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Supported constructs in language and address expressions for MACRO-32 follow:
Symbol | Construct |
---|---|
[ ] | Subscripting |
<p,s,e> | Bit field selection as in BLISS |
The DST information generated by the MACRO-32 assembler treats a label that is followed by an assembler directive for storage allocation as an array variable whose name is the label. This enables you to use the array syntax of a high-level language when examining or manipulating such data.
In the following example of MACRO-32 source code, the label LAB4 designates hexadecimal data stored in four words:
LAB4: .WORD ^X3F,5[2],^X3C |
The debugger treats LAB4 as an array variable. For example, the following command displays the value stored in each element (word):
DBG> EXAMINE LAB4 .MAIN.\MAIN\LAB4 [0]: 003F [1]: 0005 [2]: 0005 [3]: 003C |
The following command displays the value stored in the fourth word (the first word is indexed as element "0"):
DBG> EXAMINE LAB4[3] .MAIN.\MAIN\LAB4[3]: 03C |
MACRO-32 binds a data type to a label name according to the assembler directive that follows the label definition. Supported MACRO-32 directives follow:
MACRO-32 Directives | Operating System Data Type Name |
---|---|
.BYTE | Byte Unsigned (BU) |
.WORD | Word Unsigned (WU) |
.LONG | Longword Unsigned (LU) |
.SIGNED_BYTE | Byte Integer (B) |
.SIGNED_WORD | Word Integer (W) |
.LONG | Longword Integer (L) |
.QUAD | Quadword Integer (Q) |
.F_FLOATING | F_Floating (F) |
.D_FLOATING | D_Floating (D) |
.G_FLOATING | G_Floating (G) |
.H_FLOATING | H_Floating (H) (VAX specific) |
(Not applicable) | Packed decimal (P) |
Programmers who are porting applications written in MACRO-32 to Alpha
systems use the MACRO-32 compiler (AMACRO). A debugging session for
compiled MACRO-32 code is similar to that for assembled code. However,
there are some important differences that are described in this
section. For complete information on porting these applications, see
the Porting VAX MACRO Code from OpenVMS VAX to OpenVMS Alpha
manual.
C.10.4.1 Code Relocation
One major difference is the fact that the code is compiled. On a VAX
system, each MACRO-32 instruction is a single machine instruction. On
an Alpha system, each MACRO-32 instruction may be compiled into many
Alpha machine instructions. A major side effect of this difference is
the relocation and rescheduling of code if you do not specify
/NOOPTIMIZE in your compile command. After you have debugged your code,
you can recompile without /NOOPTIMIZE to improve performance.
C.10.4.2 Symbolic Variables
Another major difference between debugging compiled code and debugging assembled code is a new concept to MACRO--2, the definition of symbolic variables for examining routine arguments. On VAX systems, when you were debugging a routine and wanted to examine the arguments, you would typically do something like the following:
DBG> EXAMINE @AP ; to see the argument count DBG> EXAMINE @AP+4 ; to examine the first arg |
or
DBG> EXAMINE @AP ; to see arg count DBG> EXAMINE .+4:.+20 ; to see first 5 args |
On Alpha systems, the arguments do not reside in a vector in memory as they did on VAX systems. Furthermore, there is no AP register on Alpha systems. If you type EXAMINE @AP when debugging MACRO compiled code, the debugger reports that AP is an undefined symbol.
In the compiled code, the arguments can reside in some combination of:
The compiler does not require that you read the generated code to
locate the arguments. Instead, it provides $ARGn symbols that
point to the correct argument locations. $ARG0 is the same as @AP+0 is
on VAX systems, that is, the argument count. $ARG1 is the first
argument, $ARG2 is the second argument, and so forth. These symbols are
defined in CALL_ENTRY and JSB_ENTRY directives, but not in
EXCEPTION_ENTRY directives.
C.10.4.3 Locating Arguments Without $ARGn Symbols
There may be additional arguments in your code for which the compiler did not generate a $ARGn symbol. The number of $ARGn symbols defined for a .CALL_ENTRY routine is the maximum number detected by the compiler (either by automatic detection or as specified by MAX_ARGS) or 16, whichever is less. For a .JSB_ENTRY routine, since the arguments are homed in the caller's stack frame and the compiler cannot detect the actual number, it always creates eight $ARGn symbols.
In most cases, you can easily find any additional arguments, but in
some cases you cannot.
C.10.4.4 Arguments That Are Easy to Locate
You can easily find additional arguments if:
For example, you can examine arguments beyond the eighth argument in a JSB routine (where the argument list must be homed in the caller), as follows:
DBG> EX $ARG8 ; highest defined $ARGn . . . DBG> EX .+4 ; next arg is in next longword . . . DBG> EX .+4 ; and so on |
This example assumes that the caller detected at least ten arguments when homing the argument list.
To find arguments beyond the last $ARGn symbol in a routine
that did not home the arguments, proceed exactly as in the previous
example except substitute EX .+8 for EX .+4.
C.10.4.5 Arguments That Are Not Easy to Locate
You cannot easily find additional arguments if:
The only way to find the additional arguments in these cases is to
examine the compiled machine code to determine where the arguments
reside. Both of these problems are eliminated if MAX_ARGS is specified
correctly for the maximum argument that you want to examine.
C.10.4.6 Debugging Code with Floating-Point Data
The following list provides important information about debugging compiled MACRO-32 code with floating-point data on an Alpha system:
EXAMINE/G_FLOAT R4 |
MOVG DATA, R6 |
DBG> EX R6 .MAIN.\%LINE 100\%R6: 0FFFFFFFF D8E640D1 DBG> EX R7 .MAIN.\%LINE 100\%R7: 00000000 2F1B24DD DBG> DEP R0 = 2F1B24DDD8E640D1 DBG> EX/G_FLOAT R0 .MAIN.\%LINE 100\%R0: 4568.89900000000 |
The following list provides important information about debugging compiled MACRO-32 code with packed decimal data on an Alpha system:
The following subtopics describe debugger support for MACRO-64.
C.11.1 Operators in Language Expressions
Language MACRO-64 does not have expressions in the same sense as high-level languages. Only assembly-time expressions and only a limited set of operators are accepted. To permit the MACRO-64 programmer to use expressions at debug-time as freely as in other languages, the debugger accepts a number of operators in MACRO-64 language expressions that are not found in MACRO-64 itself. In particular, the debugger accepts a complete set of comparison and Boolean operators modeled after BLISS. It also accepts the indirection operator and the normal arithmetic operators.
Kind | Symbol | Function |
---|---|---|
Prefix | @ | Indirection |
Prefix | . | Indirection |
Prefix | + | Unary plus |
Prefix | - | Unary minus (negation) |
Infix | + | Addition |
Infix | - | Subtraction |
Infix | * | Multiplication |
Infix | / | Division |
Infix | MOD | Remainder |
Infix | @ | Left shift |
Infix | EQL | Equal to |
Infix | EQLU | Equal to |
Infix | NEQ | Not equal to |
Infix | NEQU | Not equal to |
Infix | GTR | Greater than |
Infix | GTRU | Greater than unsigned |
Infix | GEQ | Greater than or equal to |
Infix | GEQU | Greater than or equal to unsigned |
Infix | LSS | Less than |
Infix | LSSU | Less than unsigned |
Infix | LEQ | Less than or equal to |
Infix | LEQU | Less than or equal to unsigned |
Prefix | NOT | Bit-wise NOT |
Infix | AND | Bit-wise AND |
Infix | OR | Bit-wise OR |
Infix | XOR | Bit-wise exclusive OR |
Infix | EQV | Bit-wise equivalence |
C.11.2 Constructs in Language and Address Expressions
Supported constructs in language and address expressions for MACRO-64
follow:
Symbol | Construct |
---|---|
<p,s,e> | Bit field selection as in BLISS |
MACRO-64 binds a data type to a label name according to the data directive that follows the label definition. For example, in the following code fragment, the .LONG data directive directs MACRO-64 to bind the longword integer data type to labels V1, V2, and V3:
.PSECT A, NOEXE .BYTE 5 V1: V2: V3: .LONG 7 |
To confirm the type bound to V1, V2, and V3, issue a SHOW SYMBOL/TYPE command with a V* parameter. The following display results:
data .MAIN.\V1 atomic type, longword integer, size: 4 bytes data .MAIN.\V2 atomic type, longword integer, size: 4 bytes data .MAIN.\V3 atomic type, longword integer, size: 4 bytes) |
Supported MACRO-64 directives follow:
MACRO-64 Directives | Operating System Data Type Name |
---|---|
.BYTE | Byte Unsigned (BU) |
.WORD | Word Unsigned (WU) |
.LONG | Longword Unsigned (LU) |
.SIGNED_BYTE | Byte Integer (B) |
.SIGNED_WORD | Word Integer (W) |
.LONG | Longword Integer (L) |
.QUAD | Quadword Integer (Q) |
.F_FLOATING | F_Floating (F) |
.D_FLOATING | D_Floating (D) |
.G_FLOATING | G_Floating (G) |
.S_FLOATING (Alpha specific) | S_Floating (S) |
.T_FLOATING (Alpha specific) | T_Floating (T) |
(Not applicable) | Packed decimal (P) |
C.12 Pascal
The following subtopics describe debugger support for Pascal.
C.12.1 Operators in Language Expressions
Supported Pascal operators in language expressions include:
Kind | Symbol | Function |
---|---|---|
Prefix | + | Unary plus |
Prefix | - | Unary minus (negation) |
Infix | + | Addition, concatenation |
Infix | - | Subtraction |
Infix | * | Multiplication |
Infix | / | Real division |
Infix | DIV | Integer division |
Infix | MOD | Modulus |
Infix | REM | Remainder |
Infix | ** | Exponentiation (VAX specific) |
Infix | IN | Set membership |
Infix | = | Equal to |
Infix | <> | Not equal to |
Infix | > | Greater than |
Infix | >= | Greater than or equal to |
Infix | < | Less than |
Infix | <= | Less than or equal to |
Prefix | NOT | Logical NOT |
Infix | AND | Logical AND |
Infix | OR | Logical OR |
The typecast operator (::) is not supported in language expressions.
C.12.2 Constructs in Language and Address Expressions
Supported constructs in language and address expressions for Pascal
follow:
Symbol | Construct |
---|---|
[ ] | Subscripting |
. (period) | Record component selection |
^ (circumflex) | Pointer dereferencing |
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