int
__BS(translate)(void *v, bus_addr_t addr, bus_size_t len, int flags,
struct mips_bus_space_translation *mbst)
{
bus_addr_t end = addr + (len - 1);
#if CHIP_ALIGN_STRIDE != 0
int linear = flags & BUS_SPACE_MAP_LINEAR;
/*
* Can't map xxx space linearly.
*/
if (linear)
return (EOPNOTSUPP);
#endif
#ifdef CHIP_W1_BUS_START
if (addr >= CHIP_W1_BUS_START(v) && end <= CHIP_W1_BUS_END(v))
return (__BS(get_window)(v, 0, mbst));
#endif
#ifdef CHIP_W2_BUS_START
if (addr >= CHIP_W2_BUS_START(v) && end <= CHIP_W2_BUS_END(v))
return (__BS(get_window)(v, 1, mbst));
#endif
#ifdef CHIP_W3_BUS_START
if (addr >= CHIP_W3_BUS_START(v) && end <= CHIP_W3_BUS_END(v))
return (__BS(get_window)(v, 2, mbst));
#endif
#ifdef EXTENT_DEBUG
printf("\n");
#ifdef CHIP_W1_BUS_START
printf("%s: window[1]=0x%lx-0x%lx\n", __S(__BS(map)),
(u_long)CHIP_W1_BUS_START(v), (u_long)CHIP_W1_BUS_END(v));
#endif
#ifdef CHIP_W2_BUS_START
printf("%s: window[2]=0x%lx-0x%lx\n", __S(__BS(map)),
(u_long)CHIP_W2_BUS_START(v), (u_long)CHIP_W2_BUS_END(v));
#endif
#ifdef CHIP_W3_BUS_START
printf("%s: window[3]=0x%lx-0x%lx\n", __S(__BS(map)),
(u_long)CHIP_W3_BUS_START(v), (u_long)CHIP_W3_BUS_END(v));
#endif
#endif /* EXTENT_DEBUG */
/* No translation. */
return (EINVAL);
}
void
__C(CHIP,_mem_unmap)(
void *v,
bus_space_handle_t memh,
bus_size_t memsize,
int acct)
{
bus_addr_t memaddr;
int error;
if (acct == 0)
return;
#ifdef EXTENT_DEBUG
printf("mem: freeing handle 0x%lx for 0x%lx\n", memh, memsize);
#endif
memaddr = memh - ALPHA_PHYS_TO_K0SEG(CHIP_MEM_SYS_START(v));
#ifdef EXTENT_DEBUG
printf("mem: freeing 0x%lx to 0x%lx\n", memaddr, memaddr + memsize - 1);
#endif
error = extent_free(CHIP_MEM_EXTENT(v), memaddr, memsize,
EX_NOWAIT | (CHIP_EX_MALLOC_SAFE(v) ? EX_MALLOCOK : 0));
if (error) {
printf("%s: WARNING: could not unmap 0x%lx-0x%lx (error %d)\n",
__S(__C(CHIP,_mem_unmap)), memaddr, memaddr + memsize - 1,
error);
#ifdef EXTENT_DEBUG
extent_print(CHIP_MEM_EXTENT(v));
#endif
}
}
int
__C(CHIP,_mem_get_window)(
void *v,
int window,
struct alpha_bus_space_translation *abst)
{
switch (window) {
case 0:
abst->abst_bus_start = 0;
abst->abst_bus_end = 0xffffffffUL;
abst->abst_sys_start = CHIP_MEM_SYS_START(v);
abst->abst_sys_end = CHIP_MEM_SYS_START(v) + abst->abst_bus_end;
abst->abst_addr_shift = 0;
abst->abst_size_shift = 0;
abst->abst_flags = ABST_DENSE|ABST_BWX;
break;
default:
panic(__S(__C(CHIP,_mem_get_window)) ": invalid window %d",
window);
}
return (0);
}
static inline void
__C(CHIP,_mem_write_8)(
void *v,
bus_space_handle_t memh,
bus_size_t off,
uint64_t val)
{
/* XXX XXX XXX */
panic("%s not implemented", __S(__C(CHIP,_mem_write_8)));
alpha_mb();
}
static inline uint64_t
__C(CHIP,_mem_read_8)(
void *v,
bus_space_handle_t memh,
bus_size_t off)
{
alpha_mb();
/* XXX XXX XXX */
panic("%s not implemented", __S(__C(CHIP,_mem_read_8)));
}
static inline uint32_t
__C(CHIP,_mem_read_4)(
void *v,
bus_space_handle_t memh,
bus_size_t off)
{
bus_addr_t addr;
addr = memh + off;
#ifdef DIAGNOSTIC
if (addr & 3)
panic(__S(__C(CHIP,_mem_read_4)) ": addr 0x%lx not aligned",
addr);
#endif
alpha_mb();
return (*(uint32_t *)addr);
}
int
__BS(get_window)(void *v, int window, struct mips_bus_space_translation *mbst)
{
switch (window) {
#ifdef CHIP_W1_BUS_START
case 0:
mbst->mbst_bus_start = CHIP_W1_BUS_START(v);
mbst->mbst_bus_end = CHIP_W1_BUS_END(v);
mbst->mbst_sys_start = CHIP_W1_SYS_START(v);
mbst->mbst_sys_end = CHIP_W1_SYS_END(v);
mbst->mbst_align_stride = CHIP_ALIGN_STRIDE;
mbst->mbst_flags = 0;
break;
#endif
#ifdef CHIP_W2_BUS_START
case 1:
mbst->mbst_bus_start = CHIP_W2_BUS_START(v);
mbst->mbst_bus_end = CHIP_W2_BUS_END(v);
mbst->mbst_sys_start = CHIP_W2_SYS_START(v);
mbst->mbst_sys_end = CHIP_W2_SYS_END(v);
mbst->mbst_align_stride = CHIP_ALIGN_STRIDE;
mbst->mbst_flags = 0;
break;
#endif
#ifdef CHIP_W3_BUS_START
case 2:
mbst->mbst_bus_start = CHIP_W3_BUS_START(v);
mbst->mbst_bus_end = CHIP_W3_BUS_END(v);
mbst->mbst_sys_start = CHIP_W3_SYS_START(v);
mbst->mbst_sys_end = CHIP_W3_SYS_END(v);
mbst->mbst_align_stride = CHIP_ALIGN_STRIDE;
mbst->mbst_flags = 0;
break;
#endif
default:
panic(__S(__BS(get_window)) ": invalid window %d",
window);
}
return (0);
}
static inline void
__C(CHIP,_mem_write_4)(
void *v,
bus_space_handle_t memh,
bus_size_t off,
uint32_t val)
{
bus_addr_t addr;
addr = memh + off;
#ifdef DIAGNOSTIC
if (addr & 3)
panic(__S(__C(CHIP,_mem_write_4)) ": addr 0x%lx not aligned",
addr);
#endif
*(uint32_t *)addr = val;
alpha_mb();
}
TEST(cstr, simd_match_ctext_vchar)
{
#define N 300
#define P 23
int i;
char buf[N] = {[0 ... N - 1] = 0xff }; /* fill in with valid chars */
BUILD_BUG_ON(N < P + 257 || P < 1);
/* All the allowed characters are matched. */
for (i = 0; i <= 0xff; ++i)
if (i == 9 || (i >= 0x20 && i != 0x7f))
buf[P + i] = i;
EXPECT_TRUE(tfw_match_ctext_vchar(buf, N) == N);
/* Check short strings. */
EXPECT_TRUE(tfw_match_ctext_vchar(buf + P - 1, 4) == 4);
EXPECT_TRUE(tfw_match_ctext_vchar(buf + P - 1, 15) == 15);
EXPECT_TRUE(tfw_match_ctext_vchar(buf + P - 1, 29) == 29);
/* Check not allowed characters. */
buf[P + 0x7f] = 0x7f;
EXPECT_TRUE(tfw_match_ctext_vchar(buf, N) == P + 0x7f);
buf[P + 0x1f] = 0x1f;
EXPECT_TRUE(tfw_match_ctext_vchar(buf, N) == P + 0x1f);
buf[P + 0xa] = 0xa;
EXPECT_TRUE(tfw_match_ctext_vchar(buf, N) == P + 0xa);
buf[P + 8] = 8;
EXPECT_TRUE(tfw_match_ctext_vchar(buf, N) == P + 8);
buf[P + 0] = 0;
EXPECT_TRUE(tfw_match_ctext_vchar(buf, N) == P);
#undef P
#undef N
#define __S(s) s, sizeof(s) - 1
__test_ctext_vchar(__S(""));
__test_ctext_vchar(__S(" "));
__test_ctext_vchar(__S("\x08"));
__test_ctext_vchar(__S("a\x00z"));
__test_ctext_vchar(__S(" \tx\rz"));
__test_ctext_vchar(__S("\t !?@_`~>^Aa\x80\xff\x81\xfe\x00\xa\x1f\x1e"));
__test_ctext_vchar(__S("\t !?@_`~>^A}a\x80\xff\x81"
"\xfe\xaa\\Z+'\x7f\x00\x08\xa\x1f\x1\x1e"));
__test_ctext_vchar(__S("\t !?@_`~>^A}a\x80\xff\x81"
"\xfe\xaa\\Zz09+'\x7f\x00\x08\xa\x1f\x1\x1e"));
__test_ctext_vchar(__S("123456789_123456789_123456789_123456789_"
"abc\x7fmdef"));
__test_ctext_vchar(__S("123456789_123456789_123456789_123456789_"
"123456789_123456789_123456789_123456789_"
"abc\x7mdef"));
__test_ctext_vchar(__S("123456789_123456789_123456789_123456789_"
"123456789_123456789_123456789_123456789_"
"123456789_123456789_123456789_123456789_"
"abcmdef\x0"));
__test_ctext_vchar(__S("123456789_123456789_123456789_123456789_"
"123456789_123456789_123456789_123456789_"
"123456789_123456789_123456789_123456789_"
"123456789_123456789_123456789_123456789_"
"a\x6pbcmdef"));
#undef __S
}
void
__C(CHIP,_bus_mem_init)(bus_space_tag_t t, void *v)
{
#ifdef CHIP_D_MEM_W1_SYS_START
struct extent *dex;
#endif
struct extent *sex;
/*
* Initialize the bus space tag.
*/
/* cookie */
t->abs_cookie = v;
/* mapping/unmapping */
t->abs_map = __C(CHIP,_mem_map);
t->abs_unmap = __C(CHIP,_mem_unmap);
t->abs_subregion = __C(CHIP,_mem_subregion);
t->abs_translate = __C(CHIP,_mem_translate);
t->abs_get_window = __C(CHIP,_mem_get_window);
/* allocation/deallocation */
t->abs_alloc = __C(CHIP,_mem_alloc);
t->abs_free = __C(CHIP,_mem_free);
/* get kernel virtual address */
t->abs_vaddr = __C(CHIP,_mem_vaddr);
/* mmap for user */
t->abs_mmap = __C(CHIP,_mem_mmap);
/* barrier */
t->abs_barrier = __C(CHIP,_mem_barrier);
/* read (single) */
t->abs_r_1 = __C(CHIP,_mem_read_1);
t->abs_r_2 = __C(CHIP,_mem_read_2);
t->abs_r_4 = __C(CHIP,_mem_read_4);
t->abs_r_8 = __C(CHIP,_mem_read_8);
/* read multiple */
t->abs_rm_1 = __C(CHIP,_mem_read_multi_1);
t->abs_rm_2 = __C(CHIP,_mem_read_multi_2);
t->abs_rm_4 = __C(CHIP,_mem_read_multi_4);
t->abs_rm_8 = __C(CHIP,_mem_read_multi_8);
/* read region */
t->abs_rr_1 = __C(CHIP,_mem_read_region_1);
t->abs_rr_2 = __C(CHIP,_mem_read_region_2);
t->abs_rr_4 = __C(CHIP,_mem_read_region_4);
t->abs_rr_8 = __C(CHIP,_mem_read_region_8);
/* write (single) */
t->abs_w_1 = __C(CHIP,_mem_write_1);
t->abs_w_2 = __C(CHIP,_mem_write_2);
t->abs_w_4 = __C(CHIP,_mem_write_4);
t->abs_w_8 = __C(CHIP,_mem_write_8);
/* write multiple */
t->abs_wm_1 = __C(CHIP,_mem_write_multi_1);
t->abs_wm_2 = __C(CHIP,_mem_write_multi_2);
t->abs_wm_4 = __C(CHIP,_mem_write_multi_4);
t->abs_wm_8 = __C(CHIP,_mem_write_multi_8);
/* write region */
t->abs_wr_1 = __C(CHIP,_mem_write_region_1);
t->abs_wr_2 = __C(CHIP,_mem_write_region_2);
t->abs_wr_4 = __C(CHIP,_mem_write_region_4);
t->abs_wr_8 = __C(CHIP,_mem_write_region_8);
/* set multiple */
t->abs_sm_1 = __C(CHIP,_mem_set_multi_1);
t->abs_sm_2 = __C(CHIP,_mem_set_multi_2);
t->abs_sm_4 = __C(CHIP,_mem_set_multi_4);
t->abs_sm_8 = __C(CHIP,_mem_set_multi_8);
/* set region */
t->abs_sr_1 = __C(CHIP,_mem_set_region_1);
t->abs_sr_2 = __C(CHIP,_mem_set_region_2);
t->abs_sr_4 = __C(CHIP,_mem_set_region_4);
t->abs_sr_8 = __C(CHIP,_mem_set_region_8);
/* copy */
t->abs_c_1 = __C(CHIP,_mem_copy_region_1);
t->abs_c_2 = __C(CHIP,_mem_copy_region_2);
t->abs_c_4 = __C(CHIP,_mem_copy_region_4);
t->abs_c_8 = __C(CHIP,_mem_copy_region_8);
#ifdef CHIP_D_MEM_W1_SYS_START
/* XXX WE WANT EXTENT_NOCOALESCE, BUT WE CAN'T USE IT. XXX */
dex = extent_create(__S(__C(CHIP,_bus_dmem)), 0x0UL,
0xffffffffffffffffUL,
(void *)CHIP_D_MEM_EX_STORE(v), CHIP_D_MEM_EX_STORE_SIZE(v),
EX_NOWAIT);
extent_alloc_region(dex, 0, 0xffffffffffffffffUL, EX_NOWAIT);
#ifdef CHIP_D_MEM_W1_BUS_START
#ifdef EXTENT_DEBUG
printf("dmem: freeing from 0x%lx to 0x%lx\n",
CHIP_D_MEM_W1_BUS_START(v), CHIP_D_MEM_W1_BUS_END(v));
#endif
extent_free(dex, CHIP_D_MEM_W1_BUS_START(v),
CHIP_D_MEM_W1_BUS_END(v) - CHIP_D_MEM_W1_BUS_START(v) + 1,
EX_NOWAIT);
#endif
#ifdef EXTENT_DEBUG
extent_print(dex);
#endif
CHIP_D_MEM_EXTENT(v) = dex;
#endif /* CHIP_D_MEM_W1_SYS_START */
/* XXX WE WANT EXTENT_NOCOALESCE, BUT WE CAN'T USE IT. XXX */
sex = extent_create(__S(__C(CHIP,_bus_smem)), 0x0UL,
0xffffffffffffffffUL,
(void *)CHIP_S_MEM_EX_STORE(v), CHIP_S_MEM_EX_STORE_SIZE(v),
EX_NOWAIT);
extent_alloc_region(sex, 0, 0xffffffffffffffffUL, EX_NOWAIT);
#ifdef CHIP_S_MEM_W1_BUS_START
#ifdef EXTENT_DEBUG
printf("smem: freeing from 0x%lx to 0x%lx\n",
CHIP_S_MEM_W1_BUS_START(v), CHIP_S_MEM_W1_BUS_END(v));
#endif
extent_free(sex, CHIP_S_MEM_W1_BUS_START(v),
CHIP_S_MEM_W1_BUS_END(v) - CHIP_S_MEM_W1_BUS_START(v) + 1,
EX_NOWAIT);
#endif
#ifdef CHIP_S_MEM_W2_BUS_START
if (CHIP_S_MEM_W2_BUS_START(v) != CHIP_S_MEM_W1_BUS_START(v)) {
#ifdef EXTENT_DEBUG
printf("smem: freeing from 0x%lx to 0x%lx\n",
CHIP_S_MEM_W2_BUS_START(v), CHIP_S_MEM_W2_BUS_END(v));
#endif
extent_free(sex, CHIP_S_MEM_W2_BUS_START(v),
CHIP_S_MEM_W2_BUS_END(v) - CHIP_S_MEM_W2_BUS_START(v) + 1,
EX_NOWAIT);
} else {
#ifdef EXTENT_DEBUG
printf("smem: window 2 (0x%lx to 0x%lx) overlaps window 1\n",
CHIP_S_MEM_W2_BUS_START(v), CHIP_S_MEM_W2_BUS_END(v));
#endif
}
#endif
#ifdef CHIP_S_MEM_W3_BUS_START
if (CHIP_S_MEM_W3_BUS_START(v) != CHIP_S_MEM_W1_BUS_START(v) &&
CHIP_S_MEM_W3_BUS_START(v) != CHIP_S_MEM_W2_BUS_START(v)) {
#ifdef EXTENT_DEBUG
printf("smem: freeing from 0x%lx to 0x%lx\n",
CHIP_S_MEM_W3_BUS_START(v), CHIP_S_MEM_W3_BUS_END(v));
#endif
extent_free(sex, CHIP_S_MEM_W3_BUS_START(v),
CHIP_S_MEM_W3_BUS_END(v) - CHIP_S_MEM_W3_BUS_START(v) + 1,
EX_NOWAIT);
} else {
#ifdef EXTENT_DEBUG
printf("smem: window 2 (0x%lx to 0x%lx) overlaps window 1\n",
CHIP_S_MEM_W2_BUS_START(v), CHIP_S_MEM_W2_BUS_END(v));
#endif
}
#endif
#ifdef EXTENT_DEBUG
extent_print(sex);
#endif
CHIP_S_MEM_EXTENT(v) = sex;
}
void
__C(CHIP,_bus_mem_init)(
bus_space_tag_t t,
void *v)
{
struct extent *ex;
/*
* Initialize the bus space tag.
*/
/* cookie */
t->abs_cookie = v;
/* mapping/unmapping */
t->abs_map = __C(CHIP,_mem_map);
t->abs_unmap = __C(CHIP,_mem_unmap);
t->abs_subregion = __C(CHIP,_mem_subregion);
t->abs_translate = __C(CHIP,_mem_translate);
t->abs_get_window = __C(CHIP,_mem_get_window);
/* allocation/deallocation */
t->abs_alloc = __C(CHIP,_mem_alloc);
t->abs_free = __C(CHIP,_mem_free);
/* get kernel virtual address */
t->abs_vaddr = __C(CHIP,_mem_vaddr);
/* mmap for user */
t->abs_mmap = __C(CHIP,_mem_mmap);
/* barrier */
t->abs_barrier = __C(CHIP,_mem_barrier);
/* read (single) */
t->abs_r_1 = __C(CHIP,_mem_read_1);
t->abs_r_2 = __C(CHIP,_mem_read_2);
t->abs_r_4 = __C(CHIP,_mem_read_4);
t->abs_r_8 = __C(CHIP,_mem_read_8);
/* read multiple */
t->abs_rm_1 = __C(CHIP,_mem_read_multi_1);
t->abs_rm_2 = __C(CHIP,_mem_read_multi_2);
t->abs_rm_4 = __C(CHIP,_mem_read_multi_4);
t->abs_rm_8 = __C(CHIP,_mem_read_multi_8);
/* read region */
t->abs_rr_1 = __C(CHIP,_mem_read_region_1);
t->abs_rr_2 = __C(CHIP,_mem_read_region_2);
t->abs_rr_4 = __C(CHIP,_mem_read_region_4);
t->abs_rr_8 = __C(CHIP,_mem_read_region_8);
/* write (single) */
t->abs_w_1 = __C(CHIP,_mem_write_1);
t->abs_w_2 = __C(CHIP,_mem_write_2);
t->abs_w_4 = __C(CHIP,_mem_write_4);
t->abs_w_8 = __C(CHIP,_mem_write_8);
/* write multiple */
t->abs_wm_1 = __C(CHIP,_mem_write_multi_1);
t->abs_wm_2 = __C(CHIP,_mem_write_multi_2);
t->abs_wm_4 = __C(CHIP,_mem_write_multi_4);
t->abs_wm_8 = __C(CHIP,_mem_write_multi_8);
/* write region */
t->abs_wr_1 = __C(CHIP,_mem_write_region_1);
t->abs_wr_2 = __C(CHIP,_mem_write_region_2);
t->abs_wr_4 = __C(CHIP,_mem_write_region_4);
t->abs_wr_8 = __C(CHIP,_mem_write_region_8);
/* set multiple */
t->abs_sm_1 = __C(CHIP,_mem_set_multi_1);
t->abs_sm_2 = __C(CHIP,_mem_set_multi_2);
t->abs_sm_4 = __C(CHIP,_mem_set_multi_4);
t->abs_sm_8 = __C(CHIP,_mem_set_multi_8);
/* set region */
t->abs_sr_1 = __C(CHIP,_mem_set_region_1);
t->abs_sr_2 = __C(CHIP,_mem_set_region_2);
t->abs_sr_4 = __C(CHIP,_mem_set_region_4);
t->abs_sr_8 = __C(CHIP,_mem_set_region_8);
/* copy */
t->abs_c_1 = __C(CHIP,_mem_copy_region_1);
t->abs_c_2 = __C(CHIP,_mem_copy_region_2);
t->abs_c_4 = __C(CHIP,_mem_copy_region_4);
t->abs_c_8 = __C(CHIP,_mem_copy_region_8);
ex = extent_create(__S(__C(CHIP,_bus_mem)), 0x0UL, 0xffffffffUL,
(void *)CHIP_MEM_EX_STORE(v), CHIP_MEM_EX_STORE_SIZE(v),
EX_NOWAIT|EX_NOCOALESCE);
CHIP_MEM_EXTENT(v) = ex;
}
void
__BS(unmap)(void *v, bus_space_handle_t h, bus_size_t size, int acct)
{
#ifdef CHIP_EXTENT
bus_addr_t addr;
int error;
if (acct == 0)
return;
#ifdef EXTENT_DEBUG
printf("xxx: freeing handle 0x%lx for 0x%lx\n", h, size);
#endif
if (h >= MIPS_KSEG0_START && h < MIPS_KSEG1_START)
h = MIPS_KSEG0_TO_PHYS(h);
else
h = MIPS_KSEG1_TO_PHYS(h);
#ifdef CHIP_W1_BUS_START
if (h >= CHIP_W1_SYS_START(v) && h <= CHIP_W1_SYS_END(v)) {
addr = CHIP_W1_BUS_START(v) + (h - CHIP_W1_SYS_START(v));
} else
#endif
#ifdef CHIP_W2_BUS_START
if (h >= CHIP_W2_SYS_START(v) && h <= CHIP_W2_SYS_END(v)) {
addr = CHIP_W2_BUS_START(v) + (h - CHIP_W2_SYS_START(v));
} else
#endif
#ifdef CHIP_W3_BUS_START
if (h >= CHIP_W3_SYS_START(v) && h <= CHIP_W3_SYS_END(v)) {
addr = CHIP_W3_BUS_START(v) + (h - CHIP_W3_SYS_START(v));
} else
#endif
{
printf("\n");
#ifdef CHIP_W1_BUS_START
printf("%s: sys window[1]=0x%lx-0x%lx\n",
__S(__BS(map)), (u_long)CHIP_W1_SYS_START(v),
(u_long)CHIP_W1_SYS_END(v));
#endif
#ifdef CHIP_W2_BUS_START
printf("%s: sys window[2]=0x%lx-0x%lx\n",
__S(__BS(map)), (u_long)CHIP_W2_SYS_START(v),
(u_long)CHIP_W2_SYS_END(v));
#endif
#ifdef CHIP_W3_BUS_START
printf("%s: sys window[3]=0x%lx-0x%lx\n",
__S(__BS(map)), (u_long)CHIP_W3_SYS_START(v),
(u_long)CHIP_W3_SYS_END(v));
#endif
panic("%s: don't know how to unmap %lx", __S(__BS(unmap)), h);
}
#ifdef EXTENT_DEBUG
printf("xxx: freeing 0x%lx to 0x%lx\n", addr, addr + size - 1);
#endif
error = extent_free(CHIP_EXTENT(v), addr, size,
EX_NOWAIT | (CHIP_EX_MALLOC_SAFE(v) ? EX_MALLOCOK : 0));
if (error) {
printf("%s: WARNING: could not unmap 0x%lx-0x%lx (error %d)\n",
__S(__BS(unmap)), addr, addr + size - 1,
error);
#ifdef EXTENT_DEBUG
extent_print(CHIP_EXTENT(v));
#endif
}
#endif /* CHIP_EXTENT */
}
void
__BS(init)(bus_space_tag_t t, void *v)
{
#ifdef CHIP_EXTENT
struct extent *ex;
#endif
/*
* Initialize the bus space tag.
*/
/* cookie */
t->bs_cookie = v;
/* mapping/unmapping */
t->bs_map = __BS(map);
t->bs_unmap = __BS(unmap);
t->bs_subregion = __BS(subregion);
t->bs_translate = __BS(translate);
t->bs_get_window = __BS(get_window);
/* allocation/deallocation */
t->bs_alloc = __BS(alloc);
t->bs_free = __BS(free);
/* get kernel virtual address */
t->bs_vaddr = __BS(vaddr);
/* mmap for user */
t->bs_mmap = __BS(mmap);
/* barrier */
t->bs_barrier = __BS(barrier);
/* read (single) */
t->bs_r_1 = __BS(read_1);
t->bs_r_2 = __BS(read_2);
t->bs_r_4 = __BS(read_4);
t->bs_r_8 = __BS(read_8);
/* read multiple */
t->bs_rm_1 = __BS(read_multi_1);
t->bs_rm_2 = __BS(read_multi_2);
t->bs_rm_4 = __BS(read_multi_4);
t->bs_rm_8 = __BS(read_multi_8);
/* read region */
t->bs_rr_1 = __BS(read_region_1);
t->bs_rr_2 = __BS(read_region_2);
t->bs_rr_4 = __BS(read_region_4);
t->bs_rr_8 = __BS(read_region_8);
/* write (single) */
t->bs_w_1 = __BS(write_1);
t->bs_w_2 = __BS(write_2);
t->bs_w_4 = __BS(write_4);
t->bs_w_8 = __BS(write_8);
/* write multiple */
t->bs_wm_1 = __BS(write_multi_1);
t->bs_wm_2 = __BS(write_multi_2);
t->bs_wm_4 = __BS(write_multi_4);
t->bs_wm_8 = __BS(write_multi_8);
/* write region */
t->bs_wr_1 = __BS(write_region_1);
t->bs_wr_2 = __BS(write_region_2);
t->bs_wr_4 = __BS(write_region_4);
t->bs_wr_8 = __BS(write_region_8);
/* set multiple */
t->bs_sm_1 = __BS(set_multi_1);
t->bs_sm_2 = __BS(set_multi_2);
t->bs_sm_4 = __BS(set_multi_4);
t->bs_sm_8 = __BS(set_multi_8);
/* set region */
t->bs_sr_1 = __BS(set_region_1);
t->bs_sr_2 = __BS(set_region_2);
t->bs_sr_4 = __BS(set_region_4);
t->bs_sr_8 = __BS(set_region_8);
/* copy */
t->bs_c_1 = __BS(copy_region_1);
t->bs_c_2 = __BS(copy_region_2);
t->bs_c_4 = __BS(copy_region_4);
t->bs_c_8 = __BS(copy_region_8);
#ifdef CHIP_NEED_STREAM
/* read (single), stream */
t->bs_rs_1 = __BS(read_stream_1);
t->bs_rs_2 = __BS(read_stream_2);
t->bs_rs_4 = __BS(read_stream_4);
t->bs_rs_8 = __BS(read_stream_8);
/* read multiple, stream */
t->bs_rms_1 = __BS(read_multi_stream_1);
t->bs_rms_2 = __BS(read_multi_stream_2);
t->bs_rms_4 = __BS(read_multi_stream_4);
t->bs_rms_8 = __BS(read_multi_stream_8);
/* read region, stream */
t->bs_rrs_1 = __BS(read_region_stream_1);
t->bs_rrs_2 = __BS(read_region_stream_2);
t->bs_rrs_4 = __BS(read_region_stream_4);
t->bs_rrs_8 = __BS(read_region_stream_8);
/* write (single), stream */
t->bs_ws_1 = __BS(write_stream_1);
t->bs_ws_2 = __BS(write_stream_2);
t->bs_ws_4 = __BS(write_stream_4);
t->bs_ws_8 = __BS(write_stream_8);
/* write multiple, stream */
t->bs_wms_1 = __BS(write_multi_stream_1);
t->bs_wms_2 = __BS(write_multi_stream_2);
t->bs_wms_4 = __BS(write_multi_stream_4);
t->bs_wms_8 = __BS(write_multi_stream_8);
/* write region, stream */
t->bs_wrs_1 = __BS(write_region_stream_1);
t->bs_wrs_2 = __BS(write_region_stream_2);
t->bs_wrs_4 = __BS(write_region_stream_4);
t->bs_wrs_8 = __BS(write_region_stream_8);
#else /* CHIP_NEED_STREAM */
/* read (single), stream */
t->bs_rs_1 = __BS(read_1);
t->bs_rs_2 = __BS(read_2);
t->bs_rs_4 = __BS(read_4);
t->bs_rs_8 = __BS(read_8);
/* read multiple, stream */
t->bs_rms_1 = __BS(read_multi_1);
t->bs_rms_2 = __BS(read_multi_2);
t->bs_rms_4 = __BS(read_multi_4);
t->bs_rms_8 = __BS(read_multi_8);
/* read region, stream */
t->bs_rrs_1 = __BS(read_region_1);
t->bs_rrs_2 = __BS(read_region_2);
t->bs_rrs_4 = __BS(read_region_4);
t->bs_rrs_8 = __BS(read_region_8);
/* write (single), stream */
t->bs_ws_1 = __BS(write_1);
t->bs_ws_2 = __BS(write_2);
t->bs_ws_4 = __BS(write_4);
t->bs_ws_8 = __BS(write_8);
/* write multiple, stream */
t->bs_wms_1 = __BS(write_multi_1);
t->bs_wms_2 = __BS(write_multi_2);
t->bs_wms_4 = __BS(write_multi_4);
t->bs_wms_8 = __BS(write_multi_8);
/* write region, stream */
t->bs_wrs_1 = __BS(write_region_1);
t->bs_wrs_2 = __BS(write_region_2);
t->bs_wrs_4 = __BS(write_region_4);
t->bs_wrs_8 = __BS(write_region_8);
#endif /* CHIP_NEED_STREAM */
#ifdef CHIP_EXTENT
/* XXX WE WANT EXTENT_NOCOALESCE, BUT WE CAN'T USE IT. XXX */
ex = extent_create(__S(__BS(bus)), 0x0UL, 0xffffffffUL, M_DEVBUF,
(void *)CHIP_EX_STORE(v), CHIP_EX_STORE_SIZE(v), EX_NOWAIT);
extent_alloc_region(ex, 0, 0xffffffffUL, EX_NOWAIT);
#ifdef CHIP_W1_BUS_START
/*
* The window may be disabled. We notice this by seeing
* -1 as the bus base address.
*/
if (CHIP_W1_BUS_START(v) == (bus_addr_t) -1) {
#ifdef EXTENT_DEBUG
printf("xxx: this space is disabled\n");
#endif
return;
}
#ifdef EXTENT_DEBUG
printf("xxx: freeing from 0x%x to 0x%x\n", CHIP_W1_BUS_START(v),
CHIP_W1_BUS_END(v));
#endif
extent_free(ex, CHIP_W1_BUS_START(v),
CHIP_W1_BUS_END(v) - CHIP_W1_BUS_START(v) + 1, EX_NOWAIT);
#endif
#ifdef CHIP_W2_BUS_START
if (CHIP_W2_BUS_START(v) != CHIP_W1_BUS_START(v)) {
#ifdef EXTENT_DEBUG
printf("xxx: freeing from 0x%lx to 0x%lx\n",
(u_long)CHIP_W2_BUS_START(v), (u_long)CHIP_W2_BUS_END(v));
#endif
extent_free(ex, CHIP_W2_BUS_START(v),
CHIP_W2_BUS_END(v) - CHIP_W2_BUS_START(v) + 1, EX_NOWAIT);
} else {
#ifdef EXTENT_DEBUG
printf("xxx: window 2 (0x%lx to 0x%lx) overlaps window 1\n",
(u_long)CHIP_W2_BUS_START(v), (u_long)CHIP_W2_BUS_END(v));
#endif
}
#endif
#ifdef CHIP_W3_BUS_START
if (CHIP_W3_BUS_START(v) != CHIP_W1_BUS_START(v) &&
CHIP_W3_BUS_START(v) != CHIP_W2_BUS_START(v)) {
#ifdef EXTENT_DEBUG
printf("xxx: freeing from 0x%lx to 0x%lx\n",
(u_long)CHIP_W3_BUS_START(v), (u_long)CHIP_W3_BUS_END(v));
#endif
extent_free(ex, CHIP_W3_BUS_START(v),
CHIP_W3_BUS_END(v) - CHIP_W3_BUS_START(v) + 1, EX_NOWAIT);
} else {
#ifdef EXTENT_DEBUG
printf("xxx: window 2 (0x%lx to 0x%lx) overlaps window 1\n",
(u_long)CHIP_W2_BUS_START(v), (u_long)CHIP_W2_BUS_END(v));
#endif
}
#endif
#ifdef EXTENT_DEBUG
extent_print(ex);
#endif
CHIP_EXTENT(v) = ex;
#endif /* CHIP_EXTENT */
}
static int
__BS(alloc)(void *v, bus_addr_t rstart, bus_addr_t rend, bus_size_t size,
bus_size_t align, bus_size_t boundary, int flags, bus_addr_t *addrp,
bus_space_handle_t *bshp)
{
#ifdef CHIP_EXTENT
struct mips_bus_space_translation mbst;
u_long addr; /* bogus but makes extent happy */
int error;
#if CHIP_ALIGN_STRIDE != 0
int linear = flags & BUS_SPACE_MAP_LINEAR;
/*
* Can't map xxx space linearly.
*/
if (linear)
return (EOPNOTSUPP);
#endif
/*
* Do the requested allocation.
*/
#ifdef EXTENT_DEBUG
printf("%s: allocating from %#"PRIxBUSADDR" to %#"PRIxBUSADDR"\n",
__S(__BS(alloc)), rstart, rend);
#endif
error = extent_alloc_subregion(CHIP_EXTENT(v), rstart, rend, size,
align, boundary,
EX_FAST | EX_NOWAIT | (CHIP_EX_MALLOC_SAFE(v) ? EX_MALLOCOK : 0),
&addr);
if (error) {
#ifdef EXTENT_DEBUG
printf("%s: allocation failed (%d)\n", __S(__BS(alloc)), error);
extent_print(CHIP_EXTENT(v));
#endif
return (error);
}
#ifdef EXTENT_DEBUG
printf("%s: allocated 0x%lx to %#"PRIxBUSSIZE"\n",
__S(__BS(alloc)), addr, addr + size - 1);
#endif
error = __BS(translate)(v, addr, size, flags, &mbst);
if (error) {
(void) extent_free(CHIP_EXTENT(v), addr, size,
EX_NOWAIT | (CHIP_EX_MALLOC_SAFE(v) ? EX_MALLOCOK : 0));
return (error);
}
*addrp = addr;
#if !defined(__mips_o32)
if (flags & BUS_SPACE_MAP_CACHEABLE) {
*bshp = MIPS_PHYS_TO_XKPHYS_CACHED(mbst.mbst_sys_start +
(addr - mbst.mbst_bus_start));
} else {
*bshp = MIPS_PHYS_TO_XKPHYS_UNCACHED(mbst.mbst_sys_start +
(addr - mbst.mbst_bus_start));
}
#else
if (flags & BUS_SPACE_MAP_CACHEABLE) {
*bshp = MIPS_PHYS_TO_KSEG0(mbst.mbst_sys_start +
(addr - mbst.mbst_bus_start));
} else
*bshp = MIPS_PHYS_TO_KSEG1(mbst.mbst_sys_start +
(addr - mbst.mbst_bus_start));
#endif
return (0);
#else /* ! CHIP_EXTENT */
return (EOPNOTSUPP);
#endif /* CHIP_EXTENT */
}
static void
__BS(unmap)(void *v, bus_space_handle_t h, bus_size_t size, int acct)
{
#if !defined(_LP64) || defined(CHIP_EXTENT)
bus_addr_t addr = 0; /* initialize to appease gcc */
#endif
#ifndef _LP64
bool handle_is_km;
/* determine if h is addr obtained from uvm_km_alloc */
handle_is_km = !(MIPS_KSEG0_P(h) || MIPS_KSEG1_P(h));
#ifdef __mips_n32
if (handle_is_km == true)
handle_is_km = !MIPS_XKPHYS_P(h);
#endif
if (handle_is_km == true) {
paddr_t pa;
vaddr_t va = (vaddr_t)trunc_page(h);
vsize_t sz = (vsize_t)round_page((h % PAGE_SIZE) + size);
int s;
s = splhigh();
if (pmap_extract(pmap_kernel(), (vaddr_t)h, &pa) == false)
panic("%s: pmap_extract failed", __func__);
addr = (bus_addr_t)pa;
#if 0
printf("%s:%d: addr %#"PRIxBUSADDR", sz %#"PRIxVSIZE"\n",
__func__, __LINE__, addr, sz);
#endif
/* sanity check: this is why we couldn't map w/ kseg[0,1] */
KASSERT (((addr + sz) & ~MIPS_PHYS_MASK) != 0);
pmap_kremove(va, sz);
pmap_update(pmap_kernel());
uvm_km_free(kernel_map, va, sz, UVM_KMF_VAONLY);
splx(s);
}
#endif /* _LP64 */
#ifdef CHIP_EXTENT
if (acct == 0)
return;
#ifdef EXTENT_DEBUG
printf("%s: freeing handle %#"PRIxBSH" for %#"PRIxBUSSIZE"\n",
__S(__BS(unmap)), h, size);
#endif
#ifdef _LP64
KASSERT(MIPS_XKPHYS_P(h));
addr = MIPS_XKPHYS_TO_PHYS(h);
#else
if (handle_is_km == false) {
if (MIPS_KSEG0_P(h))
addr = MIPS_KSEG0_TO_PHYS(h);
#ifdef __mips_n32
else if (MIPS_XKPHYS_P(h))
addr = MIPS_XKPHYS_TO_PHYS(h);
#endif
else
addr = MIPS_KSEG1_TO_PHYS(h);
}
#endif
#ifdef CHIP_W1_BUS_START
if (addr >= CHIP_W1_SYS_START(v) && addr <= CHIP_W1_SYS_END(v)) {
addr = CHIP_W1_BUS_START(v) + (addr - CHIP_W1_SYS_START(v));
} else
#endif
#ifdef CHIP_W2_BUS_START
if (addr >= CHIP_W2_SYS_START(v) && addr <= CHIP_W2_SYS_END(v)) {
addr = CHIP_W2_BUS_START(v) + (addr - CHIP_W2_SYS_START(v));
} else
#endif
#ifdef CHIP_W3_BUS_START
if (addr >= CHIP_W3_SYS_START(v) && addr <= CHIP_W3_SYS_END(v)) {
addr = CHIP_W3_BUS_START(v) + (addr - CHIP_W3_SYS_START(v));
} else
#endif
{
printf("\n");
#ifdef CHIP_W1_BUS_START
printf("%s: sys window[1]=0x%lx-0x%lx\n",
__S(__BS(unmap)), (u_long)CHIP_W1_SYS_START(v),
(u_long)CHIP_W1_SYS_END(v));
#endif
#ifdef CHIP_W2_BUS_START
printf("%s: sys window[2]=0x%lx-0x%lx\n",
__S(__BS(unmap)), (u_long)CHIP_W2_SYS_START(v),
(u_long)CHIP_W2_SYS_END(v));
#endif
#ifdef CHIP_W3_BUS_START
printf("%s: sys window[3]=0x%lx-0x%lx\n",
__S(__BS(unmap)), (u_long)CHIP_W3_SYS_START(v),
(u_long)CHIP_W3_SYS_END(v));
#endif
panic("%s: don't know how to unmap %#"PRIxBSH, __S(__BS(unmap)), h);
}
#ifdef EXTENT_DEBUG
printf("%s: freeing %#"PRIxBUSADDR" to %#"PRIxBUSADDR"\n",
__S(__BS(unmap)), addr, addr + size - 1);
#endif
int error = extent_free(CHIP_EXTENT(v), addr, size,
EX_NOWAIT | (CHIP_EX_MALLOC_SAFE(v) ? EX_MALLOCOK : 0));
if (error) {
printf("%s: WARNING: could not unmap"
" %#"PRIxBUSADDR"-%#"PRIxBUSADDR" (error %d)\n",
__S(__BS(unmap)), addr, addr + size - 1, error);
#ifdef EXTENT_DEBUG
extent_print(CHIP_EXTENT(v));
#endif
}
#endif /* CHIP_EXTENT */
#if !defined(_LP64) || defined(CHIP_EXTENT)
__USE(addr);
#endif
}
static int
__BS(map)(void *v, bus_addr_t addr, bus_size_t size, int flags,
bus_space_handle_t *hp, int acct)
{
struct mips_bus_space_translation mbst;
int error;
/*
* Get the translation for this address.
*/
error = __BS(translate)(v, addr, size, flags, &mbst);
if (error)
return (error);
#ifdef CHIP_EXTENT
if (acct == 0)
goto mapit;
#ifdef EXTENT_DEBUG
printf("%s: allocating %#"PRIxBUSADDR" to %#"PRIxBUSADDR"\n",
__S(__BS(map)), addr, addr + size - 1);
#endif
error = extent_alloc_region(CHIP_EXTENT(v), addr, size,
EX_NOWAIT | (CHIP_EX_MALLOC_SAFE(v) ? EX_MALLOCOK : 0));
if (error) {
#ifdef EXTENT_DEBUG
printf("%s: allocation failed (%d)\n", __S(__BS(map)), error);
extent_print(CHIP_EXTENT(v));
#endif
return (error);
}
mapit:
#endif /* CHIP_EXTENT */
addr = mbst.mbst_sys_start + (addr - mbst.mbst_bus_start);
#if defined(__mips_n32) || defined(_LP64)
if (flags & BUS_SPACE_MAP_CACHEABLE) {
#ifdef __mips_n32
if (((addr + size) & ~MIPS_PHYS_MASK) == 0)
*hp = (intptr_t)MIPS_PHYS_TO_KSEG0(addr);
else
#endif
*hp = MIPS_PHYS_TO_XKPHYS_CACHED(addr);
} else if (flags & BUS_SPACE_MAP_PREFETCHABLE) {
*hp = MIPS_PHYS_TO_XKPHYS_ACC(addr);
} else {
#ifdef __mips_n32
if (((addr + size) & ~MIPS_PHYS_MASK) == 0)
*hp = (intptr_t)MIPS_PHYS_TO_KSEG1(addr);
else
#endif
*hp = MIPS_PHYS_TO_XKPHYS_UNCACHED(addr);
}
#else
if (((addr + size) & ~MIPS_PHYS_MASK) != 0) {
vaddr_t va;
paddr_t pa;
int s;
size = round_page((addr % PAGE_SIZE) + size);
va = uvm_km_alloc(kernel_map, size, PAGE_SIZE,
UVM_KMF_VAONLY | UVM_KMF_NOWAIT);
if (va == 0)
return ENOMEM;
/* check use of handle_is_km in BS(unmap) */
KASSERT(!(MIPS_KSEG0_P(va) || MIPS_KSEG1_P(va)));
*hp = va + (addr & PAGE_MASK);
pa = trunc_page(addr);
s = splhigh();
while (size != 0) {
pmap_kenter_pa(va, pa, VM_PROT_READ | VM_PROT_WRITE, 0);
pa += PAGE_SIZE;
va += PAGE_SIZE;
size -= PAGE_SIZE;
}
pmap_update(pmap_kernel());
splx(s);
} else {
if (flags & BUS_SPACE_MAP_CACHEABLE)
*hp = (intptr_t)MIPS_PHYS_TO_KSEG0(addr);
else
*hp = (intptr_t)MIPS_PHYS_TO_KSEG1(addr);
}
#endif
return (0);
}
