old-cross-binutils/gdb/memattr.c
J.T. Conklin 29e5738069 * exec.c (xfer_memory): Add attrib argument.
* infptrace.c (child_xfer_memory): Likewise.
* monitor.c (monitor_xfer_memory): Likewise.
* remote-adapt.c (adapt_xfer_inferior_memory): Likewise.
* remote-array.c (array_xfer_memory): Likewise.
* remote-bug.c (bug_xfer_memory): Likewise.
* remote-e7000.c (e7000_xfer_inferior_memory): Likewise.
* remote-eb.c (eb_xfer_inferior_memory): Likewise.
* remote-es.c (es1800_xfer_inferior_memory): Likewise.
* remote-mips.c (mips_xfer_memory): Likewise.
* remote-mm.c (mm_xfer_inferior_memory): Likewise.
* remote-nindy.c (nindy_xfer_inferior_memory): Likewise.
* remote-os9k.c (rombug_xfer_inferior_memory): Likewise.
* remote-rdi.c (arm_rdi_xfer_memory): Likewise.
* remote-rdp.c (remote_rdp_xfer_inferior_memory): Likewise.
* remote-sds.c (sds_xfer_memory): Likewise.
* remote-sim.c (gdbsim_xfer_inferior_memory): Likewise.
* remote-st.c (st2000_xfer_inferior_memory): Likewise.
* remote-udi.c (udi_xfer_inferior_memory): Likewise.
* remote-vx.c (vx_xfer_memory): Likewise.
* remote.c (remote_xfer_memory): Likewise.
* target.c (debug_to_xfer_memory, do_xfer_memory): Likewise.
* target.h (child_xfer_memory, do_xfer_memory, xfer_memory): Likewise.

* target.h (#include "memattr.h"): Added.
(target_ops.to_xfer_memory): Add attrib argument.

* wince.c (_initialize_inftarg): Removed call to set_dcache_state.
* dcache.h (set_dcache_state): Removed declaration.
* dcache.c (set_dcache_state): Removed definition

* dcache.c: Update module comment, as dcache is now enabled and
disabled with memory region attributes instead of by the global
variable "remotecache".  Add comment describing the interaction
between dcache and memory region attributes.
(dcache_xfer_memory): Add comment describing benefits of moving
cache writeback to a higher level.
(dcache_struct): Removed cache_has_stuff field.  This was used to
record whether the cache had been accessed in order to invalidate
it when it was disabled.  However, this is not needed because the
cache is write through and the code that enables, disables, and
deletes memory regions invalidate the cache.  Add comment which
suggests that we could be more selective and only invalidate those
cache lines containing data from those memory regions.
(dcache_invalidate): Updated.
(dcache_xfer_memory): Updated.

(dcache_alloc): Don't abort() if dcache_enabled_p is clear.
(dcache_xfer_memory): Removed code that called do_xfer_memory() to
perform a uncached transfer if dcache_enabled_p was clear.  This
function is now only called if caching is enabled for the memory
region.
(dcache_info): Always print cache info.

* target.c (do_xfer_memory): Add attrib argument.
(target_xfer_memory, target_xfer_memory_partial): Break transfer
into chunks defined by memory regions, pass region attributes to
do_xfer_memory().
* dcache.c (dcache_read_line, dcache_write_line): Likewise.

* Makefile.in (SFILES): Add memattr.c.
(COMMON_OBS): Add memattr.o.
(dcache.o): Add target.h to dependencies.
* memattr.c: New file.
* memattr.h: Likewise.
2001-01-23 22:48:56 +00:00

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/* memattr.c */
#include "defs.h"
#include "command.h"
#include "gdbcmd.h"
#include "memattr.h"
#include "target.h"
#include "value.h"
#include "language.h"
#include "gdb_string.h"
/* FIXME: While this conflicts with the enum defined in breakpoint.h,
I used them to be consistant with how breakpoints, tracepoints, and
displays are implemented. It doesn't lose now because breakpoint.h
is not included. */
enum enable
{
disabled,
enabled
};
const struct mem_attrib default_mem_attrib =
{
MEM_RW, /* mode */
MEM_WIDTH_UNSPECIFIED,
false, /* hwbreak */
false, /* cache */
false /* verify */
};
static struct mem_region *mem_region_chain = NULL;
static mem_number = 0;
static struct mem_region *
create_mem_region (CORE_ADDR lo, CORE_ADDR hi,
const struct mem_attrib *attrib)
{
struct mem_region *n, *p, *new;
if (lo > hi)
{
printf_unfiltered ("invalid memory region\n");
return NULL;
}
n = mem_region_chain;
while (n)
{
/* overlapping node */
if ((lo >= n->lo && lo <= n->hi) ||
(hi >= n->lo && hi <= n->hi))
{
printf_unfiltered ("overlapping memory region\n");
return NULL;
}
}
new = xmalloc (sizeof (struct mem_region));
new->lo = lo;
new->hi = hi;
new->number = ++mem_number;
new->status = enabled;
new->attrib = *attrib;
/* link in new node */
new->next = mem_region_chain;
mem_region_chain = new;
return new;
}
static void
delete_mem_region (struct mem_region *m)
{
free (m);
}
/*
* Look up the memory region cooresponding to ADDR.
*/
struct mem_region *
lookup_mem_region (CORE_ADDR addr)
{
static struct mem_region region;
struct mem_region *m;
CORE_ADDR lo;
CORE_ADDR hi;
/* First we initialize LO and HI so that they describe the entire
memory space. As we process the memory region chain, they are
redefined to describe the minimal region containing ADDR. LO
and HI are used in the case where no memory region is defined
that contains ADDR. If a memory region is disabled, it is
treated as if it does not exist. */
lo = (CORE_ADDR) 0;
hi = (CORE_ADDR) ~ 0;
for (m = mem_region_chain; m; m = m->next)
{
if (m->status == enabled)
{
if (addr >= m->lo && addr < m->hi)
return m;
if (addr >= m->hi && lo < m->hi)
lo = m->hi;
if (addr <= m->lo && hi > m->lo)
hi = m->lo;
}
}
/* Because no region was found, we must cons up one based on what
was learned above. */
region.lo = lo;
region.hi = hi;
region.attrib = default_mem_attrib;
return &region;
}
static void
mem_command (char *args, int from_tty)
{
CORE_ADDR lo, hi;
char *tok;
struct mem_attrib attrib;
if (!args)
error_no_arg ("No mem");
tok = strtok (args, " \t");
if (!tok)
error ("no lo address");
lo = parse_and_eval_address (tok);
tok = strtok (NULL, " \t");
if (!tok)
error ("no hi address");
hi = parse_and_eval_address (tok);
attrib = default_mem_attrib;
while ((tok = strtok (NULL, " \t")) != NULL)
{
if (strcmp (tok, "rw") == 0)
attrib.mode = MEM_RW;
else if (strcmp (tok, "ro") == 0)
attrib.mode = MEM_RO;
else if (strcmp (tok, "wo") == 0)
attrib.mode = MEM_WO;
else if (strcmp (tok, "8") == 0)
attrib.width = MEM_WIDTH_8;
else if (strcmp (tok, "16") == 0)
{
if ((lo % 2 != 0) || (hi % 2 != 0))
error ("region bounds not 16 bit aligned");
attrib.width = MEM_WIDTH_16;
}
else if (strcmp (tok, "32") == 0)
{
if ((lo % 4 != 0) || (hi % 4 != 0))
error ("region bounds not 32 bit aligned");
attrib.width = MEM_WIDTH_32;
}
else if (strcmp (tok, "64") == 0)
{
if ((lo % 8 != 0) || (hi % 8 != 0))
error ("region bounds not 64 bit aligned");
attrib.width = MEM_WIDTH_64;
}
#if 0
else if (strcmp (tok, "hwbreak") == 0)
attrib.hwbreak = true;
else if (strcmp (tok, "swbreak") == 0)
attrib.hwbreak = false;
#endif
else if (strcmp (tok, "cache") == 0)
attrib.cache = true;
else if (strcmp (tok, "nocache") == 0)
attrib.cache = false;
#if 0
else if (strcmp (tok, "verify") == 0)
attrib.verify = true;
else if (strcmp (tok, "noverify") == 0)
attrib.verify = false;
#endif
else
error ("unknown attribute: %s", tok);
}
create_mem_region (lo, hi, &attrib);
}
static void
mem_info_command (char *args, int from_tty)
{
struct mem_region *m;
struct mem_attrib *attrib;
if (!mem_region_chain)
{
printf_unfiltered ("There are no memory regions defined.\n");
return;
}
printf_filtered ("Memory regions now in effect:\n");
for (m = mem_region_chain; m; m = m->next)
{
printf_filtered ("%d: %c\t",
m->number,
m->status ? 'y' : 'n');
printf_filtered ("%s - ",
local_hex_string_custom ((unsigned long) m->lo, "08l"));
printf_filtered ("%s\t",
local_hex_string_custom ((unsigned long) m->hi, "08l"));
/* Print a token for each attribute.
* FIXME: Should we output a comma after each token? It may
* make it easier for users to read, but we'd lose the ability
* to cut-and-paste the list of attributes when defining a new
* region. Perhaps that is not important.
*
* FIXME: If more attributes are added to GDB, the output may
* become cluttered and difficult for users to read. At that
* time, we may want to consider printing tokens only if they
* are different from the default attribute. */
attrib = &m->attrib;
switch (attrib->mode)
{
case MEM_RW:
printf_filtered ("rw ");
break;
case MEM_RO:
printf_filtered ("ro ");
break;
case MEM_WO:
printf_filtered ("wo ");
break;
}
switch (attrib->width)
{
case MEM_WIDTH_8:
printf_filtered ("8 ");
break;
case MEM_WIDTH_16:
printf_filtered ("16 ");
break;
case MEM_WIDTH_32:
printf_filtered ("32 ");
break;
case MEM_WIDTH_64:
printf_filtered ("64 ");
break;
case MEM_WIDTH_UNSPECIFIED:
break;
}
#if 0
if (attrib->hwbreak)
printf_filtered ("hwbreak");
else
printf_filtered ("swbreak");
#endif
if (attrib->cache)
printf_filtered ("cache ");
else
printf_filtered ("nocache ");
#if 0
if (attrib->verify)
printf_filtered ("verify ");
else
printf_filtered ("noverify ");
#endif
printf_filtered ("\n");
gdb_flush (gdb_stdout);
}
}
/* Enable the memory region number NUM. */
static void
mem_enable (int num)
{
struct mem_region *m;
for (m = mem_region_chain; m; m = m->next)
if (m->number == num)
{
m->status = enabled;
return;
}
printf_unfiltered ("No memory region number %d.\n", num);
}
static void
mem_enable_command (char *args, int from_tty)
{
char *p = args;
char *p1;
int num;
struct mem_region *m;
dcache_invalidate (target_dcache);
if (p == 0)
{
for (m = mem_region_chain; m; m = m->next)
m->status = enabled;
}
else
while (*p)
{
p1 = p;
while (*p1 >= '0' && *p1 <= '9')
p1++;
if (*p1 && *p1 != ' ' && *p1 != '\t')
error ("Arguments must be memory region numbers.");
num = atoi (p);
mem_enable (num);
p = p1;
while (*p == ' ' || *p == '\t')
p++;
}
}
/* Disable the memory region number NUM. */
static void
mem_disable (int num)
{
struct mem_region *m;
for (m = mem_region_chain; m; m = m->next)
if (m->number == num)
{
m->status = disabled;
return;
}
printf_unfiltered ("No memory region number %d.\n", num);
}
static void
mem_disable_command (char *args, int from_tty)
{
char *p = args;
char *p1;
int num;
struct mem_region *m;
dcache_invalidate (target_dcache);
if (p == 0)
{
for (m = mem_region_chain; m; m = m->next)
m->status = disabled;
}
else
while (*p)
{
p1 = p;
while (*p1 >= '0' && *p1 <= '9')
p1++;
if (*p1 && *p1 != ' ' && *p1 != '\t')
error ("Arguments must be memory region numbers.");
num = atoi (p);
mem_disable (num);
p = p1;
while (*p == ' ' || *p == '\t')
p++;
}
}
/* Clear memory region list */
static void
mem_clear (void)
{
struct mem_region *m;
while ((m = mem_region_chain) != 0)
{
mem_region_chain = m->next;
delete_mem_region (m);
}
}
/* Delete the memory region number NUM. */
static void
mem_delete (int num)
{
struct mem_region *m1, *m;
if (!mem_region_chain)
{
printf_unfiltered ("No memory region number %d.\n", num);
return;
}
if (mem_region_chain->number == num)
{
m1 = mem_region_chain;
mem_region_chain = m1->next;
delete_mem_region (m1);
}
else
for (m = mem_region_chain; m->next; m = m->next)
{
if (m->next->number == num)
{
m1 = m->next;
m->next = m1->next;
delete_mem_region (m1);
break;
}
}
}
static void
mem_delete_command (char *args, int from_tty)
{
char *p = args;
char *p1;
int num;
dcache_invalidate (target_dcache);
if (p == 0)
{
if (query ("Delete all memory regions? "))
mem_clear ();
dont_repeat ();
return;
}
while (*p)
{
p1 = p;
while (*p1 >= '0' && *p1 <= '9')
p1++;
if (*p1 && *p1 != ' ' && *p1 != '\t')
error ("Arguments must be memory region numbers.");
num = atoi (p);
mem_delete (num);
p = p1;
while (*p == ' ' || *p == '\t')
p++;
}
dont_repeat ();
}
void
_initialize_mem ()
{
add_com ("mem", class_vars, mem_command,
"Define attributes for memory region.");
add_cmd ("mem", class_vars, mem_enable_command,
"Enable memory region.\n\
Arguments are the code numbers of the memory regions to enable.\n\
Do \"info mem\" to see current list of code numbers.", &enablelist);
add_cmd ("mem", class_vars, mem_disable_command,
"Disable memory region.\n\
Arguments are the code numbers of the memory regions to disable.\n\
Do \"info mem\" to see current list of code numbers.", &disablelist);
add_cmd ("mem", class_vars, mem_delete_command,
"Delete memory region.\n\
Arguments are the code numbers of the memory regions to delete.\n\
Do \"info mem\" to see current list of code numbers.", &deletelist);
add_info ("mem", mem_info_command,
"Memory region attributes");
}