Bochs/bochs/debug/lexer.l

%{
#include <stdlib.h>
#include <string.h>
#include "debug.h"
#include "parser.h"

int bx_yyinput(char *buf, int max_size);
#undef YY_INPUT
#define YY_INPUT(buf, ret, max_size) (ret = bx_yyinput(buf, max_size))

static char    *lex_input_ptr = NULL;
static unsigned lex_input_size = 0;
%}


%%
[ \t]+          ; // eat up whitespace
set             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SET); }
dis             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIS); }
on              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ON); }
off             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_OFF); }
crc             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CRC); }
c               { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CONTINUE); }
stepi           |
step            |
si              |
s               { bxlval.sval = strdup(bxtext); return(BX_TOKEN_STEPN); }
vb              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_VBREAKPOINT); }
vbreak          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_VBREAKPOINT); }
lb              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LBREAKPOINT); }
lbreak          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LBREAKPOINT); }
pb              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }
pbreak          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }
info            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_INFO); }
break           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }
b               { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }
program         { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PROGRAM); }
cr		|
creg		|
cregs		{ bxlval.sval = strdup(bxtext); return(BX_TOKEN_CONTROL_REGS); }
r		|
reg		|
registers       { bxlval.sval = strdup(bxtext); return(BX_TOKEN_REGISTERS); }
fpu             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_FPU); }
all             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ALL); }
idt		{ bxlval.sval = strdup(bxtext); return(BX_TOKEN_IDT); }
gdt		{ bxlval.sval = strdup(bxtext); return(BX_TOKEN_GDT); }
ldt		{ bxlval.sval = strdup(bxtext); return(BX_TOKEN_LDT); }
tss		{ bxlval.sval = strdup(bxtext); return(BX_TOKEN_TSS); }
dirty           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIRTY); }
linux           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LINUX); }
dump_cpu        { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DUMP_CPU); }
delete          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DEL_BREAKPOINT); }
del             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DEL_BREAKPOINT); }
d               { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DEL_BREAKPOINT); }
quit            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_QUIT); }
q               { bxlval.sval = strdup(bxtext); return(BX_TOKEN_QUIT); }
x               { bxlval.sval = strdup(bxtext); return(BX_TOKEN_EXAMINE); }
xp              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_EXAMINE); }
setpmem         { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SETPMEM); }
query           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_QUERY); }
pending         { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PENDING); }
take            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TAKE); }
dma             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DMA); }
irq             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_IRQ); }
set_cpu         { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SET_CPU); }
disas           |
disassemble     { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DISASSEMBLE); }
maths           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_MATHS); }
add             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ADD); }
sub             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SUB); }
mul             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_MUL); }
div             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIV); }
instrument      { bxlval.sval = strdup(bxtext); return(BX_TOKEN_INSTRUMENT); }
start           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_START); }
stop            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_STOP); }
reset           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_RESET); }
print           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PRINT); }
loader          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LOADER); }
doit            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DOIT); }
trace-on        { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TRACEON); }
trace-off       { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TRACEOFF); }
ptime           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PTIME); }
sb              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TIMEBP); }
sba             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TIMEBP_ABSOLUTE); }
record          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_RECORD); }
playback        { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PLAYBACK); }
modebp          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_MODEBP); }
print-stack     { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PRINT_STACK); }
watch           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_WATCH); }
unwatch         { bxlval.sval = strdup(bxtext); return(BX_TOKEN_UNWATCH); }
read            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_READ); }
write           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_WRITE); }
continue        { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CONTINUE); }
show            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SHOW); }
load-symbols    { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYMBOL); }
global          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_GLOBAL); }
where           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_WHERE); }
print-string    { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PRINT_STRING); }
diff-memory     { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIFF_MEMORY); }
sync-memory     { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYNC_MEMORY); }
sync-cpu        { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYNC_CPU); }
fast-forward    { bxlval.sval = strdup(bxtext); return(BX_TOKEN_FAST_FORWARD); }
phy2log         { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PHY_2_LOG); }
addr-info       { bxlval.sval = strdup(bxtext); return(BX_TOKEN_INFO_ADDRESS); }
ne2k            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_NE2000); }
ne2000          { bxlval.sval = strdup(bxtext); return(BX_TOKEN_NE2000); }
page            { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PAGE); }
cs              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CS); }
es              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ES); }
ss              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SS); }
ds              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DS); }
fs              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_FS); }
gs              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_GS); }
force-check     { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ALWAYS_CHECK); }
v2l             { bxlval.sval = strdup(bxtext); return(BX_TOKEN_V2L); }
\"[^\"\n]*\"    { bxlval.sval = strdup(bxtext); return(BX_TOKEN_STRING); }
\/[0-9]*[xduotcsibhwg][xduotcsibhwg] { bxlval.sval = strdup(bxtext); return(BX_TOKEN_XFORMAT); }
\/[0-9]*[xduotcsibhwg]              { bxlval.sval = strdup(bxtext); return(BX_TOKEN_XFORMAT); }
\/[0-9]+                           { bxlval.sval = strdup(bxtext); return(BX_TOKEN_XFORMAT); }
0x[0-9a-fA-F]+  { bxlval.uval = strtoul(bxtext+2, NULL, 16); return(BX_TOKEN_NUMERIC); }
0[0-7]+         { bxlval.uval = strtoul(bxtext+1, NULL, 8); return(BX_TOKEN_NUMERIC); }
[0-9]+L         { bxlval.ulval = strtoull(bxtext, NULL, 10); return(BX_TOKEN_LONG_NUMERIC); }
[0-9]+          { bxlval.uval = strtoul(bxtext, NULL, 10); return(BX_TOKEN_NUMERIC); }
$[a-zA-Z_][a-zA-Z0-9_]* { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYMBOLNAME); }
\n              { return('\n'); }
[#][^\n]*    ; // eat up comments '//'
.               { return(bxtext[0]); }
%%

// [A-Za-z_][A-Za-z0-9_]*   { bxlval.sval = strdup(bxtext); return(BX_TOKEN_GENERIC); }

  int
bx_yyinput(char *buf, int max_size)
{
  int len;

  if (lex_input_size == 0) {
    fprintf(stderr, "lex: no characters in string input buffer.\n");
    exit(1);
    }

  len = strlen(lex_input_ptr);
  if (len > max_size)
    max_size = len;

  memcpy(buf, lex_input_ptr, max_size);
  lex_input_size -= max_size;

  return(max_size);
}


  void
bx_add_lex_input(char *buf)
{
  lex_input_ptr  = buf;
  lex_input_size = strlen(buf);

  // Since we're parsing from strings, flush out
  // all current buffer state, so the next read
  // requests from yyinput

  bx_flush_buffer( YY_CURRENT_BUFFER );
}
- entered original Bochs snapshot bochs-2000_0325a.tar.gz from ftp.bochs.com 2001-04-10 05:04:59 +04:00			`%{`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include "debug.h"`
			`#include "parser.h"`

			`int bx_yyinput(char *buf, int max_size);`
			`#undef YY_INPUT`
			`#define YY_INPUT(buf, ret, max_size) (ret = bx_yyinput(buf, max_size))`

			`static char *lex_input_ptr = NULL;`
			`static unsigned lex_input_size = 0;`
			`%}`


			`%%`
			`[ \t]+ ; // eat up whitespace`
			`set { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SET); }`
			`dis { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIS); }`
			`on { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ON); }`
			`off { bxlval.sval = strdup(bxtext); return(BX_TOKEN_OFF); }`
			`crc { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CRC); }`
			`c { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CONTINUE); }`
			`stepi \|`
			`step \|`
			`si \|`
			`s { bxlval.sval = strdup(bxtext); return(BX_TOKEN_STEPN); }`
			`vb { bxlval.sval = strdup(bxtext); return(BX_TOKEN_VBREAKPOINT); }`
			`vbreak { bxlval.sval = strdup(bxtext); return(BX_TOKEN_VBREAKPOINT); }`
			`lb { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LBREAKPOINT); }`
			`lbreak { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LBREAKPOINT); }`
			`pb { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }`
			`pbreak { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }`
			`info { bxlval.sval = strdup(bxtext); return(BX_TOKEN_INFO); }`
			`break { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }`
			`b { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PBREAKPOINT); }`
			`program { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PROGRAM); }`
- merged BRANCH-smp-bochs into main branch. For details see comments in BRANCH-smp-bochs revisions. - The general task was to make multiple CPU's which communicate through their APICs. So instead of BX_CPU and BX_MEM, we now have BX_CPU(x) and BX_MEM(y). For an SMP simulation you have several processors in a shared memory space, so there might be processors BX_CPU(0..3) but only one memory space BX_MEM(0). For cosimulation, you could have BX_CPU(0) with BX_MEM(0), then BX_CPU(1) with BX_MEM(1). WARNING: Cosimulation is almost certainly broken by the SMP changes. - to simulate multiple CPUs, you have to give each CPU time to execute in turn. This is currently implemented using debugger guards. The cpu loop steps one CPU for a few instructions, then steps the next CPU for a few instructions, etc. - there is some limited support in the debugger for two CPUs, for example printing information from each CPU when single stepping. 2001-05-23 12:16:07 +04:00			`cr \|`
			`creg \|`
			`cregs { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CONTROL_REGS); }`
			`r \|`
			`reg \|`
- entered original Bochs snapshot bochs-2000_0325a.tar.gz from ftp.bochs.com 2001-04-10 05:04:59 +04:00			`registers { bxlval.sval = strdup(bxtext); return(BX_TOKEN_REGISTERS); }`
- added debugger command "info fpu" which prints all FPU registers in an output format similar to gdb (when you do info all-registers). Also, if you do "info all" you get the CPU registers and the FPU registers. - added bx_cpu_c method called fpu_print_regs, which is implemented in wmFPUemu_glue.cc 2001-09-15 10:55:14 +04:00			`fpu { bxlval.sval = strdup(bxtext); return(BX_TOKEN_FPU); }`
			`all { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ALL); }`
- merged BRANCH-smp-bochs into main branch. For details see comments in BRANCH-smp-bochs revisions. - The general task was to make multiple CPU's which communicate through their APICs. So instead of BX_CPU and BX_MEM, we now have BX_CPU(x) and BX_MEM(y). For an SMP simulation you have several processors in a shared memory space, so there might be processors BX_CPU(0..3) but only one memory space BX_MEM(0). For cosimulation, you could have BX_CPU(0) with BX_MEM(0), then BX_CPU(1) with BX_MEM(1). WARNING: Cosimulation is almost certainly broken by the SMP changes. - to simulate multiple CPUs, you have to give each CPU time to execute in turn. This is currently implemented using debugger guards. The cpu loop steps one CPU for a few instructions, then steps the next CPU for a few instructions, etc. - there is some limited support in the debugger for two CPUs, for example printing information from each CPU when single stepping. 2001-05-23 12:16:07 +04:00			`idt { bxlval.sval = strdup(bxtext); return(BX_TOKEN_IDT); }`
			`gdt { bxlval.sval = strdup(bxtext); return(BX_TOKEN_GDT); }`
			`ldt { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LDT); }`
			`tss { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TSS); }`
- entered original Bochs snapshot bochs-2000_0325a.tar.gz from ftp.bochs.com 2001-04-10 05:04:59 +04:00			`dirty { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIRTY); }`
- merged BRANCH-smp-bochs into main branch. For details see comments in BRANCH-smp-bochs revisions. - The general task was to make multiple CPU's which communicate through their APICs. So instead of BX_CPU and BX_MEM, we now have BX_CPU(x) and BX_MEM(y). For an SMP simulation you have several processors in a shared memory space, so there might be processors BX_CPU(0..3) but only one memory space BX_MEM(0). For cosimulation, you could have BX_CPU(0) with BX_MEM(0), then BX_CPU(1) with BX_MEM(1). WARNING: Cosimulation is almost certainly broken by the SMP changes. - to simulate multiple CPUs, you have to give each CPU time to execute in turn. This is currently implemented using debugger guards. The cpu loop steps one CPU for a few instructions, then steps the next CPU for a few instructions, etc. - there is some limited support in the debugger for two CPUs, for example printing information from each CPU when single stepping. 2001-05-23 12:16:07 +04:00			`linux { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LINUX); }`
- entered original Bochs snapshot bochs-2000_0325a.tar.gz from ftp.bochs.com 2001-04-10 05:04:59 +04:00			`dump_cpu { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DUMP_CPU); }`
			`delete { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DEL_BREAKPOINT); }`
			`del { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DEL_BREAKPOINT); }`
			`d { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DEL_BREAKPOINT); }`
			`quit { bxlval.sval = strdup(bxtext); return(BX_TOKEN_QUIT); }`
			`q { bxlval.sval = strdup(bxtext); return(BX_TOKEN_QUIT); }`
			`x { bxlval.sval = strdup(bxtext); return(BX_TOKEN_EXAMINE); }`
			`xp { bxlval.sval = strdup(bxtext); return(BX_TOKEN_EXAMINE); }`
			`setpmem { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SETPMEM); }`
			`query { bxlval.sval = strdup(bxtext); return(BX_TOKEN_QUERY); }`
			`pending { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PENDING); }`
			`take { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TAKE); }`
			`dma { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DMA); }`
			`irq { bxlval.sval = strdup(bxtext); return(BX_TOKEN_IRQ); }`
			`set_cpu { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SET_CPU); }`
			`disas \|`
			`disassemble { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DISASSEMBLE); }`
			`maths { bxlval.sval = strdup(bxtext); return(BX_TOKEN_MATHS); }`
			`add { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ADD); }`
			`sub { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SUB); }`
			`mul { bxlval.sval = strdup(bxtext); return(BX_TOKEN_MUL); }`
			`div { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIV); }`
			`instrument { bxlval.sval = strdup(bxtext); return(BX_TOKEN_INSTRUMENT); }`
			`start { bxlval.sval = strdup(bxtext); return(BX_TOKEN_START); }`
			`stop { bxlval.sval = strdup(bxtext); return(BX_TOKEN_STOP); }`
			`reset { bxlval.sval = strdup(bxtext); return(BX_TOKEN_RESET); }`
			`print { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PRINT); }`
			`loader { bxlval.sval = strdup(bxtext); return(BX_TOKEN_LOADER); }`
			`doit { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DOIT); }`
			`trace-on { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TRACEON); }`
			`trace-off { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TRACEOFF); }`
			`ptime { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PTIME); }`
			`sb { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TIMEBP); }`
			`sba { bxlval.sval = strdup(bxtext); return(BX_TOKEN_TIMEBP_ABSOLUTE); }`
			`record { bxlval.sval = strdup(bxtext); return(BX_TOKEN_RECORD); }`
			`playback { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PLAYBACK); }`
			`modebp { bxlval.sval = strdup(bxtext); return(BX_TOKEN_MODEBP); }`
			`print-stack { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PRINT_STACK); }`
			`watch { bxlval.sval = strdup(bxtext); return(BX_TOKEN_WATCH); }`
			`unwatch { bxlval.sval = strdup(bxtext); return(BX_TOKEN_UNWATCH); }`
			`read { bxlval.sval = strdup(bxtext); return(BX_TOKEN_READ); }`
			`write { bxlval.sval = strdup(bxtext); return(BX_TOKEN_WRITE); }`
			`continue { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CONTINUE); }`
			`show { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SHOW); }`
			`load-symbols { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYMBOL); }`
			`global { bxlval.sval = strdup(bxtext); return(BX_TOKEN_GLOBAL); }`
			`where { bxlval.sval = strdup(bxtext); return(BX_TOKEN_WHERE); }`
			`print-string { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PRINT_STRING); }`
			`diff-memory { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DIFF_MEMORY); }`
			`sync-memory { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYNC_MEMORY); }`
			`sync-cpu { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYNC_CPU); }`
			`fast-forward { bxlval.sval = strdup(bxtext); return(BX_TOKEN_FAST_FORWARD); }`
			`phy2log { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PHY_2_LOG); }`
			`addr-info { bxlval.sval = strdup(bxtext); return(BX_TOKEN_INFO_ADDRESS); }`
- add "info ne2k" command to the debugger, which prints all the registers of the NE2000 model. 2001-09-29 23:16:34 +04:00			`ne2k { bxlval.sval = strdup(bxtext); return(BX_TOKEN_NE2000); }`
			`ne2000 { bxlval.sval = strdup(bxtext); return(BX_TOKEN_NE2000); }`
			`page { bxlval.sval = strdup(bxtext); return(BX_TOKEN_PAGE); }`
- entered original Bochs snapshot bochs-2000_0325a.tar.gz from ftp.bochs.com 2001-04-10 05:04:59 +04:00			`cs { bxlval.sval = strdup(bxtext); return(BX_TOKEN_CS); }`
			`es { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ES); }`
			`ss { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SS); }`
			`ds { bxlval.sval = strdup(bxtext); return(BX_TOKEN_DS); }`
			`fs { bxlval.sval = strdup(bxtext); return(BX_TOKEN_FS); }`
			`gs { bxlval.sval = strdup(bxtext); return(BX_TOKEN_GS); }`
			`force-check { bxlval.sval = strdup(bxtext); return(BX_TOKEN_ALWAYS_CHECK); }`
			`v2l { bxlval.sval = strdup(bxtext); return(BX_TOKEN_V2L); }`
			`\"[^\"\n]*\" { bxlval.sval = strdup(bxtext); return(BX_TOKEN_STRING); }`
			`\/[0-9]*[xduotcsibhwg][xduotcsibhwg] { bxlval.sval = strdup(bxtext); return(BX_TOKEN_XFORMAT); }`
			`\/[0-9]*[xduotcsibhwg] { bxlval.sval = strdup(bxtext); return(BX_TOKEN_XFORMAT); }`
			`\/[0-9]+ { bxlval.sval = strdup(bxtext); return(BX_TOKEN_XFORMAT); }`
			`0x[0-9a-fA-F]+ { bxlval.uval = strtoul(bxtext+2, NULL, 16); return(BX_TOKEN_NUMERIC); }`
			`0[0-7]+ { bxlval.uval = strtoul(bxtext+1, NULL, 8); return(BX_TOKEN_NUMERIC); }`
- change strtoull back to normal name 2001-04-10 05:57:02 +04:00			`[0-9]+L { bxlval.ulval = strtoull(bxtext, NULL, 10); return(BX_TOKEN_LONG_NUMERIC); }`
- entered original Bochs snapshot bochs-2000_0325a.tar.gz from ftp.bochs.com 2001-04-10 05:04:59 +04:00			`[0-9]+ { bxlval.uval = strtoul(bxtext, NULL, 10); return(BX_TOKEN_NUMERIC); }`
			`$[a-zA-Z_][a-zA-Z0-9_]* { bxlval.sval = strdup(bxtext); return(BX_TOKEN_SYMBOLNAME); }`
			`\n { return('\n'); }`
			`[#][^\n]* ; // eat up comments '//'`
			`. { return(bxtext[0]); }`
			`%%`

			`// [A-Za-z_][A-Za-z0-9_]* { bxlval.sval = strdup(bxtext); return(BX_TOKEN_GENERIC); }`

			`int`
			`bx_yyinput(char *buf, int max_size)`
			`{`
			`int len;`

			`if (lex_input_size == 0) {`
			`fprintf(stderr, "lex: no characters in string input buffer.\n");`
			`exit(1);`
			`}`

			`len = strlen(lex_input_ptr);`
			`if (len > max_size)`
			`max_size = len;`

			`memcpy(buf, lex_input_ptr, max_size);`
			`lex_input_size -= max_size;`

			`return(max_size);`
			`}`


			`void`
			`bx_add_lex_input(char *buf)`
			`{`
			`lex_input_ptr = buf;`
			`lex_input_size = strlen(buf);`

			`// Since we're parsing from strings, flush out`
			`// all current buffer state, so the next read`
			`// requests from yyinput`

			`bx_flush_buffer( YY_CURRENT_BUFFER );`
			`}`