census_context *census_context_create(const census_context *base,
const census_tag *tags, int ntags,
census_context_status const **status) {
census_context *context =
(census_context *)gpr_malloc(sizeof(census_context));
// If we are given a base, copy it into our new tag set. Otherwise set it
// to zero/NULL everything.
if (base == NULL) {
memset(context, 0, sizeof(census_context));
} else {
tag_set_copy(&context->tags[PROPAGATED_TAGS], &base->tags[PROPAGATED_TAGS]);
tag_set_copy(&context->tags[LOCAL_TAGS], &base->tags[LOCAL_TAGS]);
memset(&context->status, 0, sizeof(context->status));
}
// Walk over the additional tags and, for those that aren't invalid, modify
// the context to add/replace/delete as required.
for (int i = 0; i < ntags; i++) {
const census_tag *tag = &tags[i];
size_t key_len = validate_tag(tag->key);
// ignore the tag if it is invalid or too short.
if (key_len <= 1) {
context->status.n_invalid_tags++;
} else {
if (tag->value != NULL) {
size_t value_len = validate_tag(tag->value);
if (value_len != 0) {
context_modify_tag(context, tag, key_len, value_len);
} else {
context->status.n_invalid_tags++;
}
} else {
if (context_delete_tag(context, tag, key_len)) {
context->status.n_deleted_tags++;
}
}
}
}
// Remove any deleted tags, update status if needed, and return.
tag_set_flatten(&context->tags[PROPAGATED_TAGS]);
tag_set_flatten(&context->tags[LOCAL_TAGS]);
context->status.n_propagated_tags = context->tags[PROPAGATED_TAGS].ntags;
context->status.n_local_tags = context->tags[LOCAL_TAGS].ntags;
if (status) {
*status = &context->status;
}
return context;
}
// test many changes at once.
static void replace_add_delete_test(void) {
struct census_tag_set *cts =
census_tag_set_create(NULL, basic_tags, BASIC_TAG_COUNT, NULL);
const census_tag_set_create_status *status;
struct census_tag_set *cts2 =
census_tag_set_create(cts, modify_tags, MODIFY_TAG_COUNT, &status);
census_tag_set_create_status expected = {2, 1, 6, 2, 3, 4, 0, 2};
GPR_ASSERT(memcmp(status, &expected, sizeof(expected)) == 0);
// validate tag set contents. Use specific indices into the two arrays
// holding tag values.
GPR_ASSERT(validate_tag(cts2, &basic_tags[3]));
GPR_ASSERT(validate_tag(cts2, &basic_tags[4]));
GPR_ASSERT(validate_tag(cts2, &modify_tags[0]));
GPR_ASSERT(validate_tag(cts2, &modify_tags[1]));
GPR_ASSERT(validate_tag(cts2, &modify_tags[6]));
GPR_ASSERT(validate_tag(cts2, &modify_tags[7]));
GPR_ASSERT(validate_tag(cts2, &modify_tags[8]));
GPR_ASSERT(validate_tag(cts2, &modify_tags[9]));
GPR_ASSERT(validate_tag(cts2, &modify_tags[10]));
GPR_ASSERT(!validate_tag(cts2, &basic_tags[0]));
GPR_ASSERT(!validate_tag(cts2, &basic_tags[1]));
GPR_ASSERT(!validate_tag(cts2, &basic_tags[2]));
GPR_ASSERT(!validate_tag(cts2, &basic_tags[5]));
GPR_ASSERT(!validate_tag(cts2, &basic_tags[6]));
GPR_ASSERT(!validate_tag(cts2, &basic_tags[7]));
census_tag_set_destroy(cts);
census_tag_set_destroy(cts2);
}
bool device_memory_interface::interface_validity_check(emu_options &options, const game_driver &driver) const
{
bool detected_overlap = DETECT_OVERLAPPING_MEMORY ? false : true;
bool error = false;
// loop over all address spaces
for (address_spacenum spacenum = AS_0; spacenum < ADDRESS_SPACES; spacenum++)
{
const address_space_config *spaceconfig = space_config(spacenum);
if (spaceconfig != NULL)
{
int datawidth = spaceconfig->m_databus_width;
int alignunit = datawidth / 8;
// construct the maps
::address_map *map = global_alloc(::address_map(device(), spacenum));
// if this is an empty map, just skip it
if (map->m_entrylist.first() == NULL)
{
global_free(map);
continue;
}
// validate the global map parameters
if (map->m_spacenum != spacenum)
{
mame_printf_error("%s: %s device '%s' space %d has address space %d handlers!\n", driver.source_file, driver.name, device().tag(), spacenum, map->m_spacenum);
error = true;
}
if (map->m_databits != datawidth)
{
mame_printf_error("%s: %s device '%s' uses wrong memory handlers for %s space! (width = %d, memory = %08x)\n", driver.source_file, driver.name, device().tag(), spaceconfig->m_name, datawidth, map->m_databits);
error = true;
}
// loop over entries and look for errors
for (address_map_entry *entry = map->m_entrylist.first(); entry != NULL; entry = entry->next())
{
UINT32 bytestart = spaceconfig->addr2byte(entry->m_addrstart);
UINT32 byteend = spaceconfig->addr2byte_end(entry->m_addrend);
// look for overlapping entries
if (!detected_overlap)
{
address_map_entry *scan;
for (scan = map->m_entrylist.first(); scan != entry; scan = scan->next())
if (entry->m_addrstart <= scan->m_addrend && entry->m_addrend >= scan->m_addrstart &&
((entry->m_read.m_type != AMH_NONE && scan->m_read.m_type != AMH_NONE) ||
(entry->m_write.m_type != AMH_NONE && scan->m_write.m_type != AMH_NONE)))
{
mame_printf_warning("%s: %s '%s' %s space has overlapping memory (%X-%X,%d,%d) vs (%X-%X,%d,%d)\n", driver.source_file, driver.name, device().tag(), spaceconfig->m_name, entry->m_addrstart, entry->m_addrend, entry->m_read.m_type, entry->m_write.m_type, scan->m_addrstart, scan->m_addrend, scan->m_read.m_type, scan->m_write.m_type);
detected_overlap = true;
break;
}
}
// look for inverted start/end pairs
if (byteend < bytestart)
{
mame_printf_error("%s: %s wrong %s memory read handler start = %08x > end = %08x\n", driver.source_file, driver.name, spaceconfig->m_name, entry->m_addrstart, entry->m_addrend);
error = true;
}
// look for misaligned entries
if ((bytestart & (alignunit - 1)) != 0 || (byteend & (alignunit - 1)) != (alignunit - 1))
{
mame_printf_error("%s: %s wrong %s memory read handler start = %08x, end = %08x ALIGN = %d\n", driver.source_file, driver.name, spaceconfig->m_name, entry->m_addrstart, entry->m_addrend, alignunit);
error = true;
}
// if this is a program space, auto-assign implicit ROM entries
if (entry->m_read.m_type == AMH_ROM && entry->m_region == NULL)
{
entry->m_region = device().tag();
entry->m_rgnoffs = entry->m_addrstart;
}
// if this entry references a memory region, validate it
if (entry->m_region != NULL && entry->m_share == 0)
{
// look for the region
bool found = false;
for (const rom_source *source = rom_first_source(device().mconfig()); source != NULL && !found; source = rom_next_source(*source))
for (const rom_entry *romp = rom_first_region(*source); !ROMENTRY_ISEND(romp) && !found; romp++)
{
const char *regiontag_c = ROMREGION_GETTAG(romp);
if (regiontag_c != NULL)
{
astring fulltag;
astring regiontag;
// a leading : on a region name indicates an absolute region, so fix up accordingly
if (entry->m_region[0] == ':')
{
regiontag = &entry->m_region[1];
}
else
{
if (strchr(entry->m_region,':')) {
regiontag = entry->m_region;
} else {
device().siblingtag(regiontag, entry->m_region);
}
}
rom_region_name(fulltag, &driver, source, romp);
if (fulltag.cmp(regiontag) == 0)
{
// verify the address range is within the region's bounds
offs_t length = ROMREGION_GETLENGTH(romp);
if (entry->m_rgnoffs + (byteend - bytestart + 1) > length)
{
mame_printf_error("%s: %s device '%s' %s space memory map entry %X-%X extends beyond region '%s' size (%X)\n", driver.source_file, driver.name, device().tag(), spaceconfig->m_name, entry->m_addrstart, entry->m_addrend, entry->m_region, length);
error = true;
}
found = true;
}
}
}
// error if not found
if (!found)
{
mame_printf_error("%s: %s device '%s' %s space memory map entry %X-%X references non-existant region '%s'\n", driver.source_file, driver.name, device().tag(), spaceconfig->m_name, entry->m_addrstart, entry->m_addrend, entry->m_region);
error = true;
}
}
// make sure all devices exist
if ((entry->m_read.m_type == AMH_LEGACY_DEVICE_HANDLER && entry->m_read.m_tag != NULL && device().mconfig().devicelist().find(entry->m_read.m_tag) == NULL) ||
(entry->m_write.m_type == AMH_LEGACY_DEVICE_HANDLER && entry->m_write.m_tag != NULL && device().mconfig().devicelist().find(entry->m_write.m_tag) == NULL))
{
mame_printf_error("%s: %s device '%s' %s space memory map entry references nonexistant device '%s'\n", driver.source_file, driver.name, device().tag(), spaceconfig->m_name, entry->m_write.m_tag);
error = true;
}
// make sure ports exist
// if ((entry->m_read.m_type == AMH_PORT && entry->m_read.m_tag != NULL && portlist.find(entry->m_read.m_tag) == NULL) ||
// (entry->m_write.m_type == AMH_PORT && entry->m_write.m_tag != NULL && portlist.find(entry->m_write.m_tag) == NULL))
// {
// mame_printf_error("%s: %s device '%s' %s space memory map entry references nonexistant port tag '%s'\n", driver.source_file, driver.name, device().tag(), spaceconfig->m_name, entry->m_read.tag);
// error = true;
// }
// validate bank and share tags
if (entry->m_read.m_type == AMH_BANK && !validate_tag(driver, "bank", entry->m_read.m_tag))
error = true ;
if (entry->m_write.m_type == AMH_BANK && !validate_tag(driver, "bank", entry->m_write.m_tag))
error = true;
if (entry->m_share != NULL && !validate_tag(driver, "share", entry->m_share))
error = true;
}
// release the address map
global_free(map);
}
}
return error;
}
/* basic xml parser */
static int xml_parse(request *req, tag_t *parent, char *xstr, int len)
{
int i;
int next_ch = -1;
int last_ch = -1;
int this_ch = -1;
int rval;
int state;
tag_t *tag = NULL;
state = set_xstate(XST_DONE);
nest++;
i = 0;
while(i < len) {
last_ch = xstr[i-1];
this_ch = xstr[i];
next_ch = xstr[i+1];
if(state == XST_DONE) {
/* done processing at this level, return processed count to previous level */
if(this_ch == '<' && next_ch == '/')
return i;
state = set_xstate(XST_GET_START_TAG);
tag = create_tag(req, parent);
}
switch (state) {
case XST_GET_START_TAG:
if(!tag->start_name) {
tag->start_name = &xstr[i];
}
tag->start_len++;
/* process any tag attributes */
if(!tag->attr_name) {
if((this_ch == ' ') && (next_ch != '/'))
tag->attr_name = &xstr[i+1];
}
else {
if(this_ch != '>')
tag->attr_len++;
}
if (this_ch == '>') {
if(last_ch == '?') {
if(!req->prolog_tag) {
req->prolog_tag = tag;
state = set_xstate(XST_DONE);
goto NextChar;
}
else
return -1;
}
else if(!req->root_tag) {
req->root_tag = tag;
}
if(last_ch == '/') { // empty tag
state = set_xstate(XST_VALIDATE);
tag->empty = 1;
}
else
state = set_xstate(XST_GET_VALUE);
}
break;
case XST_GET_VALUE:
if (this_ch != '<') {
if(!tag->value_name)
tag->value_name = &xstr[i];
tag->value_len++;
break;
}
else
state = set_xstate(XST_GET_END_TAG);
/* fall through is deliberate */
case XST_GET_END_TAG:
if(!tag->end_name)
tag->end_name = &xstr[i];
tag->end_len++;
if (this_ch == '>')
state = set_xstate(XST_VALIDATE);
break;
}
if(state == XST_VALIDATE) {
state = set_xstate(XST_DONE);
rval = validate_tag(tag);
//fprintf(stderr,"\r\After validate_tag with retval:%d\n",rval);
if (rval == 0) {
tag = NULL;
goto NextChar;
}
/* tag is invalid */
else if (rval < 0) {
return -1;
}
// tag mismatch, adjust len and process child
i = i - tag->end_len;
rval = xml_parse(req, tag, tag->end_name, len-i);
if(rval < 0)
return rval;
tag->end_name = 0; // clear end tag
tag->end_len = 0;
nest--;
state = set_xstate(XST_GET_END_TAG);
i = i+rval; // advance processed offset
}
NextChar:
i++;
};
//fprintf(stderr,"\r\nAfter xml_parse\n");
return i;
}
static int probe_udf(SECTION *section, int level, int sector_size)
{
unsigned char *buffer;
u4 count, addr, sect;
int seen_primary = 0;
int seen_logical = 0;
int i;
char s[256];
/* first read the Anchor Volume Descriptor Pointer @ sector 256 */
if (get_buffer(section, 256 * sector_size, 512, (void **)&buffer) < 512)
return 0;
if (!validate_tag(buffer, 256))
return 0;
/* tag identifier */
if (get_le_short(buffer) != 2)
return 0;
print_line(level, "UDF file system");
print_line(level + 1, "Sector size %d bytes", sector_size);
/* get the Volume Descriptor Area */
count = get_le_long(buffer + 16) / sector_size;
addr = get_le_long(buffer + 20);
/* look for a Logical Volume Descriptor */
for (i = 0; i < count; i++) {
sect = addr + i;
if (get_buffer(section, (u8)sect * sector_size, 512, (void **)&buffer) < 512)
break;
if (!validate_tag(buffer, sect))
continue;
/* switch by tag identifier */
switch (get_le_short(buffer)) {
case 1: /* Primary Volume Descriptor */
if (!seen_primary) {
seen_primary = 1;
if (buffer[24] == 8) {
get_string(buffer + 25, 30, s);
print_line(level+1, "Volume name \"%s\"", s);
} else if (buffer[24] == 16) {
format_utf16_le(buffer + 25, 30, s);
print_line(level+1, "Volume name \"%s\"", s);
} else {
print_line(level+1, "Volume name encoding not supported");
}
}
break;
case 6: /* Logical Volume Descriptor */
if (!seen_logical) {
seen_logical = 1;
if (memcmp(buffer + 216+1, "*OSTA UDF Compliant", 19) == 0) {
print_line(level+1, "UDF version %x.%02x",
(int)buffer[216+25], (int)buffer[216+24]);
}
}
break;
}
}
if (!seen_primary) {
print_line(level + 1, "Primary Volume Descriptor missing");
}
return 1; /* some problems */
}
