OpenCores
URL https://opencores.org/ocsvn/openrisc/openrisc/trunk

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [gnu-old/] [binutils-2.18.50/] [gas/] [doc/] [c-i370.texi] - Blame information for rev 832

Go to most recent revision | Details | Compare with Previous | View Log

Line No. Rev Author Line
1 38 julius
@c Copyright 2000, 2002 Free Software Foundation, Inc.
2
@c This is part of the GAS manual.
3
@c For copying conditions, see the file as.texinfo.
4
@ifset GENERIC
5
@page
6
@node ESA/390-Dependent
7
@chapter ESA/390 Dependent Features
8
@end ifset
9
@ifclear GENERIC
10
@node Machine Dependencies
11
@chapter ESA/390 Dependent Features
12
@end ifclear
13
 
14
@cindex i370 support
15
@cindex ESA/390 support
16
 
17
@menu
18
* ESA/390 Notes::                Notes
19
* ESA/390 Options::              Options
20
* ESA/390 Syntax::               Syntax
21
* ESA/390 Floating Point::       Floating Point
22
* ESA/390 Directives::           ESA/390 Machine Directives
23
* ESA/390 Opcodes::              Opcodes
24
@end menu
25
 
26
@node ESA/390 Notes
27
@section Notes
28
The ESA/390 @code{@value{AS}} port is currently intended to be a back-end
29
for the @sc{gnu} @sc{cc} compiler.  It is not HLASM compatible, although
30
it does support a subset of some of the HLASM directives.  The only
31
supported binary file format is ELF; none of the usual MVS/VM/OE/USS
32
object file formats, such as ESD or XSD, are supported.
33
 
34
When used with the @sc{gnu} @sc{cc} compiler, the ESA/390 @code{@value{AS}}
35
will produce correct, fully relocated, functional binaries, and has been
36
used to compile and execute large projects.  However, many aspects should
37
still be considered experimental; these include shared library support,
38
dynamically loadable objects, and any relocation other than the 31-bit
39
relocation.
40
 
41
@node ESA/390 Options
42
@section Options
43
@code{@value{AS}} has no machine-dependent command-line options for the ESA/390.
44
 
45
@cindex ESA/390 Syntax
46
@node ESA/390 Syntax
47
@section Syntax
48
The opcode/operand syntax follows the ESA/390 Principles of Operation
49
manual; assembler directives and general syntax are loosely based on the
50
prevailing AT&T/SVR4/ELF/Solaris style notation.  HLASM-style directives
51
are @emph{not} supported for the most part, with the exception of those
52
described herein.
53
 
54
A leading dot in front of directives is optional, and the case of
55
directives is ignored; thus for example, .using and USING have the same
56
effect.
57
 
58
A colon may immediately follow a label definition.  This is
59
simply for compatibility with how most assembly language programmers
60
write code.
61
 
62
@samp{#} is the line comment character.
63
 
64
@samp{;} can be used instead of a newline to separate statements.
65
 
66
Since @samp{$} has no special meaning, you may use it in symbol names.
67
 
68
Registers can be given the symbolic names r0..r15, fp0, fp2, fp4, fp6.
69
By using thesse symbolic names, @code{@value{AS}} can detect simple
70
syntax errors. The name rarg or r.arg is a synonym for r11, rtca or r.tca
71
for r12, sp, r.sp, dsa r.dsa for r13, lr or r.lr for r14, rbase or r.base
72
for r3 and rpgt or r.pgt for r4.
73
 
74
@samp{*} is the current location counter.  Unlike @samp{.} it is always
75
relative to the last USING directive.  Note that this means that
76
expressions cannot use multiplication, as any occurrence of @samp{*}
77
will be interpreted as a location counter.
78
 
79
All labels are relative to the last USING.  Thus, branches to a label
80
always imply the use of base+displacement.
81
 
82
Many of the usual forms of address constants / address literals
83
are supported.  Thus,
84
@example
85
        .using  *,r3
86
        L       r15,=A(some_routine)
87
        LM      r6,r7,=V(some_longlong_extern)
88
        A       r1,=F'12'
89
        AH      r0,=H'42'
90
        ME      r6,=E'3.1416'
91
        MD      r6,=D'3.14159265358979'
92
        O       r6,=XL4'cacad0d0'
93
        .ltorg
94
@end example
95
should all behave as expected: that is, an entry in the literal
96
pool will be created (or reused if it already exists), and the
97
instruction operands will be the displacement into the literal pool
98
using the current base register (as last declared with the @code{.using}
99
directive).
100
 
101
@node ESA/390 Floating Point
102
@section Floating Point
103
@cindex floating point, ESA/390 (@sc{ieee})
104
@cindex ESA/390 floating point (@sc{ieee})
105
The assembler generates only @sc{ieee} floating-point numbers.  The older
106
floating point formats are not supported.
107
 
108
 
109
@node ESA/390 Directives
110
@section ESA/390 Assembler Directives
111
 
112
@code{@value{AS}} for the ESA/390 supports all of the standard ELF/SVR4
113
assembler directives that are documented in the main part of this
114
documentation.  Several additional directives are supported in order
115
to implement the ESA/390 addressing model.  The most important of these
116
are @code{.using} and @code{.ltorg}
117
 
118
@cindex ESA/390-only directives
119
These are the additional directives in @code{@value{AS}} for the ESA/390:
120
 
121
@table @code
122
@item .dc
123
A small subset of the usual DC directive is supported.
124
 
125
@item .drop @var{regno}
126
Stop using @var{regno} as the base register.  The @var{regno} must
127
have been previously declared with a @code{.using} directive in the
128
same section as the current section.
129
 
130
@item .ebcdic @var{string}
131
Emit the EBCDIC equivalent of the indicated string.  The emitted string
132
will be null terminated.  Note that the directives @code{.string} etc. emit
133
ascii strings by default.
134
 
135
@item EQU
136
The standard HLASM-style EQU directive is not supported; however, the
137
standard @code{@value{AS}} directive .equ can be used to the same effect.
138
 
139
@item .ltorg
140
Dump the literal pool accumulated so far; begin a new literal pool.
141
The literal pool will be written in the current section; in order to
142
generate correct assembly, a @code{.using} must have been previously
143
specified in the same section.
144
 
145
@item .using @var{expr},@var{regno}
146
Use @var{regno} as the base register for all subsequent RX, RS, and SS form
147
instructions. The @var{expr} will be evaluated to obtain the base address;
148
usually, @var{expr} will merely be @samp{*}.
149
 
150
This assembler allows two @code{.using} directives to be simultaneously
151
outstanding, one in the @code{.text} section, and one in another section
152
(typically, the @code{.data} section).  This feature allows
153
dynamically loaded objects to be implemented in a relatively
154
straightforward way.  A @code{.using} directive must always be specified
155
in the @code{.text} section; this will specify the base register that
156
will be used for branches in the @code{.text} section.  A second
157
@code{.using} may be specified in another section; this will specify
158
the base register that is used for non-label address literals.
159
When a second @code{.using} is specified, then the subsequent
160
@code{.ltorg} must be put in the same section; otherwise an error will
161
result.
162
 
163
Thus, for example, the following code uses @code{r3} to address branch
164
targets and @code{r4} to address the literal pool, which has been written
165
to the @code{.data} section.  The is, the constants @code{=A(some_routine)},
166
@code{=H'42'} and @code{=E'3.1416'} will all appear in the @code{.data}
167
section.
168
 
169
@example
170
.data
171
        .using  LITPOOL,r4
172
.text
173
        BASR    r3,0
174
        .using  *,r3
175
        B       START
176
        .long   LITPOOL
177
START:
178
        L       r4,4(,r3)
179
        L       r15,=A(some_routine)
180
        LTR     r15,r15
181
        BNE     LABEL
182
        AH      r0,=H'42'
183
LABEL:
184
        ME      r6,=E'3.1416'
185
.data
186
LITPOOL:
187
        .ltorg
188
@end example
189
 
190
 
191
Note that this dual-@code{.using} directive semantics extends
192
and is not compatible with HLASM semantics.  Note that this assembler
193
directive does not support the full range of HLASM semantics.
194
 
195
@end table
196
 
197
@node ESA/390 Opcodes
198
@section Opcodes
199
For detailed information on the ESA/390 machine instruction set, see
200
@cite{ESA/390 Principles of Operation} (IBM Publication Number DZ9AR004).

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.