a mutually exclusive operation.
ALP0994: Invalid argument in option "<option>": In the argument field of a parameterized command line option, an argument of a specific type was expected, but an invalid token was encountered instead.
ALP0995: Expecting ":" or "=" in option "<option>": A parameterized option was encountered, but no colon (:) or equal sign (=) followed the option identifier.; Recovery: Parameterized options must be immediately followed by a colon or equal sign with no intervening white space characters, followed by the option argument(s).
ALP0996: Invalid message number: An explicit message number specified with the -M option did not identify a message for which switching is enabled.; Recovery: Only warning and informational messages may switched on or off.
ALP0997: Invalid keyword "<keyword>" in option "<option>": The referenced identifier was not a valid keyword; a keyword was expected in the context of the referenced option.

Message Numbers 1000-1999: Fatal Error Messages

Fatal errors typically occur when the assembler requests a resource from the operating system, but the request fails. This may or may not be due to user error, but the assembler was unable to correct the problem and execution is terminated after an orderly shutdown is performed.

ALP1101: Memory allocation error

The assembler attempted to dynamically allocate a block of storage, but the request was denied.

Recovery:

Close any large or memory intensive processes
Verify that sufficient paging space exists
The host computer may have insufficient hardware resources

ALP1102: Too many error messages

This message is displayed when the assembler has reached the error limit threshold. Related Information:

Me - Set Number of Errors Before Assembler Aborts

ALP1103: Error opening message output file "<file>"; <reason>

An error occurred while attempting to open the referenced file. Recovery: Verify that the file exists and that read permission is allowed. Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP1104: Input and message output filenames are identical

The assembler has detected an attempt to create an output file with a name identical to that of an input file; the operation was not allowed.

The assembler only detects this condition when the names are an identical match , using a case-sensitive comparison algorithm.

Recovery: Ensure that the correct command line options have been used. Internal variables may have been incorrectly initialized using options that affect automatic file name generation, thus causing a filename collision.

Related Information:

Internal Variables
File Control Options

ALP1401: Error opening listing output file "<file>"; <reason>

An error occurred while attempting to open the referenced file. Recovery: Verify that the file exists and that read permission is allowed. Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP1402: Error writing listing output file "<file>"; <reason>

An error occurred while attempting to write to the referenced file. Recovery: Ensure that there is sufficient space on the target file system, and no other processes are accessing or modifying the file. Verify that the file system is functioning correctly.

ALP1403: Input and listing output filenames are identical

The assembler has detected an attempt to create an output file with a name identical to that of an input file; the operation was not allowed. The assembler only detects this condition when the names are an identical match , using a case-sensitive comparison algorithm. Recovery: Ensure that the correct command line options have been used. Internal variables may have been incorrectly initialized using options that affect automatic file name generation, thus causing a filename collision. Related Information:

Internal Variables
File Control Options

ALP1601: Error creating object output file "<file>"; <reason>

An error occurred while attempting to create the referenced file. Recovery: Verify that the target drive and directory exist and that create and write permission have been granted. Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP1602: Error writing object output file "<file>"; <reason>

An error occurred while attempting to write to the referenced file. Recovery: Ensure that there is sufficient space on the target file system, and no other processes are accessing or modifying the file. Verify that the file system is functioning correctly.

ALP1603: Input and object output filenames are identical

The assembler has detected an attempt to create an output file with a name identical to that of an input file; the operation was not allowed. The assembler only detects this condition when the names are an identical match , using a case-sensitive comparison algorithm. Recovery: Ensure that the correct command line options have been used. Internal variables may have been incorrectly initialized using options that affect automatic file name generation, thus causing a filename collision. Related Information:

Internal Variables
File Control Options

ALP1801: Error opening source file "<file>"; <reason>

An error occurred while attempting to open the referenced file. Recovery: Verify that the file exists and that read permission is allowed. Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP1802: Error reading source file "<file>"; <reason>

An error occurred while attempting to read from the referenced file. Recovery: Ensure that the file exists, that the filelength is non-zero, and that read permission is allowed. Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP1803: Circular text substitution

The preprocessor has detected an attempt to perform a recursive text substitution operation, such as an INCLUDE file "including" itself, or a macro expanding itself.

ALP1804: Internal buffer overflow

The preprocessor has overflowed an internal memory buffer while trying to process the referenced token. Recovery: Reduce the number of whitespace characters preceding the token or the number of characters in the token itself.

ALP1901: Unexpected character <character-value> in identifier

The command line parser was expecting an identifier but immediately encountered a non-identifier character. Command line parsing was prematurely terminated.

ALP1902: Unexpected character <character-value> in keyword

The command line parser was expecting an keyword but immediately encountered a non-identifier character. Command line parsing was prematurely terminated.

ALP1903: Error opening response file "<file>"; <reason>

An error occurred while attempting to open the referenced file. Recovery: Verify that the file exists and that read permission is allowed. Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP1904: Invalid filename in "@" directive

The command line parser was processing an @Filename (command line response file) directive, but the token following the "@" character did not constitute a valid filename. Recovery: Ensure that only valid filename characters are used.

ALP1905: Unexpected character or terminator <character-value>

The command line parser encountered either an illegal control character or the end of the command line input stream before the current command parameter was completely parsed.

ALP1906: Numeric constant is invalid; <reason>

An error occurred while converting the referenced numeric constant to an internal representation.

Message Numbers 3000-3999: Error Messages

Error messages are typically issued during processing of the input stream and indicate a syntax or semantic error in the user program. The assembler will continue processing after an error has occurred, but since the input stream was incorrect an output object file will not be created.

ALP3201: Can't <verb> <expr_type> <from/to/by/with> <expr_type>

This message appears during expression processing when a binary operation was performed on two primary expressions of incompatible type. The message replacement parameters indicate the attempted operation.

ALP3202: Overflow or division by zero

Either the expression evaluated to a quantity that is not representable in the current expression word size, or an expression contained a binary division (/) or modulus (MOD) operation where the denominator expression was evaluated to be zero.

ALP3203: Can't take offset of expression

The expression to which the OFFSET operator was applied did not contain a constant or relocatable address. Recovery: The offset operator may not be applied to register values. If the offset expression is applied to a quoted string, ensure that the string length does not exceed the length of what is representable as a constant value, given the word size of the enclosing segment (2 for USE16 segments, 4 for USE32 segments).

ALP3204: Expecting relocatable expression

An expression was used in a context that required a segment or group relative address, but one was not supplied.

ALP3205: Expecting primary expression

The assembler was expecting a terminal operand (an identifier, register, or constant) or an expression enclosed in parentheses () or square brackets [ ]; instead, an unexpected token was encountered at the referenced location.

ALP3206: Expecting "]"

An opening bracket "[" was encountered and the subsequent expression was fully parsed, but a closing bracket "]" was not encountered.

ALP3207: Expecting ")"

An opening parenthesis "(" was encountered and the subsequent expression was fully parsed, but a closing parenthesis ")" was not encountered.

ALP3208: Forward reference needs segment override or FAR PTR

An expression contained a forward reference to a location that was later determined to be of FAR distance. When forward references are used, the assembler makes default assumptions about the eventual definition of undefined labels used in the expression; such definitions are never assumed to be in a different segment. Use of such an expression can cause differences between the code generated on the first and second passes of the assembler. Recovery: Qualify the expression with a distance override (FAR, FAR16, or FAR32) or segment override (:) operator.

ALP3210: Illegal operation on relocatable value

A unary operator was applied to an expression containing a relocatable address or indirect memory expression, but the operator may only be used with constant values.

ALP3211: Illegal type expression

A "<type> PTR" type conversion expression was encountered, but the expression given by <type> was not a valid qualified type.

ALP3212: Operands must be relative to same segment or group

A binary operation was performed on two relocatable expressions, but the expressions were not declared relative to the same segment.

ALP3213: Illegal digit(s) for current .RADIX

A literal integer constant was not qualified with a prefix or suffix (radix override), but was specified using digits that are not valid for the current radix. For instance, use of the literal 1234 is illegal when the current radix value is 2.

ALP3214: Value cannot be negative

A negative-value expression was encountered where only positive numbers are allowed, such as the count-value for the DUP operator, the field-width entry in a RECORD definition, or the shift-value in the SHL or SHR operators.

ALP3215: Expression cannot be forward-referenced

The referenced expression is used in a context where an undefined or forward-referenced value prevents the assembler from completing the operation or generating a reliable construct. This is the case during the declaration of user-defined types or where the value of the location counter will depend on the results of the expression.

ALP3216: Expression does not have an operand size

The SIZE operator was used on an expression for which no operand size exists (a simple number value, for example). The SIZE operator may only be used on expressions that have an operand size attribute, such as a variable name or type name expression.

ALP3217: Record tag expected

A left-hand identifier operand was followed by a right-hand expression list operand enclosed in angle brackets or braces. The construct was parsed as a record constant, but could not be evaluated because the left-hand operand was not a record tag name previously defined with the RECORD directive.

ALP3218: Numeric constant is invalid; <reason>

An error occurred while converting the referenced numeric constant to an internal representation.

ALP3219: Expression must be a constant value

The assembler issues this message whenever a constant expression is required, but the expression supplied contained relocation information or machine register references.

ALP3220: Undefined symbol "<identifier>"

This message appears when an identifier was referenced in an expression or type declaration, and the identifier has no external declaration or definition or is forward-referenced.

ALP3221: Expecting "," or ")"

This message appears when processing a DUP expression list and an unexpected token was encountered. The parser was expecting the list to be continued with a comma or terminated with a closing parentheses. Recovery: Check for possible unbalanced parentheses ().

ALP3222: Expecting "("

The DUP operator was encountered but was not followed by an opening parentheses to begin the duplicated expression list. Recovery: The duplicated expression list following the DUP operator must be enclosed in parentheses (), even if the expression list only contains a single item.

ALP3223: Expecting variable name

The LENGTH operator may only be applied to data labels (variable names). LENGTH returns the number of items allocated to the data label when the label was defined in a data allocation statement.

ALP3224: Expecting "," or "<closing brace/bracket>"

This message appears within a bracketed expression list where the assembler was expecting a comma to introduce the next initializer expression, or a closing brace or angle bracket to terminate the initializer expression list.

ALP3225: Register-indirect expression illegal in this context

A constant or relocatable address expression was expected but the expression also contained at least one machine register. Such an address may be calculated only at run time, and is illegal in this context.

ALP3226: Expression must have structure or union type

The expression to the left of a structure member selection operator (.) did not have a structure or union type. The assembler cannot evaluate the member expression to the right of the selection operator unless the left hand operand has an associated structure or union type. Recovery: If the left hand operand must be something other than an explicit structure or union variable (such as a register-indirect expression like [EBX]), then use the PTR operator to convert the left hand operand to the appropriate type.

ALP3227: Right operand is not a member of structure or union

The expression to the right of a structure member selection operator (.) was not a member of the left-hand structure or union expression. Recovery: The right-hand operand must be an identifier named in the type definition for the structure or union.

ALP3228: Invalid identifier type for this operation

The symbol type of the referenced identifier was not valid in this context. Recovery: This could happen if a text macro name was used in a context where macro expansions are not performed.

ALP3229: Expression type not valid in this context

The referenced expression evaluated to a type that is not valid for the context in which it was used. An example of this would be the use of a segment name or group name where a data label was expected.

Recovery: Review the expression-types allowed by the statement or clause where the referenced expression was used, and modify the construct accordingly.

ALP3301: Label must be followed by a directive

A user identifier appeared in the label field, but the end of line was encountered before an assembler directive was specified to give the label a definition.

Recovery: Code labels must be followed by a single colon (:) or double colon (::) on the same line as the label itself. Named assembler directives must appear on the same line as the associated label, or the line continuation (\) character must follow the label to create a single logical line. Check for a possible misspelled identifier or keyword. Verify that the identifier was specified using the correct uppercase and lowercase letters if case sensitive assembly is in effect.

ALP3302: Expecting label, directive, or mnemonic

The token referenced in the error message was unexpected. This error occurs when the first token on the line is not a valid label, directive, or mnemonic, or when a valid label has been encountered but was not followed by a valid directive or mnemonic.

Recovery: If this message references an identifier, check that it was spelled correctly, or that the identifier was specified using the correct uppercase and lowercase letters if case sensitive assembly is in effect.

ALP3303: Can't be preceded by data label

The referenced token is either an instruction mnemonic or a user identifier that appears after a label. If the referenced token is an instruction mnemonic, then the preceding label must be followed by a single colon (:) or double colon (::). Data labels may not be used to refer to instructions. Otherwise, it is invalid to have two labels appearing in succession. Recovery: Check for misspellings in either identifier, and that the identifiers were specified using the correct uppercase and lowercase letters if case sensitive assembly is in effect.

ALP3501: Address size mismatch

This message indicates one of the following:

An indirect memory expression contained a mixtre of 16-bit or 32-bit base or index registers. This prevents the assembler from determining the address size of the expresson, and is illegal.
The instruction performs an unalterable implicit operation which conflicts with the operands supplied.

ALP3502: Invalid register expression

A processor register was specified using indexed notation (i.e., "REG(X)"), but the expression in parentheses was out of range and did not refer to a valid register.

ALP3503: Can't use this register with scale factor

In an indirect memory expression, the scaling operator (*) was applied to a register for which the processor does not support a scaling operation. A scaling factor may only be used on 80386 or later processors, and only in 32-bit address expressions. Within this context, only the EAX, EBX, ECX, EDX, EDI, ESI, and EBP registers are valid. A scaling factor may not be applied to the ESP register.

ALP3504: Illegal target of self relative pointer

The SHORT operator was used, but the expression to which it was applied was not a simple self relative displacement. This can occur if the expression is a constant, data label, or indirect memory operand.

ALP3505: Invalid mnemonic/operand combination

This message appears when a valid mnemonic has been recognized and all operand expressions have been correctly parsed, but the assembler was unable to combine the results into a form that it could associate with a valid instruction encoding. Recovery: This usually indicates that one or more operand expressions were not correctly specified. Verify such factors as:

Correctly specified operand sizes
Register combinations allowable for this instruction
Labels or identifiers are of the correct type
Correct number of operands

ALP3506: Register combination invalid with <number>-bit expression

For 80386 processors or greater, both 16-bit and 32-bit effective addresses are supported, but the two modes differ in the register combinations that are allowed for indirect addressing. The expression used a combination that was invalid for the referenced address size. For expressions that refer to 16-bit (USE16) memory locations, only a single base register (BX or BP) and/or a single index register (DI or SI) may be used. For expressions that refer to 32-bit (USE32) memory locations, only a single base register (EAX, EBX, ECX, EDX, ESP, EBP, EDI, ESI) and/or a single index register (EAX, EBX, ECX, EDX, EBP, EDI, ESI) may be used; no single register may appear more than once in a given expression.

ALP3507: Scaling factor must be 1, 2, 4, or 8

The processor only supports the scaling factors referenced in the message.

ALP3508: Invalid use of register

One of the following illegal conditions occurred:

An attempt was made to use an unsupported register in an indirect memory expression (for example, [AH]).
An attempt was made to combine a register with other terms to form an indirect memory expression, and the register was not enclosed in square brackets [ ].
A register argument was expected and correctly parsed in an assembler directive, but the referenced register cannot be legally used in this particular context.

ALP3509: Multiple base registers

An indirect memory expression contained a combination of registers that was invalid for the selected addressing mode. More than one register was evaluated as a base register by the assembler; the processor only supports a single base register within register indirect addressing mode. For expressions that refer to 16-bit (USE16) memory locations, only BX and BP are valid base registers. For expressions that refer to 32-bit (USE32) memory locations, only EAX, EBX, ECX, EDX, ESP, EBP, EDI, and ESI are valid base registers.

ALP3510: Multiple index registers

An indirect memory expression contained a combination of registers that was invalid for the selected addressing mode. More than one register was evaluated as an index register by the assembler; the processor only supports a single index register within register indirect addressing mode. For expressions that refer to 16-bit (USE16) memory locations, only DI and SI are valid index registers. For expressions that refer to 32-bit (USE32) memory locations, only EAX, EBX, ECX, EDX, EBP, EDI, and ESI are valid index registers.

ALP3511: Multiple scaling factors

In an indirect memory expression, the scaling operator (*) was applied to more than one register term. The processor does not support more that one scaling factor within a single effective address.

ALP3512: Near target cannot be in different code segment

A JMP or CALL instruction specified a near target that was defined in a different segment, but the segments containing the instruction and the target were not named together in a GROUP directive. An instruction and its near target cannot be in different segments (addressed by the CS register) at run time.

Recovery: If the instruction was otherwise properly coded, use the GROUP directive to collect the segments together so that they will be accessible at run time with the same CS register value.

ALP3513: Need size for operand

The instruction operand list did not specify a size for the operation, and the assembler is unable to select a default instruction encoding because multiple variations exist.

Recovery: As size may be assigned to one or more of the operands by using the <type> PTR override operator.

ALP3514: Cannot establish near target without ASSUME CS:

When running the under MASM 5.10 emulation, the assembler requires the code segment register (CS) to have an ASSUME setting for the currently opened segment before it will allow the creation of explicit near code labels.

Recovery: Insert an "ASSUME CS:SegName" statement at the beginning of the segment before the appearance of any near code labels.

ALP3515: Code generation outside of segment boundaries

A processor instruction was encountered, but no program segment has been opened.

Recovery: Place all processor instructions within a named program segment.

ALP3516: Target is out of range by <displacement> bytes(s)

The instruction references a code label or address using a self-relative displacement (a signed value relative to the address of the next instruction), but the target address requires a displacement value that is too large to be encoded into the instruction.

Recovery: If the SHORT operator was used in the operand field, remove it. If the instruction is of the "conditional jump" variety, it may be necessary to transform it into a "jump around a jump" by inverting the condition under which the jump is performed, then changing the target so that it references an address immediately following a "direct jump" instruction, which must be inserted and coded so that it references the original target location.

ALP3517: Selected processor does not support this operand

An attempt was made to use an operand (such as a machine register) that does not exist on the processor for which code is being generated.

Recovery: Either use a processor selection directive to select the correct target processor, or modify the referenced operand to one that is supported on the target machine.

ALP3518: Can't access data, no ASSUME or segment override

One of the following conditions occurred:

An attempt was made to reference a named memory location that exists in a segment for which no ASSUME statement is in effect
An attempt was made to combine two terms in a binary expression that are relative to different segments.

ALP3519: Too many operands

This message appears during processing of an instruction operand list. More operand expressions were encountered than is valid for the instruction set of the target architecture.

Recovery: Remove the offending token(s) beginning at the referenced location.

ALP3520: Segment address size not supported on this processor

A 16-bit processor selection directive was encountered within a 32-bit segment, or an attempt was made to reopen a 32-bit segment after switching to a 16-bit processor type. The selected processor cannot support 32-bit segments.

ALP3521: Register expected

While processing an assembler directive an unexpected token was encountered at the referenced location. A processor register was expected instead.

ALP3522: Selected processor does not support this instruction

A mnemonic or mnemonic/operand combination has been used that is not supported by the processor for which the assembler is currently generating object code.

Recovery: Verify that the correct target processor has been selected with one of the processor selection directives, or that the correct instruction form has been coded. Since ALP does not perform some of the same implicit conversions that MASM 5.10 does, use of the <type> PTR conversion operator may be required to avoid certain type-mismatch problems.

ALP3523: Cannot change expression word size

After the expression word size was explicitly set with an OPTION EXPRxx directive, an attempt was made to alter the setting with another OPTION directive, or by switching to a 32-bit processor after an explicit OPTION EXPR16 was issued. Once set, the expression word size cannot be altered.

ALP3601: Filename expected

The INCLUDELIB directive was used, but an error occurred while attempting to parse the filename parameter.

Recovery: Verify that only legal filename characters are used. If the filename appears as a quoted string literal, verify that the literal uses legal syntax according to the rules for quoted strings.

ALP3602: Floating-point initializer illegal with integer variable

A floating point initializer was used on a variable that was not of type DD , DQ, DT, REAL4, REAL8, or REAL10.

ALP3603: Integer initializer illegal with floating-point variable

An integer initializer was used on a variable that was of type REAL4, REAL8 , or REAL10. Only floating-point initializers can be used with variables having these types.

ALP3604: Expression has no effect

During a data allocation directive, an attempt was made to initialize an item using an expression that was not correctly evaluated.

Recovery: This may indicate an error in the internal assembler logic. Note the conditions of the error, and contact IBM.

ALP3605: String is empty

During a data allocation directive, an attempt was made to initialize an item using a quoted string expression that contained no data.

Recovery: Quoted strings must contain at least one character value, otherwise the expression is illegal.

ALP3606: Symbol "<identifier> was never defined

An identifier was declared with a GROUP or PUBLIC directive, but was never given a full definition. This condition prevents the assembler from writing the appropriate records to the output object file. Recovery: Segments declared in a GROUP directive must defined in a SEGMENT directive. Identifiers declared with the PUBLIC directive must be defined as a code label, data label, or absolute symbolic constant.

ALP3607: Value not addressable

The expression following the END directive did not evaluate to segment relative address. The expression must refer to a memory location to which the operating system loader can pass control when the program is executed.

Recovery: Ensure that the expression contains no machine registers, and that it references a value relative to a segment defined within the module.

ALP3608: Segment size exceeds 64K limit

The amount of data emitted into the current (16-bit) segment has exceeded 65536. No object file can be produced under this condition, and the current location counter has been wrapped back to zero.

Recovery: Reduce the amount of code or data contained in this segment, or move some of the information to another segment.

ALP3701: Argument expected

While processing a directive that accepts a list of comma separated arguments, at least one argument followed by a comma was parsed, but no additional argument was encountered before the end of the line.

ALP3702: Can't override array with single item

Within a structure variable instantiation, an incorrect attempt was made to override the default initializer of a structure member. The structure member was defined to be of type array (having been initialized with a character string or list of expressions enclosed in brackets), and the overriding expression in the structure instantiation was a single numeric expression.

Recovery: Array members can only be overridden using a quoted character string or a bracketed list of numeric expressions.

ALP3703: .RADIX value must be one of: 2, 8, 10, or 16

Self-explanatory.

ALP3704: Can't nest initializers

This message appears when a structure instantiation contained a nested override initializer within brackets, and OPTION OLDSTRUCTS was in effect. Nested structures are not allowed when the assembler is operating in this mode.

ALP3705: Colon expected

Self-explanatory.

ALP3706: Expecting "<" or "{"

When a structure or record variable is allocated, the assembler expects one or more initializer expressions to follow the structure or record type name. Initializer expressions must be enclosed in angle brackets or braces, but an unexpected token was encountered at the referenced location.

ALP3707: Initializer too long or incorrect type

Within the initializer list of a structure instantiation, one of the following conditions occurred:

An attempt was made to initialize a structure member with a character string override that exceeded the length of the member definition.
The initializer expression type did not match that of the structure member item being initialized.

ALP3708: Invalid ALIGN setting

A zero or incorrect value was specified as the argument to the ALIGN directive.

ALP3709: Previous definition prevents external attribute

An attempt was made to declare an identifier as being external to this module, but a previous conflicting definition already exists. The operation is disallowed.

ALP3710: Syntax error; unexpected token

The referenced token is not valid for the construct being parsed. The assembler could not attempt further processing or diagnosis of the construct.

ALP3711: Previous definition prevents change in global visibility

One of the following conditions has occurred:

The PUBLIC directive or keyword was used to export an identifier, but the identifier has already been declared with attributes that prevent it from being exported.
A PUBLIC directive was used on a procedure name, but the PRIVATE keyword was used in the PROC directive that defined the procedure.

Recovery: Verify that the identifier does not appear in a COMM or EXTERN declaration, and that the identifier is a valid code or data label. Insure that the PUBLIC declaration appears before the identifier it references, and that the declaration is processed by the assembler on the first pass.

ALP3712: "<token>" must be a segment name

This message appears during processing of the GROUP directive when one of the arguments was not a valid segment name.

Recovery: Only identifiers defined using the SEGMENT directive are valid arguments to the GROUP directive. If the message is referencing an identifier, verify that it is indeed the name of a valid segment. Verify that the identifier was specified using the correct uppercase and lowercase letters if case sensitive assembly is in effect.

ALP3713: Label outside of segment boundaries

This message appears when a label definition appears outside of any enclosing segment. The label is an assembler alias for a segment relative machine address; such an address cannot be assigned to the label unless it appears inside of a program segment. This condition is an error, and must be corrected.

Recovery: Place the definition within a valid segment.

ALP3714: Directive must be named

This message appears when a directive was encountered but was not preceded by a label. A label is required for this directive.

Recovery: Precede the directive with a valid identifier.

ALP3715: Must specify all columns in .LIST ORDER

The .LIST ORDER directive did not specify a position for every possible column. All column names must appear in the list.

ALP3716: Listing control stack is empty

This message appears when the user issues a .LIST POP directive and there are no listing environment entries on the stack.

Recovery: A matching .LIST PUSH directive must be issued before .LIST POP may be used.

ALP3717: Processor mnemonic used as a label

This message is issued when a processor instruction mnemonic is used as an identifier. The severity of this message may be relaxed from Error to Warning in certain circumstances by using the +Sk command line switch.

Related Information:

#Sk - Control Use of Reserved Words as Labels

ALP3718: Misplaced ENDP; no open PROC

This error occurs when the ENDP (end procedure) directive was encountered, but there is no procedure currently open.

Recovery: The PROC directive must be used to open a procedure before the ENDP directive can be used.

ALP3719: No closing bracket

An opening bracket "[" was encountered within a directive or expression, but a matching close bracket "]" was never supplied, or was misplaced.

ALP3720: Data allocation outside of segment boundaries

A data definition directive was encountered, but no program segment has been opened.

Recovery: Place all data allocation directives within a named program segment.

ALP3721: Operation illegal within structure or union

An attempt was made to use a directive or construct that is illegal within the context of a structure definition.

Recovery: Processor instructions are not allowed in structure definitions, and only a subset of assembler directives are legal in this context.

ALP3722: Expression is not a segment or group

One of the following illegal conditions occurred:

A segment override expression (using the colon (:) operator) did not contain a valid segment register, segment name or group name expression on the left side of the colon operator.
An ASSUME directive contained an expression that did not evaluate to a valid segment or group name. The argument to the ASSUME directive specified a machine segment register, which may only be associated with a segment or group name.

Recovery: Verify the correct spelling of either the register argument or the segment name or group name expression.

ALP3723: ON or OFF expected

A listing control directive was encountered where the value of a flag is being manipulated; the ON or OFF keywords are the only values acceptable in this context.

ALP3724: ON, OFF, or BLANK expected

A listing control directive was encountered where the display or non-display of an individual column is being determined; the ON, OFF, or BLANK keywords are the only values acceptable in this context.

ALP3725: Phase error between passes

The address assigned to a label on pass one of the assembler had a different value on the second pass. This usually indicates that a forward reference to a label was not fully qualified, and the eventual definition of the label was different than what was assumed by the assembler on the first pass. On the second pass, the assembler did not need to make any assumptions about the attributes of the symbol, but the resulting generation of object code caused a discrepancy in the value of the location counter.

Recovery: Use the listing control command line options to request a listing for both pass one and pass two of the assembler; use this listing to compare location counter values prior to the point where the phase error occurred. This will reveal the instruction that caused the location counter to become unsynchronized.

Related Information:

#Lp - Generate Listing on Specific Pass

ALP3726: Symbol already defined as different type

An identifier has been redeclared to have attributes that conflict with a previous declaration or definition.

Recovery: If this is an external declaration (using an EXTRN or COMM directive) referencing a data variable, ensure that the type specifier has been correctly respecified. Verify that the variable has not already been defined within this module. External declarations for data labels or near code labels appearing within segment boundaries must not reappear within the boundaries of a different segment. Labels appearing outside of segment boundaries inherit the default address size (USE16 or USE32), and must not reappear within a segment having a conflicting address size. Far code labels may not be redeclared with conflicting address sizes.

ALP3727: PROC name mismatch

The ENDP directive was used to close the current procedure, but the name used in the ENDP directive did not match the name specified in the matching PROC directive.

ALP3728: Symbol redeclared relative to different segment

A data label or near code label appearing in an external declaration was redeclared in a different segment (or outside of segment boundaries) and conflicts with a previous declaration or definition.

Recovery: Data labels or near code labels appearing within segment boundaries must not reappear within the boundaries of a different segment. Labels appearing outside of segment boundaries inherit the default address size (USE16 or USE32), and must not reappear within a segment having a conflicting address size.

ALP3729: Attribute mismatch during reopen of segment

An existing segment was reopened using different or conflicting attributes.

Recovery: All identically named SEGMENT directives must be declared with the same attribute list. If an address size attribute (USE16 or USE32) was not explicitly specified in the SEGMENT directive, verify that the default segment word size was not altered between segment declarations with a processor selection directive.

ALP3730: No segment, structure, or union opened as "<identifier>"

The ENDS directive was used, but no segment, structure, or union was open ( or did not match the referenced name) and thus could not be terminated.

Recovery: If a name was given in the message, verify that it matches the name used in the associated SEGMENT, STRUC, or UNION directive. Verify that nested occurrences of SEGMENT, STRUC, or UNION are paired with a matching ENDS directive.

ALP3731: Identifier expected

A directive or expression operator was used such that an identifier was expected, but none was supplied.

Recovery: Check for a possible misspelled identifier; Verify that the identifier was specified using the correct uppercase and lowercase letters if case sensitive assembly is in effect. Verify that the identifier is not a reserved keyword.

ALP3732: Reserved symbol "<identifier>" cannot be created or modified

An invalid operation was performed on a reserved identifier. One of the following conditions occurred:

An attempt was made through an EQU (or =) directive to alter the value of a predefined identifier. Unless documented otherwise, this is an illegal operation.
The assembler attempted the deferred creation of a reserved symbol, but a user-defined identifier already exists with the same name and has conflicting attributes.

ALP3733: Symbol redefinition error

An attempt was made to redefine an identifier in a context where redefinitions are not allowed. Redefinitions are allowed only for text macros and assembler variables assigned using the equal (=) directive.

ALP3734: Too many initializers

A bracketed expression list within a structure instantiation or record constant contained too many comma-separated expressions. The number of initializer expressions exceeded the number of elements in the structure or record definition.

ALP3735: Qualified type or type keyword expected

This message appears when a type expression or a COMM, EXTRN, or LABEL directive was expecting a type keyword, but none was supplied.

ALP3736: Unexpected text in statement

An assembler directive was fully parsed and recognized, but invalid information was encountered at the referenced location.

ALP3737: <text>

This assembler issues this message to display user defined text when the ECHO or %OUT directives are encountered.

ALP3738: Symbol redefinition has different value

An attempt was made to redefine an EQU symbol to value which differs from a previous definition. EQU symbols may have multiple definitions only if they have identical constant values.

ALP3739: Directive illegal outside of segment boundaries

The referenced directive performs a segment-relative operation and may only be used inside of segment boundaries.

ALP3740: Alignment value must be a power of 2

The expression argument given in the ALIGN directive did not evaluate to a power of 2 (2, 4, 8, etc.).

ALP3741: Alignment value not valid with current segment alignment

The referenced alignment factor was less than the alignment factor specified in the SEGMENT declaration containing the ALIGN or EVEN statement . This condition is illegal because the assembler cannot guarantee that the linker will not invalidate the requested alignment when it exercises its right to position the entire segment according to the alignment factor given in the enclosing SEGMENT declaration.

Recovery: Respecify either the aligment factor or the SEGMENT delaration so that the segment alignment is greater than or equal to any alignment factor requested therein.

ALP3742: Redefinition has different number of fields

A RECORD type redefinition did not contain the same number of fields as a previous definition.

ALP3743: Redefinition has different value

A redefinition construct was encountered (such as a type definition directive) where the redefined value did not match that of a previous definition. Redefinitions are allowed for this particular construct, but they must restate the same value given in the original definition.

ALP3744: Too many bits in record definition

The referenced record definition exceeded the maximum allowable value of 32 bits.

ALP3745: Record tag or fieldname expected

The operand of the MASK or WIDTH operators must be an identifier defined with the RECORD directive. This identifier must be either the tag name of the record itself, or one of the field name entries defined within the body of the RECORD directive.

ALP3746: Value is out of range

The value of the referenced expression is not representable, requires too many significant bits to be stored, or lies outside the range of legal values for this context.

ALP3747: Mismatch of segment address sizes in group

A group was declared to contain segments of differing address sizes. A group may contain either USE16 or USE32 segments, but not a combination of both.

ALP3748: Segment already a member of group "<group-name>"

An attempt was made to assign a segment to more than one parent group.

ALP3749: Directive requires use of .MODEL

A simplified segmentation operation was encountered but a .MODEL directive was never processed.

ALP3750: PROC must immediately precede LOCAL

A LOCAL assembler directive was encountered, and one of the following occurred:

The LOCAL directive was not enclosed within a PROC/ENDP procedure block.
The LOCAL directive was positioned within a procedure block, but other assembler directives or instructions were encountered between the PROC directive and the LOCAL directive.

ALP3751: Operand has incorrect size

The size given for an operand was incorrect, or did not match that of a destination or target operand where it is to be used.

ALP3752: Mismatch in <attribute> attribute

The value of an attribute specified in a redeclaration or redefinition did not match the value given in the original declaration or definition. The body of the message indicates the type of attribute that is mismatched, and the assembler follows this message with two 5704 informational messages showing the coordinates and values of the mismatched constructs.

ALP3753: Name collision caused by promotion from inner scope

During a definition of a structure (or union) type, a field identifier defined at the outer (current) scope had the same name as a field defined in a promoted inner scope (one created through the use of an unnamed imbedded structure). When a structure type is used to create an unnamed field within another structure type, all of the field names from the inner structure are "promoted", or made visible to the outer defining scope.

Recovery: One of the field identifier names must be altered to avoid the name collision. Alternatively, the unnamed imbedded structure may be given an explicit field name, in which case its own fields are no longer promoted, and fully-qualified references must be used to reach them from within expressions.

ALP3754: Cannot determine calling convention

A procedure was defined to accept arguments passed on the stack by a calling routine, but no language attribute was specified or assumed for the procedure. The language attribute determines the calling convention, which in turn defines the order that arguments are pushed onto the stack.

Recovery: Use one of the following constructs:

Specify an explicit language keyword in the body of the PROC directive.
Specify a .MODEL directive with a language keyword argument.
Specify an OPTION LANGUAGE directive.

ALP3801: Argument expected

When processing one of the EQU, IRP, IRPC, FOR, or FORC macro directives, the required argument immediately following the directive was missing or incorrectly specified.

Recovery: Modify the referenced token so that it is a valid argument for the directive. If this directive appears within a nested macro expansion, check to see that correct arguments were passed to outer level macros, or that outer level macro definitions are correct.

ALP3802: EXITM outside of macro

The EXITM keyword was encountered outside the context of a macro body.

Recovery: Verify that unexpected conditional assembly results are not affecting the block structure of the program. The EXITM keyword may not be used outside the scope of a macro body.

ALP3803: Comma expected

Self-explanatory. This message is displayed for any preprocessor directive that requires a comma where one was not supplied.

ALP3804: Extra data on line

This message appears any time the preprocessor has parsed a correctly formed preprocessor directive, but additional token(s) (other than comments were encountered before the end of line was reached.

Recovery: Remove the offending token(s) beginning at the referenced location.

ALP3805: Filename expected

This message appears when an INCLUDE preprocessor directive did not contain a properly formed filename. The INCLUDE directive is ignored.

ALP3806: <text>

This is the message printed as part of a conditional error directive; if one of these directives is processed and the user has included text information to be printed, it will appear in the <text> field of the message. If no user text was specified, this parameter will be empty and the message will contain no additional text.

Recovery: This was a forced error.

ALP3807: Identifier expected

This message appears when a conditional preprocessor directive was expecting an identifier and one was not supplied.

ALP3808: Reserved macro "<macro-name>" cannot be redefined

The assembler defines the referenced identifier for its own purposes; it may not be redefined by the user.

ALP3809: Missing ENDM

The preprocessor was reading the body of a macro definition when the end of the current input stream was reached; the macro definition was never closed with an ENDM keyword.

Recovery: Verify that unexpected conditional assembly results are not affecting the block structure of the program. A macro definition may not be closed in an input stream different from the one where it was started.

ALP3810: <ELSExx/ENDIF> without matching IFxxx

This message indicates that an ELSE or ENDIF construct was encountered prior to encountering an IF construct.

ALP3811: Reserved symbol "<identifier>" cannot be modified

An attempt was made through the -D command line option to alter the value of a predefined identifier. Unless documented otherwise, this is an illegal operation.

ALP3812: Symbol "<identifier>" already defined

An attempt was made to define a preprocessor macro name that conflicts with an existing identifier of an incompatible type.

ALP3813: <Text-Item> expected

This message is displayed when a preprocessor directive expected a text argument enclosed in angle brackets < >, but a valid argument was not supplied.

ALP3814: Invalid character in numeric constant

The assembler was parsing a numeric constant and an alphabetic character was encountered that was not a valid radix specifier or hexadecimal digit.

ALP3815: Illegal digit(s) for specified radix

A literal integer constant was qualified with radix override, but was specified using digits that are not valid for the given radix qualifier. For instance, use of the literal 1234Y is not legal because the Y suffix specifies a binary number and only the digits 0 and 1 are valid binary digits.

ALP3816: Expecting ">"

This message appears when the preprocessor is parsing a <text-item> and the end of line or end of file was encountered. A closing angle bracket (>) was expected.

ALP3817: Unterminated COMMENT

The preprocessor was scanning the body of a COMMENT directive when the end of the current input stream was encountered; the closing delimiter character originally specified in the COMMENT directive was never encountered.

Recovery: Block comments may not span across input files. Provide a closing delimiter as specified in the opening COMMENT directive.

ALP3896: Control character illegal in this context

A COMMENT preprocessor directive was encountered, and an attempt was made to scan for the next character which signifies the beginning and end of the comment text, but an unexpected non-printable control character was encountered instead.

Recovery: Only characters that are representable as printable text may be used to open and close a COMMENT sequence.

ALP3897: No closing quote

The preprocessor was parsing a quoted string literal, and the end of line or other terminator was encountered before the literal was ended with a closing quote character.

Recovery: Verify that only single quotes (´´) or double quotes ("") are used to open and close a string literal; they must be used in pairs. Verify that the ending quote character was not immediately preceded by another identical quote character; the assembler interprets this sequence as a request to insert a quote character into the string literal.

ALP3898: Unexpected end of file

The lexical analyzer portion of the assembler preprocessor was scanning within the body of a token (for example, a block comment), when the end of the input stream was encountered.

ALP3899: Unexpected terminator

The lexical analyzer portion of the assembler preprocessor was performing a text substitution operation as directed by one of the "!" or "&" operators, when the end of file or internal macro buffer was encountered.

Message Numbers 4000-4999: Warning Messages

Warning messages are issued when the assembler detects a questionable construct in the input stream. The condition is not severe enough to prevent generation of an object file, but the situation should be investigated and corrected since the output program may be incorrect.

ALP4201: Offset operator applied to register-indirect expression

An OFFSET operator was applied to a register-indirect expression. In MASM 5.10 emulation mode this does not cause conversion to an immediate expression; instead the register-indirect addressing mode attributes are retained, and the assembler applies the OFFSET operator to the displacement field, forcing it to have the size of the address offset. Applying the OFFSET operator to a register-indirect expression is illegal if the assembler is not operating under MASM 5.10 emulation.

ALP4202: Invalid type expression; cannot convert

Under MASM 5.10 emulation, a constant numeric expression may be used as the left-hand operand of the PTR operator. In the referenced expression, the left-hand operand of the PTR operator did not evaluate to a value suitable for use as the operand size of the right-hand operand. The operand size of the right-hand operator was not converted.

ALP4203: Type conversion operation has no effect

A type conversion operation involving the PTR operator was performed on an expression whose type cannot be modified. For example, the right operand of the PTR operator cannot be a register value.

ALP4401: Error closing listing file

An error occurred while attempting to close the referenced file. Recovery: Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP4402: Error deleting listing file

An error occurred while attempting to delete the referenced file. Recovery: Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP4501: Assuming NEAR distance for operand size

A CALL or JMP instruction was coded to pass control indirectly through a memory operand of indeterminate size. When operating in MASM 5.10 emulation mode, the memory operand is assumed to have the same size as address size of the segment containing the CALL or JMP instruction, and implies a target having NEAR distance. Recovery: The memory operand should be given an explicit size, regardless of whether or not the default address size and NEAR distance is the desired operation. This code will cause assembly errors if not assembled under MASM 5.10 emulation mode.

ALP4502: Can't ASSUME CS to a grouped segment

An attempt was made to ASSUME the CS register to a segment that was previously named in a GROUP directive. This implies that the CS register might have different values to access the same body of code at runtime. This is illegal, and the assembler altered the ASSUME operation to refer to the group containing the segment instead. Recovery: If running the assembler under MASM 5.10 emulation, change the ASSUME directive to refer to the group name containing the segment; otherwise, remove the ASSUME statement.

ALP4503: Operand size does not match instruction

This is a warning message that appears when an operand specifies a size that differs from the operand size of the instruction. In this case, the operand size is implied by the instruction itself, and an explicit operand size is not required. However, if an operand size is supplied, it must match the implied size or this warning will be issued.

ALP4504: [Constant] is immediate in MASM mode

This message indicates that a single expression coded as a constant value in square brackets [ ] is treated as though the brackets were not specified (when the assembler is operating in MASM emulation mode, which is the default). This warning is issued because brackets are required for an indirect memory expression when registers are involved, and the connotation is that the presence of brackets is required to force a memory reference, when in fact they are ignored. Recovery: Use a segment override (for example, DS:[1234h]) when an indirect memory reference to an absolute address is desired. As explained above, the presence of brackets shown in the example is not required, but they are preferred for readability. Note: A future release may provide an alternate mode of operation such that bracketed constant values will be treated as memory references; this warning message thus points out constructs that are incompatible with any future releases operating in this mode. Since the presence of brackets are currently redundant in this context (and indicate a possible programming error), it is recommended that they be removed.

ALP4505: Access to data through a code label

This warning occurs when an instruction attempts a memory access through a code label (a procedure name or a label followed by a colon). This is an invalid operation unless a type conversion is first performed on the expression containing the label.

ALP4506: Selected processor does not support this instruction

This message is issued under the same circumstances as message ALP3522, but has reduced severity when the assembler is operating under MASM emulation.

ALP4507: Only storing NEAR portion of FAR pointer

Within a data allocation directive, a variable was initialized to contain the address of a FAR code label or variable defined in another segment. However, the size of the variable being initialized is not large enough to hold the fully qualified address (both segment and offset) of the item, and only the offset portion was stored. Recovery: If the full address of the pointer is desired, then the size of the data item being initialized must be increased. Otherwise, the OFFSET operator should be used in the address expression to truncate the segment information and suppress this warning.

ALP4508: Operand size inferred from immediate value

When operating under MASM 5.10 emulation mode, the assembler allows an immediate value to determine the size of the memory operand to which it is applied if its magnitude exceeds that which will fit into a byte. In this case, it is assumed that the operation refers to a word-sized memory operand (2 bytes in USE16 segment, 4 bytes in a USE32 segment). If the magnitude of the immediate value is sufficiently small (less than 128), then the operation is ambiguous, and an error is generated because the assembler does not know whether to treat the memory operand as a byte or a word value. Recovery: An explicit size should be given to the memory operand. Code relying on this behavior will not assemble correctly if the assembler is not operating in MASM 5.10 emulation mode.

ALP4509: Operand size mismatch

One of the following conditions occurred:

An attempt was made within a data allocation directive to initialize an item with an expression having an explicit and different size.
A memory operand with an explicit size was used in conjunction with a register operand, but two operand sizes did not match. The register operand size overrides the size of the memory operand.
A memory operand with an explicit size was used in conjunction with an address offset. The size of the memory operand and the size implied by the address size of the offset value did not match.

ALP4510: Truncation of significant bits in immediate value

One of the following conditions occurred:

An operand expression was encoded into the instruction as an immediate value, but the magnitude of the numeric expression exceeded the number of bits required to store it in instruction encoding; the value was truncated to fit in the allotted space.

Since the assembler uses 32-bit arithmetic during expression processing, operations such as negation or logical inversion of small numeric quantities can result in values that require all 32 bits of precision.

A relocatable immediate expression was converted to a smaller type, thus affecting the type of the relocation record generated for resolution by the linker. This could happen if an offset expression was forced into a byte sized storage space.

Recovery: Use the <type> PTR override to explicitly convert the expression to a value of the proper size.

ALP4512: Can't ASSUME CS to different segment or group; ignored

Within an open segment, an attempt was made to ASSUME the CS register to a different segment, or to a group not containing the currently opened segment. The operation was not allowed. Recovery: Remove the ASSUME statement, or adjust it so that it specifies the currently opened code segment or a group containing the segment.

ALP4513: Invalid mnemonic/operand combination

This message is issued under circumstances similar to that of message ALP3505. In this case an instruction encoding was found for the given mnemonic/operand combination, but the encoding is considered invalid when the assembler is not operating under this level of MASM emulation; thus this warning is issued.

ALP4514: No size for operand, assuming default

This message indicates that no operand size was given for the instruction, but the assembler was able to infer an operand size from the instruction itself. This message is only issued when the assembler is operating under MASM 5.10 emulation. In this mode, a default operand size is associated with certain processor mnemonics; this default value is used when no explicit operand size is given. Recovery: An explicit operand size should be given for the referenced expression because the assembler is automatically resolving a potentially dangerous ambiguity in its selection of a default operand size.

ALP4601: Error closing object file

An error occurred while attempting to close the referenced file. Recovery: Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP4602: Error deleting object file

An error occurred while attempting to delete the referenced file. Recovery: Verify that no other processes are accessing the file, and that the file system is functioning correctly.

ALP4603: Missing END

The end of file was encountered but an END directive was never processed. All top-level assembler modules invoked from the command line must have an END directive as the last statement in the file. Files processed with the INCLUDE preprocessor directive should not contain an END statement.

ALP4701: Unterminated PROC

When the end of the source input stream was encountered, it was determined that a procedure was opened with a PROC directive, but never closed. Recovery: Any procedures opened with PROC must be closed within the same input stream using the ENDP directive.

ALP4702: Unterminated segment ""

When the end of the source input stream was encountered, it was determined that a segment was opened with a SEGMENT directive, but never closed. Recovery: Any segments opened with SEGMENT must be closed within the same input stream using the ENDS directive.

ALP4703: Unterminated structure or union

When the end of the source input stream was encountered, it was determined that a structure or union was opened with a STRUC/STRUCT or UNION directive , but never closed. Recovery: Any structure or union must be terminated using the ENDS directive.

ALP4704: Address size mismatch

The referenced address expression was used as a source operand, but the address size of the expression did not match the size of the target operand . An implicit conversion was applied to the address size of the referenced expression.

ALP4706: Processor mnemonic used as a label

This message is issued when a processor instruction mnemonic is used as an identifier. This condition is normally an error if the +Sk command line switch is turned off. Related Information:

Sk - Control Use of Reserved Words as Labels

ALP4707: Alignment value not valid with current segment alignment

The referenced alignment factor was less than the alignment factor specified in the SEGMENT declaration containing the ALIGN statement. This condition is illegal because the assembler cannot guarantee that the linker will not invalidate the requested alignment when it exercises its right to position the entire segment according to the alignment factor given in the enclosing SEGMENT declaration. Note: This condition is allowed to exist as a warning under MASM 5.10 emulation for backward compatibility with existing source files. Recovery: Respecify either the aligment factor or the SEGMENT delaration so that the segment alignment is greater than or equal to any alignment factor requested therein.

ALP4708: Symbol redeclared relative to different segment

This message is issued under the same circumstances as message ALP3728, but has reduced severity when the assembler is operating under MASM emulation.

ALP4709: Label outside segment boundaries

This message is issued under the same circumstances as message ALP3713, but has reduced severity when the assembler is operating under MASM 5.10 emulation.

ALP4710: Identifier expected

This message is issued under the same circumstances as message ALP3731, but has reduced severity when the assembler is operating under MASM 5.10 emulation.

ALP4711: Attribute respecification ignored

An attempt was made in a directive to change an attribute that has already been specified. Once set, the attribute cannot be changed. If the attribute is respecified, it must match the existing setting or this warning will be issued.

ALP4712: Mismatch of segment address sizes in group

This message is issued under the same circumstances as message ALP3747, but has reduced severity when the assembler is operating under MASM 5.10 emulation.

ALP4713: Attribute mismatch during reopen of segment

This message is issued under the same circumstances as message ALP3729, but has reduced severity when the assembler is operating under MASM 5.10 emulation.

ALP4801: Identifier expected, condition is false

For compatibility with MASM, the IFDEF and IFNDEF preprocessor directives will accept a non-identifier token as an argument, but this warning is issued to indicate that the condition cannot be properly tested, and the result is always false. Recovery: Modify the argument so that it is a correctly formed identifier.

ALP4802: Extra data on line

This message appears under the same conditions as that of ALP3804, but for better compatibility with MASM the severity has been reduced from an error to a warning. This message will be issued if an IFDEF, IFNDEF, ELSEIFDEF, or ELSEIFNDEF directive contains extra data at the end of the line. Recovery: Remove the offending token(s) beginning at the referenced location.

ALP4803: Expecting ">"

This message appears when the preprocessor is parsing a <text-item> and the end of line or end of file was encountered. A closing angle bracket (>) was expected.

ALP4804: Expression expected, zero assumed

For compatibility with MASM, certain preprocessor directives that expect an expression operand will not issue an error if the operand is absent. This warning is issued instead to indicate that an implicit expression value of zero is assumed.

ALP4899: Illegal character

This message is issued by the text preprocessor when a character was encountered in the source stream that is not part of the valid execution character set. Recovery: This may cause undefined behaviors, and a text editor should be used to remove the offending character.

Message Numbers 5000-5999: Informational Messages

Informational messages may be requested with a command line option (see #M - Control Individual Messages or Groups) and provide the user with a variety of useful information. All informational messages are disabled by default.

ALP5001: Number of Errors :<number>

Informs the user of the number of error messages issued during the assembly.

ALP5002: Number of Warnings :<number>

Informs the user of the number of warning messages issued during the assembly.

ALP5003: Number of Symbols :<number>

This message indicates how many user identifiers were defined during the assembly.

ALP5101: Opened message output file "<file>"

This message indicates that the message output processor has opened and is prepared to write to the referenced file.

ALP5201: Operand is declared relative to "<identifier>"

This message indicates that the referenced relocatable expression is declared relative to the given segment or group name.

ALP5301: Assembler is on source pass <number>

This messages indicates that the assembler has begun processing the referenced pass through the input stream.

ALP5401: Closed listing output file "<file>"

This message indicates that the listing file processor has closed the referenced file.

ALP5402: Deleted listing output file "<file>"

This message indicates that the listing file processor has deleted the referenced file.

ALP5403: Opened listing output file "<file>"

This message indicates that the listing file processor has opened and is prepared to write to the referenced file.

ALP5501: Address size is <USE16/USE32>

This message provides information to supplement the occurrence of other related warning or error messages. The expression referenced by the message coordinates has inherited or has been assigned the address size given in the message text.

ALP5502: No size for operand, assuming default

This message indicates that no operand size was given for the instruction, but the assembler was able to infer an operand size from the instruction itself.

ALP5503: Instruction padded with NOP(s)

This message indicates that the assembler generated one or more NOP instructions to follow the object code generated for the referenced instruction. The instruction operand list contains a forward-referenced expression which forced the assembler to allow space for the longest possible instruction encoding on the first pass. The generation of NOP instructions may be avoided by qualifying the forward reference with a <type> PTR override.

ALP5504: Operand size is <number>

This is an informational message that typically accompanies other errors or warnings dealing with operand size problems. This message is issued for every operand expression involved in the condition that caused the associated error or warning message, and indicates the operand size of the referenced expression.

ALP5505: Segment override has no effect

This message is issued when a segment override operator was used in an expression, but the override was discarded because the offset operator was applied.

ALP5506: Generated ASSUME CS:<signal>

This message is issued when an attempt is made to generate code in an open segment for which there is no valid ASSUME CS in effect. The assembler automatically generates an ASSUME statement such that the CS register is associated with the currently opened segment or with the group containing that segment if one exists.

ALP5601: Closed object output file "<file>"

This message indicates that the object file processor has closed the referenced file.

ALP5602: Deleted object output file "<file>"

This message indicates that the object file processor has deleted the referenced file.

ALP5603: Opened object output file "<file>"

This message indicates that the object file processor has opened and is prepared to write to the referenced file.

ALP5701: Assembly terminated by .ABORT

The .ABORT directive was used to terminate the assembler at the referenced location.

ALP5702: Address size assumed to be <USE16/USE32>

This messages indicates that the referenced identifier was an external code label declared outside of segment boundaries, and was assumed to be defined in an external segment having the referenced address size.

ALP5703: Structure redefinition: "<identifier>"

This message indicates that the current structure definition is replacing a previous definition of the same name.

ALP5704: Declaration sets <attribute> = <keyword>

This message describes the attribute that is mismatched in a segment redeclaration.

ALP5705: <directive> outside of segment boundaries

This message appears when an external declaration (COMM or EXTRN) appears outside of any enclosing segment.

If an external declaration is not enclosed in a segment definition that describes how the external symbol is ultimately defined, the assembler is deprived of segment attribute information; in particular, USE16 versus USE32. This could cause the assembler to generate incorrect object code, and may also cause linker errors. Recovery: Place the external declaration within a segment definition that correctly reflects the segment definition in the external module where the symbol is defined.

ALP5801: Begin skipping tokens

This message indicates that the results of a conditional assembly directive were evaluated to be false, and that the preprocessor has begun discarding tokens at the referenced location. No tokens will be returned to the parser until an appropriate ELSE or ENDIF condition is encountered.

ALP5802: Finished skipping tokens

This message indicates that a false conditional block was ended with an appropriate ELSE or ENDIF construct. The preprocessor will begin returning tokens to the parser after the referenced location.

ALP5803: Closed source file "<file>"

This message indicates that the preprocessor has closed the referenced file.

ALP5804: Opened source file "<file>"

This message indicates that the preprocessor has opened and is prepared to read from the referenced file.

ALP5805: Macro redefinition: "<macro-name>"

This message indicates that the current macro definition is replacing a previous definition of the same name.

ALP5806: Opened INCLUDE file "<file>"

This message indicates that the preprocessor has opened and is prepared to read from the referenced include file.

ALP5807: Closed INCLUDE file "<file>"

This message indicates that the preprocessor has closed the referenced include file.

ALP5901: Closed response file "<file>"

This message indicates that the command line processor has closed the referenced file.

ALP5902: Opened response file "<file>"

This message indicates that the command line processor has opened and is prepared to read from the referenced file.

Return Codes

When ALP completes, it passes a return code back to the program that invoked it. This return code shows whether ALP completed successfully or with an error. The return codes are:

0 Normal program completion.
1 User-specified file not found.
2 Unexpected system error.
3 Terminated by user or operating system.
4 Syntax errors in input file.
5 Command line usage error.
6 Internal sanity check failure.
7 Error accessing ALP messages file.

Notices

October 1997

The following paragraph does not apply to the United Kingdom or any country where such provisions are inconsistent with local law:

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