xref: /openbmc/qemu/docs/devel/decodetree.rst (revision b14df228)
1========================
2Decodetree Specification
3========================
4
5A *decodetree* is built from instruction *patterns*.  A pattern may
6represent a single architectural instruction or a group of same, depending
7on what is convenient for further processing.
8
9Each pattern has both *fixedbits* and *fixedmask*, the combination of which
10describes the condition under which the pattern is matched::
11
12  (insn & fixedmask) == fixedbits
13
14Each pattern may have *fields*, which are extracted from the insn and
15passed along to the translator.  Examples of such are registers,
16immediates, and sub-opcodes.
17
18In support of patterns, one may declare *fields*, *argument sets*, and
19*formats*, each of which may be re-used to simplify further definitions.
20
21Fields
22======
23
24Syntax::
25
26  field_def     := '%' identifier ( unnamed_field )* ( !function=identifier )?
27  unnamed_field := number ':' ( 's' ) number
28
29For *unnamed_field*, the first number is the least-significant bit position
30of the field and the second number is the length of the field.  If the 's' is
31present, the field is considered signed.  If multiple ``unnamed_fields`` are
32present, they are concatenated.  In this way one can define disjoint fields.
33
34If ``!function`` is specified, the concatenated result is passed through the
35named function, taking and returning an integral value.
36
37One may use ``!function`` with zero ``unnamed_fields``.  This case is called
38a *parameter*, and the named function is only passed the ``DisasContext``
39and returns an integral value extracted from there.
40
41A field with no ``unnamed_fields`` and no ``!function`` is in error.
42
43Field examples:
44
45+---------------------------+---------------------------------------------+
46| Input                     | Generated code                              |
47+===========================+=============================================+
48| %disp   0:s16             | sextract(i, 0, 16)                          |
49+---------------------------+---------------------------------------------+
50| %imm9   16:6 10:3         | extract(i, 16, 6) << 3 | extract(i, 10, 3)  |
51+---------------------------+---------------------------------------------+
52| %disp12 0:s1 1:1 2:10     | sextract(i, 0, 1) << 11 |                   |
53|                           |    extract(i, 1, 1) << 10 |                 |
54|                           |    extract(i, 2, 10)                        |
55+---------------------------+---------------------------------------------+
56| %shimm8 5:s8 13:1         | expand_shimm8(sextract(i, 5, 8) << 1 |      |
57|   !function=expand_shimm8 |               extract(i, 13, 1))            |
58+---------------------------+---------------------------------------------+
59
60Argument Sets
61=============
62
63Syntax::
64
65  args_def    := '&' identifier ( args_elt )+ ( !extern )?
66  args_elt    := identifier (':' identifier)?
67
68Each *args_elt* defines an argument within the argument set.
69If the form of the *args_elt* contains a colon, the first
70identifier is the argument name and the second identifier is
71the argument type.  If the colon is missing, the argument
72type will be ``int``.
73
74Each argument set will be rendered as a C structure "arg_$name"
75with each of the fields being one of the member arguments.
76
77If ``!extern`` is specified, the backing structure is assumed
78to have been already declared, typically via a second decoder.
79
80Argument sets are useful when one wants to define helper functions
81for the translator functions that can perform operations on a common
82set of arguments.  This can ensure, for instance, that the ``AND``
83pattern and the ``OR`` pattern put their operands into the same named
84structure, so that a common ``gen_logic_insn`` may be able to handle
85the operations common between the two.
86
87Argument set examples::
88
89  &reg3       ra rb rc
90  &loadstore  reg base offset
91  &longldst   reg base offset:int64_t
92
93
94Formats
95=======
96
97Syntax::
98
99  fmt_def      := '@' identifier ( fmt_elt )+
100  fmt_elt      := fixedbit_elt | field_elt | field_ref | args_ref
101  fixedbit_elt := [01.-]+
102  field_elt    := identifier ':' 's'? number
103  field_ref    := '%' identifier | identifier '=' '%' identifier
104  args_ref     := '&' identifier
105
106Defining a format is a handy way to avoid replicating groups of fields
107across many instruction patterns.
108
109A *fixedbit_elt* describes a contiguous sequence of bits that must
110be 1, 0, or don't care.  The difference between '.' and '-'
111is that '.' means that the bit will be covered with a field or a
112final 0 or 1 from the pattern, and '-' means that the bit is really
113ignored by the cpu and will not be specified.
114
115A *field_elt* describes a simple field only given a width; the position of
116the field is implied by its position with respect to other *fixedbit_elt*
117and *field_elt*.
118
119If any *fixedbit_elt* or *field_elt* appear, then all bits must be defined.
120Padding with a *fixedbit_elt* of all '.' is an easy way to accomplish that.
121
122A *field_ref* incorporates a field by reference.  This is the only way to
123add a complex field to a format.  A field may be renamed in the process
124via assignment to another identifier.  This is intended to allow the
125same argument set be used with disjoint named fields.
126
127A single *args_ref* may specify an argument set to use for the format.
128The set of fields in the format must be a subset of the arguments in
129the argument set.  If an argument set is not specified, one will be
130inferred from the set of fields.
131
132It is recommended, but not required, that all *field_ref* and *args_ref*
133appear at the end of the line, not interleaving with *fixedbit_elf* or
134*field_elt*.
135
136Format examples::
137
138  @opr    ...... ra:5 rb:5 ... 0 ....... rc:5
139  @opi    ...... ra:5 lit:8    1 ....... rc:5
140
141Patterns
142========
143
144Syntax::
145
146  pat_def      := identifier ( pat_elt )+
147  pat_elt      := fixedbit_elt | field_elt | field_ref | args_ref | fmt_ref | const_elt
148  fmt_ref      := '@' identifier
149  const_elt    := identifier '=' number
150
151The *fixedbit_elt* and *field_elt* specifiers are unchanged from formats.
152A pattern that does not specify a named format will have one inferred
153from a referenced argument set (if present) and the set of fields.
154
155A *const_elt* allows a argument to be set to a constant value.  This may
156come in handy when fields overlap between patterns and one has to
157include the values in the *fixedbit_elt* instead.
158
159The decoder will call a translator function for each pattern matched.
160
161Pattern examples::
162
163  addl_r   010000 ..... ..... .... 0000000 ..... @opr
164  addl_i   010000 ..... ..... .... 0000000 ..... @opi
165
166which will, in part, invoke::
167
168  trans_addl_r(ctx, &arg_opr, insn)
169
170and::
171
172  trans_addl_i(ctx, &arg_opi, insn)
173
174Pattern Groups
175==============
176
177Syntax::
178
179  group            := overlap_group | no_overlap_group
180  overlap_group    := '{' ( pat_def | group )+ '}'
181  no_overlap_group := '[' ( pat_def | group )+ ']'
182
183A *group* begins with a lone open-brace or open-bracket, with all
184subsequent lines indented two spaces, and ending with a lone
185close-brace or close-bracket.  Groups may be nested, increasing the
186required indentation of the lines within the nested group to two
187spaces per nesting level.
188
189Patterns within overlap groups are allowed to overlap.  Conflicts are
190resolved by selecting the patterns in order.  If all of the fixedbits
191for a pattern match, its translate function will be called.  If the
192translate function returns false, then subsequent patterns within the
193group will be matched.
194
195Patterns within no-overlap groups are not allowed to overlap, just
196the same as ungrouped patterns.  Thus no-overlap groups are intended
197to be nested inside overlap groups.
198
199The following example from PA-RISC shows specialization of the *or*
200instruction::
201
202  {
203    {
204      nop   000010 ----- ----- 0000 001001 0 00000
205      copy  000010 00000 r1:5  0000 001001 0 rt:5
206    }
207    or      000010 rt2:5 r1:5  cf:4 001001 0 rt:5
208  }
209
210When the *cf* field is zero, the instruction has no side effects,
211and may be specialized.  When the *rt* field is zero, the output
212is discarded and so the instruction has no effect.  When the *rt2*
213field is zero, the operation is ``reg[r1] | 0`` and so encodes
214the canonical register copy operation.
215
216The output from the generator might look like::
217
218  switch (insn & 0xfc000fe0) {
219  case 0x08000240:
220    /* 000010.. ........ ....0010 010..... */
221    if ((insn & 0x0000f000) == 0x00000000) {
222        /* 000010.. ........ 00000010 010..... */
223        if ((insn & 0x0000001f) == 0x00000000) {
224            /* 000010.. ........ 00000010 01000000 */
225            extract_decode_Fmt_0(&u.f_decode0, insn);
226            if (trans_nop(ctx, &u.f_decode0)) return true;
227        }
228        if ((insn & 0x03e00000) == 0x00000000) {
229            /* 00001000 000..... 00000010 010..... */
230            extract_decode_Fmt_1(&u.f_decode1, insn);
231            if (trans_copy(ctx, &u.f_decode1)) return true;
232        }
233    }
234    extract_decode_Fmt_2(&u.f_decode2, insn);
235    if (trans_or(ctx, &u.f_decode2)) return true;
236    return false;
237  }
238