bird/filter/decl.m4
Ondrej Zajicek (work) 26bc4f9904 Filter: Implement direct recursion
Direct recursion almost worked, just crashed on function signature check.
Split function parsing such that function signature is saved before
function body is processed. Recursive calls are marked so they can be
avoided during f_same() and similar code walking.

Also, include tower of hanoi solver as a test case.
2022-06-27 21:13:31 +02:00

692 lines
21 KiB
Text

m4_divert(-1)m4_dnl
#
# BIRD -- Construction of per-instruction structures
#
# (c) 2018 Maria Matejka <mq@jmq.cz>
#
# Can be freely distributed and used under the terms of the GNU GPL.
#
# THIS IS A M4 MACRO FILE GENERATING 3 FILES ALTOGETHER.
# KEEP YOUR HANDS OFF UNLESS YOU KNOW WHAT YOU'RE DOING.
# EDITING AND DEBUGGING THIS FILE MAY DAMAGE YOUR BRAIN SERIOUSLY.
#
# But you're welcome to read and edit and debug if you aren't scared.
#
# Uncomment the following line to get exhaustive debug output.
# m4_debugmode(aceflqtx)
#
# How it works:
# 1) Instruction to code conversion (uses diversions 100..199)
# 2) Code wrapping (uses diversions 1..99)
# 3) Final preparation (uses diversions 200..299)
# 4) Shipout
#
# See below for detailed description.
#
#
# 1) Instruction to code conversion
# The code provided in f-inst.c between consecutive INST() calls
# is interleaved for many different places. It is here processed
# and split into separate instances where split-by-instruction
# happens. These parts are stored in temporary diversions listed:
#
# 101 content of per-inst struct
# 102 constructor arguments
# 103 constructor body
# 104 dump line item content
# (there may be nothing in dump-line content and
# it must be handled specially in phase 2)
# 105 linearize body
# 106 comparator body
# 107 struct f_line_item content
# 108 interpreter body
# 109 iterator body
#
# Here are macros to allow you to _divert to the right directions.
m4_define(FID_STRUCT_IN, `m4_divert(101)')
m4_define(FID_NEW_ARGS, `m4_divert(102)')
m4_define(FID_NEW_BODY, `m4_divert(103)')
m4_define(FID_DUMP_BODY, `m4_divert(104)m4_define([[FID_DUMP_BODY_EXISTS]])')
m4_define(FID_LINEARIZE_BODY, `m4_divert(105)')
m4_define(FID_SAME_BODY, `m4_divert(106)')
m4_define(FID_LINE_IN, `m4_divert(107)')
m4_define(FID_INTERPRET_BODY, `m4_divert(108)')
m4_define(FID_ITERATE_BODY, `m4_divert(109)')
# Sometimes you want slightly different code versions in different
# outputs.
# Use FID_HIC(code for inst-gen.h, code for inst-gen.c, code for inst-interpret.c)
# and put it into [[ ]] quotes if it shall contain commas.
m4_define(FID_HIC, `m4_ifelse(TARGET, [[H]], [[$1]], TARGET, [[I]], [[$2]], TARGET, [[C]], [[$3]])')
# In interpreter code, this is quite common.
m4_define(FID_INTERPRET_EXEC, `FID_HIC(,[[FID_INTERPRET_BODY()]],[[m4_divert(-1)]])')
m4_define(FID_INTERPRET_NEW, `FID_HIC(,[[m4_divert(-1)]],[[FID_INTERPRET_BODY()]])')
# If the instruction is never converted to constant, the interpret
# code is not produced at all for constructor
m4_define(NEVER_CONSTANT, `m4_define([[INST_NEVER_CONSTANT]])')
m4_define(FID_IFCONST, `m4_ifdef([[INST_NEVER_CONSTANT]],[[$2]],[[$1]])')
# If the instruction has some attributes (here called members),
# these are typically carried with the instruction from constructor
# to interpreter. This yields a line of code everywhere on the path.
# FID_MEMBER is a macro to help with this task.
m4_define(FID_MEMBER, `m4_dnl
FID_LINE_IN()m4_dnl
$1 $2;
FID_STRUCT_IN()m4_dnl
$1 $2;
FID_NEW_ARGS()m4_dnl
, $1 $2
FID_NEW_BODY()m4_dnl
whati->$2 = $2;
FID_LINEARIZE_BODY()m4_dnl
item->$2 = whati->$2;
m4_ifelse($3,,,[[
FID_SAME_BODY()m4_dnl
if ($3) return 0;
]])
m4_ifelse($4,,,[[
FID_DUMP_BODY()m4_dnl
debug("%s" $4 "\n", INDENT, $5);
]])
FID_INTERPRET_EXEC()m4_dnl
const $1 $2 = whati->$2
FID_INTERPRET_BODY')
# Instruction arguments are needed only until linearization is done.
# This puts the arguments into the filter line to be executed before
# the instruction itself.
#
# To achieve this, ARG_ANY must be called before anything writes into
# the instruction line as it moves the instruction pointer forward.
m4_define(ARG_ANY, `
FID_STRUCT_IN()m4_dnl
struct f_inst * f$1;
FID_NEW_ARGS()m4_dnl
, struct f_inst * f$1
FID_NEW_BODY()m4_dnl
whati->f$1 = f$1;
for (const struct f_inst *child = f$1; child; child = child->next) {
what->size += child->size;
FID_IFCONST([[
if (child->fi_code != FI_CONSTANT)
constargs = 0;
]])
}
FID_LINEARIZE_BODY
pos = linearize(dest, whati->f$1, pos);
FID_INTERPRET_BODY()')
# Some instructions accept variable number of arguments.
m4_define(VARARG, `
FID_NEW_ARGS()m4_dnl
, struct f_inst * fvar
FID_STRUCT_IN()m4_dnl
struct f_inst * fvar;
uint varcount;
FID_LINE_IN()m4_dnl
uint varcount;
FID_NEW_BODY()m4_dnl
whati->varcount = 0;
whati->fvar = fvar;
for (const struct f_inst *child = fvar; child; child = child->next, whati->varcount++) {
what->size += child->size;
FID_IFCONST([[
if (child->fi_code != FI_CONSTANT)
constargs = 0;
]])
}
FID_IFCONST([[
const struct f_inst **items = NULL;
if (constargs && whati->varcount) {
items = alloca(whati->varcount * sizeof(struct f_inst *));
const struct f_inst *child = fvar;
for (uint i=0; child; i++)
child = (items[i] = child)->next;
}
]])
FID_LINEARIZE_BODY()m4_dnl
pos = linearize(dest, whati->fvar, pos);
item->varcount = whati->varcount;
FID_DUMP_BODY()m4_dnl
debug("%snumber of varargs %u\n", INDENT, item->varcount);
FID_SAME_BODY()m4_dnl
if (f1->varcount != f2->varcount) return 0;
FID_INTERPRET_BODY()
FID_HIC(,[[
if (fstk->vcnt < whati->varcount) runtime("Stack underflow");
fstk->vcnt -= whati->varcount;
]],)
')
# Some arguments need to check their type. After that, ARG_ANY is called.
m4_define(ARG, `ARG_ANY($1) ARG_TYPE($1,$2)')
m4_define(ARG_TYPE, `ARG_TYPE_STATIC($1,$2) ARG_TYPE_DYNAMIC($1,$2)')
m4_define(ARG_TYPE_STATIC, `
FID_NEW_BODY()m4_dnl
if (f$1->type && (f$1->type != ($2)) && !f_const_promotion(f$1, ($2)))
cf_error("Argument $1 of %s must be of type %s, got type %s",
f_instruction_name(what->fi_code), f_type_name($2), f_type_name(f$1->type));
FID_INTERPRET_BODY()')
m4_define(ARG_TYPE_DYNAMIC, `
FID_INTERPRET_EXEC()m4_dnl
if (v$1.type != ($2))
runtime("Argument $1 of %s must be of type %s, got type %s",
f_instruction_name(what->fi_code), f_type_name($2), f_type_name(v$1.type));
FID_INTERPRET_BODY()')
m4_define(ARG_SAME_TYPE, `
FID_NEW_BODY()m4_dnl
if (f$1->type && f$2->type && (f$1->type != f$2->type) &&
!f_const_promotion(f$2, f$1->type) && !f_const_promotion(f$1, f$2->type))
cf_error("Arguments $1 and $2 of %s must be of the same type", f_instruction_name(what->fi_code));
FID_INTERPRET_BODY()')
m4_define(ARG_PREFER_SAME_TYPE, `
FID_NEW_BODY()m4_dnl
if (f$1->type && f$2->type && (f$1->type != f$2->type))
(void) (f_const_promotion(f$2, f$1->type) || f_const_promotion(f$1, f$2->type));
FID_INTERPRET_BODY()')
# Executing another filter line. This replaces the recursion
# that was needed in the former implementation.
m4_define(LINEX, `FID_INTERPRET_EXEC()LINEX_($1)FID_INTERPRET_NEW()return $1 FID_INTERPRET_BODY()')
m4_define(LINEX_, `do {
fstk->estk[fstk->ecnt].pos = 0;
fstk->estk[fstk->ecnt].line = $1;
fstk->estk[fstk->ecnt].ventry = fstk->vcnt;
fstk->estk[fstk->ecnt].vbase = fstk->estk[fstk->ecnt-1].vbase;
fstk->estk[fstk->ecnt].emask = 0;
fstk->ecnt++;
} while (0)')
m4_define(LINE, `
FID_LINE_IN()m4_dnl
const struct f_line * fl$1;
FID_STRUCT_IN()m4_dnl
struct f_inst * f$1;
FID_NEW_ARGS()m4_dnl
, struct f_inst * f$1
FID_NEW_BODY()m4_dnl
whati->f$1 = f$1;
FID_DUMP_BODY()m4_dnl
f_dump_line(item->fl$1, indent + 1);
FID_LINEARIZE_BODY()m4_dnl
item->fl$1 = f_linearize(whati->f$1);
FID_SAME_BODY()m4_dnl
if (!f_same(f1->fl$1, f2->fl$1)) return 0;
FID_ITERATE_BODY()m4_dnl
if (whati->fl$1) BUFFER_PUSH(fit->lines) = whati->fl$1;
FID_INTERPRET_EXEC()m4_dnl
do { if (whati->fl$1) {
LINEX_(whati->fl$1);
} } while(0)
FID_INTERPRET_NEW()m4_dnl
return whati->f$1
FID_INTERPRET_BODY()')
# Some of the instructions have a result. These constructions
# state the result and put it to the right place.
m4_define(RESULT, `RESULT_TYPE([[$1]]) RESULT_([[$1]],[[$2]],[[$3]])')
m4_define(RESULT_, `RESULT_VAL([[ (struct f_val) { .type = $1, .val.$2 = $3 } ]])')
m4_define(RESULT_VAL, `FID_HIC(, [[do { res = $1; fstk->vcnt++; } while (0)]],
[[return fi_constant(what, $1)]])')
m4_define(RESULT_VOID, `RESULT_VAL([[ (struct f_val) { .type = T_VOID } ]])')
m4_define(ERROR,
`m4_errprint(m4___file__:m4___line__: $*
)m4_m4exit(1)')
# This macro specifies result type and makes there are no conflicting definitions
m4_define(RESULT_TYPE,
`m4_ifdef([[INST_RESULT_TYPE]],
[[m4_ifelse(INST_RESULT_TYPE,$1,,[[ERROR([[Multiple type definitions in]] INST_NAME)]])]],
[[m4_define(INST_RESULT_TYPE,$1) RESULT_TYPE_($1)]])')
m4_define(RESULT_TYPE_CHECK,
`m4_ifelse(INST_OUTVAL,0,,
[[m4_ifdef([[INST_RESULT_TYPE]],,[[ERROR([[Missing type definition in]] INST_NAME)]])]])')
m4_define(RESULT_TYPE_, `
FID_NEW_BODY()m4_dnl
what->type = $1;
FID_INTERPRET_BODY()')
# Some common filter instruction members
m4_define(SYMBOL, `FID_MEMBER(struct symbol *, sym, [[strcmp(f1->sym->name, f2->sym->name) || (f1->sym->class != f2->sym->class)]], "symbol %s", item->sym->name)')
m4_define(RTC, `FID_MEMBER(struct rtable_config *, rtc, [[strcmp(f1->rtc->name, f2->rtc->name)]], "route table %s", item->rtc->name)')
m4_define(STATIC_ATTR, `FID_MEMBER(struct f_static_attr, sa, f1->sa.sa_code != f2->sa.sa_code,,)')
m4_define(DYNAMIC_ATTR, `FID_MEMBER(struct f_dynamic_attr, da, f1->da.ea_code != f2->da.ea_code,,)')
m4_define(ACCESS_RTE, `FID_HIC(,[[do { if (!fs->rte) runtime("No route to access"); } while (0)]],NEVER_CONSTANT())')
# 2) Code wrapping
# The code produced in 1xx temporary diversions is a raw code without
# any auxiliary commands and syntactical structures around. When the
# instruction is done, INST_FLUSH is called. More precisely, it is called
# at the beginning of INST() call and at the end of file.
#
# INST_FLUSH picks all the temporary diversions, wraps their content
# into appropriate headers and structures and saves them into global
# diversions listed:
#
# 4 enum fi_code
# 5 enum fi_code to string
# 6 dump line item
# 7 dump line item callers
# 8 linearize
# 9 same (filter comparator)
# 10 iterate
# 1 union in struct f_inst
# 3 constructors + interpreter
#
# These global diversions contain blocks of code that can be directly
# put into the final file, yet it still can't be written out now as
# every instruction writes to all of these diversions.
# Code wrapping diversion names. Here we want an explicit newline
# after the C comment.
m4_define(FID_ZONE, `m4_divert($1) /* $2 for INST_NAME() */
')
m4_define(FID_INST, `FID_ZONE(1, Instruction structure for config)')
m4_define(FID_LINE, `FID_ZONE(2, Instruction structure for interpreter)')
m4_define(FID_NEW, `FID_ZONE(3, Constructor)')
m4_define(FID_ENUM, `FID_ZONE(4, Code enum)')
m4_define(FID_ENUM_STR, `FID_ZONE(5, Code enum to string)')
m4_define(FID_DUMP, `FID_ZONE(6, Dump line)')
m4_define(FID_DUMP_CALLER, `FID_ZONE(7, Dump line caller)')
m4_define(FID_LINEARIZE, `FID_ZONE(8, Linearize)')
m4_define(FID_SAME, `FID_ZONE(9, Comparison)')
m4_define(FID_ITERATE, `FID_ZONE(10, Iteration)')
# This macro does all the code wrapping. See inline comments.
m4_define(INST_FLUSH, `m4_ifdef([[INST_NAME]], [[
RESULT_TYPE_CHECK()m4_dnl Check for defined RESULT_TYPE()
FID_ENUM()m4_dnl Contents of enum fi_code { ... }
INST_NAME(),
FID_ENUM_STR()m4_dnl Contents of const char * indexed by enum fi_code
[INST_NAME()] = "INST_NAME()",
FID_INST()m4_dnl Anonymous structure inside struct f_inst
struct {
m4_undivert(101)m4_dnl
} i_[[]]INST_NAME();
FID_LINE()m4_dnl Anonymous structure inside struct f_line_item
struct {
m4_undivert(107)m4_dnl
} i_[[]]INST_NAME();
FID_NEW()m4_dnl Constructor and interpreter code together
FID_HIC(
[[m4_dnl Public declaration of constructor in H file
struct f_inst *f_new_inst_]]INST_NAME()[[(enum f_instruction_code fi_code
m4_undivert(102)m4_dnl
);]],
[[m4_dnl The one case in The Big Switch inside interpreter
case INST_NAME():
#define whati (&(what->i_]]INST_NAME()[[))
m4_ifelse(m4_eval(INST_INVAL() > 0), 1, [[if (fstk->vcnt < INST_INVAL()) runtime("Stack underflow"); fstk->vcnt -= INST_INVAL(); ]])
m4_undivert(108)m4_dnl
#undef whati
break;
]],
[[m4_dnl Constructor itself
struct f_inst *f_new_inst_]]INST_NAME()[[(enum f_instruction_code fi_code
m4_undivert(102)m4_dnl
)
{
/* Allocate the structure */
struct f_inst *what = fi_new(fi_code);
FID_IFCONST([[uint constargs = 1;]])
/* Initialize all the members */
#define whati (&(what->i_]]INST_NAME()[[))
m4_undivert(103)m4_dnl
/* If not constant, return the instruction itself */
FID_IFCONST([[if (!constargs)]])
return what;
/* Try to pre-calculate the result */
FID_IFCONST([[m4_undivert(108)]])m4_dnl
#undef whati
}
]])
FID_DUMP_CALLER()m4_dnl Case in another big switch used in instruction dumping (debug)
case INST_NAME(): f_dump_line_item_]]INST_NAME()[[(item, indent + 1); break;
FID_DUMP()m4_dnl The dumper itself
m4_ifdef([[FID_DUMP_BODY_EXISTS]],
[[static inline void f_dump_line_item_]]INST_NAME()[[(const struct f_line_item *item_, const int indent)]],
[[static inline void f_dump_line_item_]]INST_NAME()[[(const struct f_line_item *item UNUSED, const int indent UNUSED)]])
m4_undefine([[FID_DUMP_BODY_EXISTS]])
{
#define item (&(item_->i_]]INST_NAME()[[))
m4_undivert(104)m4_dnl
#undef item
}
FID_LINEARIZE()m4_dnl The linearizer
case INST_NAME(): {
#define whati (&(what->i_]]INST_NAME()[[))
#define item (&(dest->items[pos].i_]]INST_NAME()[[))
m4_undivert(105)m4_dnl
#undef whati
#undef item
dest->items[pos].fi_code = what->fi_code;
dest->items[pos].flags = what->flags;
dest->items[pos].lineno = what->lineno;
break;
}
FID_SAME()m4_dnl This code compares two f_line"s while reconfiguring
case INST_NAME():
#define f1 (&(f1_->i_]]INST_NAME()[[))
#define f2 (&(f2_->i_]]INST_NAME()[[))
m4_undivert(106)m4_dnl
#undef f1
#undef f2
break;
FID_ITERATE()m4_dnl The iterator
case INST_NAME():
#define whati (&(what->i_]]INST_NAME()[[))
m4_undivert(109)m4_dnl
#undef whati
break;
m4_divert(-1)FID_FLUSH(101,200)m4_dnl And finally this flushes all the unused diversions
]])')
m4_define(INST, `m4_dnl This macro is called on beginning of each instruction.
INST_FLUSH()m4_dnl First, old data is flushed
m4_define([[INST_NAME]], [[$1]])m4_dnl Then we store instruction name,
m4_define([[INST_INVAL]], [[$2]])m4_dnl instruction input value count,
m4_define([[INST_OUTVAL]], [[$3]])m4_dnl instruction output value count,
m4_undefine([[INST_NEVER_CONSTANT]])m4_dnl reset NEVER_CONSTANT trigger,
m4_undefine([[INST_RESULT_TYPE]])m4_dnl and reset RESULT_TYPE value.
FID_INTERPRET_BODY()m4_dnl By default, every code is interpreter code.
')
# 3) Final preparation
#
# Now we prepare all the code around the global diversions.
# It must be here, not in m4wrap, as we want M4 to mark the code
# by #line directives correctly, not to claim that every single line
# is at the beginning of the m4wrap directive.
#
# This part is split by the final file.
# H for inst-gen.h
# I for inst-interpret.c
# C for inst-gen.c
#
# So we in cycle:
# A. open a diversion
# B. send there some code
# C. close that diversion
# D. flush a global diversion
# E. open another diversion and goto B.
#
# Final diversions
# 200+ completed text before it is flushed to output
# This is a list of output diversions
m4_define(FID_WR_PUT_LIST)
# This macro does the steps C to E, see before.
m4_define(FID_WR_PUT_ALSO, `m4_define([[FID_WR_PUT_LIST]],FID_WR_PUT_LIST()[[FID_WR_DPUT(]]FID_WR_DIDX[[)FID_WR_DPUT(]]$1[[)]])m4_define([[FID_WR_DIDX]],m4_eval(FID_WR_DIDX+1))m4_divert(FID_WR_DIDX)')
# These macros do the splitting between H/I/C
m4_define(FID_WR_DIRECT, `m4_ifelse(TARGET,[[$1]],[[FID_WR_INIT()]],[[FID_WR_STOP()]])')
m4_define(FID_WR_INIT, `m4_define([[FID_WR_DIDX]],200)m4_define([[FID_WR_PUT]],[[FID_WR_PUT_ALSO($]][[@)]])m4_divert(200)')
m4_define(FID_WR_STOP, `m4_define([[FID_WR_PUT]])m4_divert(-1)')
# Here is the direct code to be put into the output files
# together with the undiversions, being hidden under FID_WR_PUT()
m4_changequote([[,]])
FID_WR_DIRECT(I)
FID_WR_PUT(3)
FID_WR_DIRECT(C)
#if defined(__GNUC__) && __GNUC__ >= 6
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wmisleading-indentation"
#endif
#include "nest/bird.h"
#include "filter/filter.h"
#include "filter/f-inst.h"
/* Instruction codes to string */
static const char * const f_instruction_name_str[] = {
FID_WR_PUT(5)
};
const char *
f_instruction_name_(enum f_instruction_code fi)
{
if (fi < (sizeof(f_instruction_name_str) / sizeof(f_instruction_name_str[0])))
return f_instruction_name_str[fi];
else
bug("Got unknown instruction code: %d", fi);
}
static inline struct f_inst *
fi_new(enum f_instruction_code fi_code)
{
struct f_inst *what = cfg_allocz(sizeof(struct f_inst));
what->lineno = ifs->lino;
what->size = 1;
what->fi_code = fi_code;
return what;
}
static inline struct f_inst *
fi_constant(struct f_inst *what, struct f_val val)
{
what->fi_code = FI_CONSTANT;
what->i_FI_CONSTANT.val = val;
return what;
}
static int
f_const_promotion(struct f_inst *arg, enum f_type want)
{
if (arg->fi_code != FI_CONSTANT)
return 0;
struct f_val *c = &arg->i_FI_CONSTANT.val;
if ((c->type == T_IP) && ipa_is_ip4(c->val.ip) && (want == T_QUAD)) {
*c = (struct f_val) {
.type = T_QUAD,
.val.i = ipa_to_u32(c->val.ip),
};
return 1;
}
else if ((c->type == T_SET) && (!c->val.t) && (want == T_PREFIX_SET)) {
*c = f_const_empty_prefix_set;
return 1;
}
return 0;
}
#define v1 whati->f1->i_FI_CONSTANT.val
#define v2 whati->f2->i_FI_CONSTANT.val
#define v3 whati->f3->i_FI_CONSTANT.val
#define vv(i) items[i]->i_FI_CONSTANT.val
#define runtime(fmt, ...) cf_error("filter preevaluation, line %d: " fmt, ifs->lino, ##__VA_ARGS__)
#define fpool cfg_mem
#define falloc(size) cfg_alloc(size)
/* Instruction constructors */
FID_WR_PUT(3)
#undef v1
#undef v2
#undef v3
#undef vv
/* Line dumpers */
#define INDENT (((const char *) f_dump_line_indent_str) + sizeof(f_dump_line_indent_str) - (indent) - 1)
static const char f_dump_line_indent_str[] = " ";
FID_WR_PUT(6)
void f_dump_line(const struct f_line *dest, uint indent)
{
if (!dest) {
debug("%sNo filter line (NULL)\n", INDENT);
return;
}
debug("%sFilter line %p (len=%u)\n", INDENT, dest, dest->len);
for (uint i=0; i<dest->len; i++) {
const struct f_line_item *item = &dest->items[i];
debug("%sInstruction %s at line %u\n", INDENT, f_instruction_name_(item->fi_code), item->lineno);
switch (item->fi_code) {
FID_WR_PUT(7)
default: bug("Unknown instruction %x in f_dump_line", item->fi_code);
}
}
debug("%sFilter line %p dump done\n", INDENT, dest);
}
/* Linearize */
static uint
linearize(struct f_line *dest, const struct f_inst *what, uint pos)
{
for ( ; what; what = what->next) {
switch (what->fi_code) {
FID_WR_PUT(8)
}
pos++;
}
return pos;
}
struct f_line *
f_linearize_concat(const struct f_inst * const inst[], uint count)
{
uint len = 0;
for (uint i=0; i<count; i++)
for (const struct f_inst *what = inst[i]; what; what = what->next)
len += what->size;
struct f_line *out = cfg_allocz(sizeof(struct f_line) + sizeof(struct f_line_item)*len);
for (uint i=0; i<count; i++)
out->len = linearize(out, inst[i], out->len);
#ifdef LOCAL_DEBUG
f_dump_line(out, 0);
#endif
return out;
}
/* Filter line comparison */
int
f_same(const struct f_line *fl1, const struct f_line *fl2)
{
if ((!fl1) && (!fl2))
return 1;
if ((!fl1) || (!fl2))
return 0;
if (fl1->len != fl2->len)
return 0;
for (uint i=0; i<fl1->len; i++) {
#define f1_ (&(fl1->items[i]))
#define f2_ (&(fl2->items[i]))
if (f1_->fi_code != f2_->fi_code)
return 0;
if (f1_->flags != f2_->flags)
return 0;
switch(f1_->fi_code) {
FID_WR_PUT(9)
}
}
#undef f1_
#undef f2_
return 1;
}
/* Part of FI_SWITCH filter iterator */
static void
f_add_tree_lines(const struct f_tree *t, void *fit_)
{
struct filter_iterator * fit = fit_;
if (t->data)
BUFFER_PUSH(fit->lines) = t->data;
}
/* Filter line iterator */
void
f_add_lines(const struct f_line_item *what, struct filter_iterator *fit)
{
switch(what->fi_code) {
FID_WR_PUT(10)
}
}
#if defined(__GNUC__) && __GNUC__ >= 6
#pragma GCC diagnostic pop
#endif
FID_WR_DIRECT(H)
/* Filter instruction codes */
enum f_instruction_code {
FID_WR_PUT(4)m4_dnl
} PACKED;
/* Filter instruction structure for config */
struct f_inst {
struct f_inst *next; /* Next instruction */
enum f_instruction_code fi_code; /* Instruction code */
enum f_instruction_flags flags; /* Flags, instruction-specific */
enum f_type type; /* Type of returned value, if known */
int size; /* How many instructions are underneath */
int lineno; /* Line number */
union {
FID_WR_PUT(1)m4_dnl
};
};
/* Filter line item */
struct f_line_item {
enum f_instruction_code fi_code; /* What to do */
enum f_instruction_flags flags; /* Flags, instruction-specific */
uint lineno; /* Where */
union {
FID_WR_PUT(2)m4_dnl
};
};
/* Instruction constructors */
FID_WR_PUT(3)
m4_divert(-1)
# 4) Shipout
#
# Everything is prepared in FID_WR_PUT_LIST now. Let's go!
m4_changequote(`,')
# Flusher auxiliary macro
m4_define(FID_FLUSH, `m4_ifelse($1,$2,,[[m4_undivert($1)FID_FLUSH(m4_eval($1+1),$2)]])')
# Defining the macro used in FID_WR_PUT_LIST
m4_define(FID_WR_DPUT, `m4_undivert($1)')
# After the code is read and parsed, we:
m4_m4wrap(`INST_FLUSH()m4_divert(0)FID_WR_PUT_LIST()m4_divert(-1)FID_FLUSH(1,200)')
m4_changequote([[,]])
# And now M4 is going to parse f-inst.c, fill the diversions
# and after the file is done, the content of m4_m4wrap (see before)
# is executed.