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1022 1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055 1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105 1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134 1135 1136 1137 1138 1139 1140 1141 1142 1143 1144 1145 1146 1147 1148 1149 1150 1151 1152 1153 1154 1155 1156 1157 1158 1159 1160 1161 1162 1163 1164 1165 1166 1167 1168 1169 1170 1171 1172 1173 1174 1175 1176 1177 1178 1179 1180 1181 1182 1183 1184 1185 1186 1187 1188 1189 1190 1191 1192 1193 1194 1195 1196 1197 1198 1199 1200 1201 1202 1203 1204 1205 1206 1207 1208 1209 1210 1211 1212 1213 1214 1215 1216 1217 1218 1219 1220 1221 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See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include <linux/kernel.h> #include <linux/export.h> #include <linux/memblock.h> #include <linux/slab.h> #include <asm/cell-regs.h> #include <asm/firmware.h> #include <asm/prom.h> #include <asm/udbg.h> #include <asm/lv1call.h> #include <asm/setup.h> #include "platform.h" #if defined(DEBUG) #define DBG udbg_printf #else #define DBG pr_devel #endif enum { #if defined(CONFIG_PS3_DYNAMIC_DMA) USE_DYNAMIC_DMA = 1, #else USE_DYNAMIC_DMA = 0, #endif }; enum { PAGE_SHIFT_4K = 12U, PAGE_SHIFT_64K = 16U, PAGE_SHIFT_16M = 24U, }; static unsigned long make_page_sizes(unsigned long a, unsigned long b) { return (a << 56) | (b << 48); } enum { ALLOCATE_MEMORY_TRY_ALT_UNIT = 0X04, ALLOCATE_MEMORY_ADDR_ZERO = 0X08, }; /* valid htab sizes are {18,19,20} = 256K, 512K, 1M */ enum { HTAB_SIZE_MAX = 20U, /* HV limit of 1MB */ HTAB_SIZE_MIN = 18U, /* CPU limit of 256KB */ }; /*============================================================================*/ /* virtual address space routines */ /*============================================================================*/ /** * struct mem_region - memory region structure * @base: base address * @size: size in bytes * @offset: difference between base and rm.size * @destroy: flag if region should be destroyed upon shutdown */ struct mem_region { u64 base; u64 size; unsigned long offset; int destroy; }; /** * struct map - address space state variables holder * @total: total memory available as reported by HV * @vas_id - HV virtual address space id * @htab_size: htab size in bytes * * The HV virtual address space (vas) allows for hotplug memory regions. * Memory regions can be created and destroyed in the vas at runtime. * @rm: real mode (bootmem) region * @r1: highmem region(s) * * ps3 addresses * virt_addr: a cpu 'translated' effective address * phys_addr: an address in what Linux thinks is the physical address space * lpar_addr: an address in the HV virtual address space * bus_addr: an io controller 'translated' address on a device bus */ struct map { u64 total; u64 vas_id; u64 htab_size; struct mem_region rm; struct mem_region r1; }; #define debug_dump_map(x) _debug_dump_map(x, __func__, __LINE__) static void __maybe_unused _debug_dump_map(const struct map *m, const char *func, int line) { DBG("%s:%d: map.total = %llxh\n", func, line, m->total); DBG("%s:%d: map.rm.size = %llxh\n", func, line, m->rm.size); DBG("%s:%d: map.vas_id = %llu\n", func, line, m->vas_id); DBG("%s:%d: map.htab_size = %llxh\n", func, line, m->htab_size); DBG("%s:%d: map.r1.base = %llxh\n", func, line, m->r1.base); DBG("%s:%d: map.r1.offset = %lxh\n", func, line, m->r1.offset); DBG("%s:%d: map.r1.size = %llxh\n", func, line, m->r1.size); } static struct map map; /** * ps3_mm_phys_to_lpar - translate a linux physical address to lpar address * @phys_addr: linux physical address */ unsigned long ps3_mm_phys_to_lpar(unsigned long phys_addr) { BUG_ON(is_kernel_addr(phys_addr)); return (phys_addr < map.rm.size || phys_addr >= map.total) ? phys_addr : phys_addr + map.r1.offset; } EXPORT_SYMBOL(ps3_mm_phys_to_lpar); /** * ps3_mm_vas_create - create the virtual address space */ void __init ps3_mm_vas_create(unsigned long* htab_size) { int result; u64 start_address; u64 size; u64 access_right; u64 max_page_size; u64 flags; result = lv1_query_logical_partition_address_region_info(0, &start_address, &size, &access_right, &max_page_size, &flags); if (result) { DBG("%s:%d: lv1_query_logical_partition_address_region_info " "failed: %s\n", __func__, __LINE__, ps3_result(result)); goto fail; } if (max_page_size < PAGE_SHIFT_16M) { DBG("%s:%d: bad max_page_size %llxh\n", __func__, __LINE__, max_page_size); goto fail; } BUILD_BUG_ON(CONFIG_PS3_HTAB_SIZE > HTAB_SIZE_MAX); BUILD_BUG_ON(CONFIG_PS3_HTAB_SIZE < HTAB_SIZE_MIN); result = lv1_construct_virtual_address_space(CONFIG_PS3_HTAB_SIZE, 2, make_page_sizes(PAGE_SHIFT_16M, PAGE_SHIFT_64K), &map.vas_id, &map.htab_size); if (result) { DBG("%s:%d: lv1_construct_virtual_address_space failed: %s\n", __func__, __LINE__, ps3_result(result)); goto fail; } result = lv1_select_virtual_address_space(map.vas_id); if (result) { DBG("%s:%d: lv1_select_virtual_address_space failed: %s\n", __func__, __LINE__, ps3_result(result)); goto fail; } *htab_size = map.htab_size; debug_dump_map(&map); return; fail: panic("ps3_mm_vas_create failed"); } /** * ps3_mm_vas_destroy - */ void ps3_mm_vas_destroy(void) { int result; DBG("%s:%d: map.vas_id = %llu\n", __func__, __LINE__, map.vas_id); if (map.vas_id) { result = lv1_select_virtual_address_space(0); BUG_ON(result); result = lv1_destruct_virtual_address_space(map.vas_id); BUG_ON(result); map.vas_id = 0; } } static int ps3_mm_get_repository_highmem(struct mem_region *r) { int result; /* Assume a single highmem region. */ result = ps3_repository_read_highmem_info(0, &r->base, &r->size); if (result) goto zero_region; if (!r->base || !r->size) { result = -1; goto zero_region; } r->offset = r->base - map.rm.size; DBG("%s:%d: Found high region in repository: %llxh %llxh\n", __func__, __LINE__, r->base, r->size); return 0; zero_region: DBG("%s:%d: No high region in repository.\n", __func__, __LINE__); r->size = r->base = r->offset = 0; return result; } static int ps3_mm_set_repository_highmem(const struct mem_region *r) { /* Assume a single highmem region. */ return r ? ps3_repository_write_highmem_info(0, r->base, r->size) : ps3_repository_write_highmem_info(0, 0, 0); } /** * ps3_mm_region_create - create a memory region in the vas * @r: pointer to a struct mem_region to accept initialized values * @size: requested region size * * This implementation creates the region with the vas large page size. * @size is rounded down to a multiple of the vas large page size. */ static int ps3_mm_region_create(struct mem_region *r, unsigned long size) { int result; u64 muid; r->size = _ALIGN_DOWN(size, 1 << PAGE_SHIFT_16M); DBG("%s:%d requested %lxh\n", __func__, __LINE__, size); DBG("%s:%d actual %llxh\n", __func__, __LINE__, r->size); DBG("%s:%d difference %llxh (%lluMB)\n", __func__, __LINE__, size - r->size, (size - r->size) / 1024 / 1024); if (r->size == 0) { DBG("%s:%d: size == 0\n", __func__, __LINE__); result = -1; goto zero_region; } result = lv1_allocate_memory(r->size, PAGE_SHIFT_16M, 0, ALLOCATE_MEMORY_TRY_ALT_UNIT, &r->base, &muid); if (result || r->base < map.rm.size) { DBG("%s:%d: lv1_allocate_memory failed: %s\n", __func__, __LINE__, ps3_result(result)); goto zero_region; } r->destroy = 1; r->offset = r->base - map.rm.size; return result; zero_region: r->size = r->base = r->offset = 0; return result; } /** * ps3_mm_region_destroy - destroy a memory region * @r: pointer to struct mem_region */ static void ps3_mm_region_destroy(struct mem_region *r) { int result; if (!r->destroy) { pr_info("%s:%d: Not destroying high region: %llxh %llxh\n", __func__, __LINE__, r->base, r->size); return; } DBG("%s:%d: r->base = %llxh\n", __func__, __LINE__, r->base); if (r->base) { result = lv1_release_memory(r->base); BUG_ON(result); r->size = r->base = r->offset = 0; map.total = map.rm.size; } ps3_mm_set_repository_highmem(NULL); } /*============================================================================*/ /* dma routines */ /*============================================================================*/ /** * dma_sb_lpar_to_bus - Translate an lpar address to ioc mapped bus address. * @r: pointer to dma region structure * @lpar_addr: HV lpar address */ static unsigned long dma_sb_lpar_to_bus(struct ps3_dma_region *r, unsigned long lpar_addr) { if (lpar_addr >= map.rm.size) lpar_addr -= map.r1.offset; BUG_ON(lpar_addr < r->offset); BUG_ON(lpar_addr >= r->offset + r->len); return r->bus_addr + lpar_addr - r->offset; } #define dma_dump_region(_a) _dma_dump_region(_a, __func__, __LINE__) static void __maybe_unused _dma_dump_region(const struct ps3_dma_region *r, const char *func, int line) { DBG("%s:%d: dev %llu:%llu\n", func, line, r->dev->bus_id, r->dev->dev_id); DBG("%s:%d: page_size %u\n", func, line, r->page_size); DBG("%s:%d: bus_addr %lxh\n", func, line, r->bus_addr); DBG("%s:%d: len %lxh\n", func, line, r->len); DBG("%s:%d: offset %lxh\n", func, line, r->offset); } /** * dma_chunk - A chunk of dma pages mapped by the io controller. * @region - The dma region that owns this chunk. * @lpar_addr: Starting lpar address of the area to map. * @bus_addr: Starting ioc bus address of the area to map. * @len: Length in bytes of the area to map. * @link: A struct list_head used with struct ps3_dma_region.chunk_list, the * list of all chuncks owned by the region. * * This implementation uses a very simple dma page manager * based on the dma_chunk structure. This scheme assumes * that all drivers use very well behaved dma ops. */ struct dma_chunk { struct ps3_dma_region *region; unsigned long lpar_addr; unsigned long bus_addr; unsigned long len; struct list_head link; unsigned int usage_count; }; #define dma_dump_chunk(_a) _dma_dump_chunk(_a, __func__, __LINE__) static void _dma_dump_chunk (const struct dma_chunk* c, const char* func, int line) { DBG("%s:%d: r.dev %llu:%llu\n", func, line, c->region->dev->bus_id, c->region->dev->dev_id); DBG("%s:%d: r.bus_addr %lxh\n", func, line, c->region->bus_addr); DBG("%s:%d: r.page_size %u\n", func, line, c->region->page_size); DBG("%s:%d: r.len %lxh\n", func, line, c->region->len); DBG("%s:%d: r.offset %lxh\n", func, line, c->region->offset); DBG("%s:%d: c.lpar_addr %lxh\n", func, line, c->lpar_addr); DBG("%s:%d: c.bus_addr %lxh\n", func, line, c->bus_addr); DBG("%s:%d: c.len %lxh\n", func, line, c->len); } static struct dma_chunk * dma_find_chunk(struct ps3_dma_region *r, unsigned long bus_addr, unsigned long len) { struct dma_chunk *c; unsigned long aligned_bus = _ALIGN_DOWN(bus_addr, 1 << r->page_size); unsigned long aligned_len = _ALIGN_UP(len+bus_addr-aligned_bus, 1 << r->page_size); list_for_each_entry(c, &r->chunk_list.head, link) { /* intersection */ if (aligned_bus >= c->bus_addr && aligned_bus + aligned_len <= c->bus_addr + c->len) return c; /* below */ if (aligned_bus + aligned_len <= c->bus_addr) continue; /* above */ if (aligned_bus >= c->bus_addr + c->len) continue; /* we don't handle the multi-chunk case for now */ dma_dump_chunk(c); BUG(); } return NULL; } static struct dma_chunk *dma_find_chunk_lpar(struct ps3_dma_region *r, unsigned long lpar_addr, unsigned long len) { struct dma_chunk *c; unsigned long aligned_lpar = _ALIGN_DOWN(lpar_addr, 1 << r->page_size); unsigned long aligned_len = _ALIGN_UP(len + lpar_addr - aligned_lpar, 1 << r->page_size); list_for_each_entry(c, &r->chunk_list.head, link) { /* intersection */ if (c->lpar_addr <= aligned_lpar && aligned_lpar < c->lpar_addr + c->len) { if (aligned_lpar + aligned_len <= c->lpar_addr + c->len) return c; else { dma_dump_chunk(c); BUG(); } } /* below */ if (aligned_lpar + aligned_len <= c->lpar_addr) { continue; } /* above */ if (c->lpar_addr + c->len <= aligned_lpar) { continue; } } return NULL; } static int dma_sb_free_chunk(struct dma_chunk *c) { int result = 0; if (c->bus_addr) { result = lv1_unmap_device_dma_region(c->region->dev->bus_id, c->region->dev->dev_id, c->bus_addr, c->len); BUG_ON(result); } kfree(c); return result; } static int dma_ioc0_free_chunk(struct dma_chunk *c) { int result = 0; int iopage; unsigned long offset; struct ps3_dma_region *r = c->region; DBG("%s:start\n", __func__); for (iopage = 0; iopage < (c->len >> r->page_size); iopage++) { offset = (1 << r->page_size) * iopage; /* put INVALID entry */ result = lv1_put_iopte(0, c->bus_addr + offset, c->lpar_addr + offset, r->ioid, 0); DBG("%s: bus=%#lx, lpar=%#lx, ioid=%d\n", __func__, c->bus_addr + offset, c->lpar_addr + offset, r->ioid); if (result) { DBG("%s:%d: lv1_put_iopte failed: %s\n", __func__, __LINE__, ps3_result(result)); } } kfree(c); DBG("%s:end\n", __func__); return result; } /** * dma_sb_map_pages - Maps dma pages into the io controller bus address space. * @r: Pointer to a struct ps3_dma_region. * @phys_addr: Starting physical address of the area to map. * @len: Length in bytes of the area to map. * c_out: A pointer to receive an allocated struct dma_chunk for this area. * * This is the lowest level dma mapping routine, and is the one that will * make the HV call to add the pages into the io controller address space. */ static int dma_sb_map_pages(struct ps3_dma_region *r, unsigned long phys_addr, unsigned long len, struct dma_chunk **c_out, u64 iopte_flag) { int result; struct dma_chunk *c; c = kzalloc(sizeof(struct dma_chunk), GFP_ATOMIC); if (!c) { result = -ENOMEM; goto fail_alloc; } c->region = r; c->lpar_addr = ps3_mm_phys_to_lpar(phys_addr); c->bus_addr = dma_sb_lpar_to_bus(r, c->lpar_addr); c->len = len; BUG_ON(iopte_flag != 0xf800000000000000UL); result = lv1_map_device_dma_region(c->region->dev->bus_id, c->region->dev->dev_id, c->lpar_addr, c->bus_addr, c->len, iopte_flag); if (result) { DBG("%s:%d: lv1_map_device_dma_region failed: %s\n", __func__, __LINE__, ps3_result(result)); goto fail_map; } list_add(&c->link, &r->chunk_list.head); *c_out = c; return 0; fail_map: kfree(c); fail_alloc: *c_out = NULL; DBG(" <- %s:%d\n", __func__, __LINE__); return result; } static int dma_ioc0_map_pages(struct ps3_dma_region *r, unsigned long phys_addr, unsigned long len, struct dma_chunk **c_out, u64 iopte_flag) { int result; struct dma_chunk *c, *last; int iopage, pages; unsigned long offset; DBG(KERN_ERR "%s: phy=%#lx, lpar%#lx, len=%#lx\n", __func__, phys_addr, ps3_mm_phys_to_lpar(phys_addr), len); c = kzalloc(sizeof(struct dma_chunk), GFP_ATOMIC); if (!c) { result = -ENOMEM; goto fail_alloc; } c->region = r; c->len = len; c->lpar_addr = ps3_mm_phys_to_lpar(phys_addr); /* allocate IO address */ if (list_empty(&r->chunk_list.head)) { /* first one */ c->bus_addr = r->bus_addr; } else { /* derive from last bus addr*/ last = list_entry(r->chunk_list.head.next, struct dma_chunk, link); c->bus_addr = last->bus_addr + last->len; DBG("%s: last bus=%#lx, len=%#lx\n", __func__, last->bus_addr, last->len); } /* FIXME: check whether length exceeds region size */ /* build ioptes for the area */ pages = len >> r->page_size; DBG("%s: pgsize=%#x len=%#lx pages=%#x iopteflag=%#llx\n", __func__, r->page_size, r->len, pages, iopte_flag); for (iopage = 0; iopage < pages; iopage++) { offset = (1 << r->page_size) * iopage; result = lv1_put_iopte(0, c->bus_addr + offset, c->lpar_addr + offset, r->ioid, iopte_flag); if (result) { pr_warning("%s:%d: lv1_put_iopte failed: %s\n", __func__, __LINE__, ps3_result(result)); goto fail_map; } DBG("%s: pg=%d bus=%#lx, lpar=%#lx, ioid=%#x\n", __func__, iopage, c->bus_addr + offset, c->lpar_addr + offset, r->ioid); } /* be sure that last allocated one is inserted at head */ list_add(&c->link, &r->chunk_list.head); *c_out = c; DBG("%s: end\n", __func__); return 0; fail_map: for (iopage--; 0 <= iopage; iopage--) { lv1_put_iopte(0, c->bus_addr + offset, c->lpar_addr + offset, r->ioid, 0); } kfree(c); fail_alloc: *c_out = NULL; return result; } /** * dma_sb_region_create - Create a device dma region. * @r: Pointer to a struct ps3_dma_region. * * This is the lowest level dma region create routine, and is the one that * will make the HV call to create the region. */ static int dma_sb_region_create(struct ps3_dma_region *r) { int result; u64 bus_addr; DBG(" -> %s:%d:\n", __func__, __LINE__); BUG_ON(!r); if (!r->dev->bus_id) { pr_info("%s:%d: %llu:%llu no dma\n", __func__, __LINE__, r->dev->bus_id, r->dev->dev_id); return 0; } DBG("%s:%u: len = 0x%lx, page_size = %u, offset = 0x%lx\n", __func__, __LINE__, r->len, r->page_size, r->offset); BUG_ON(!r->len); BUG_ON(!r->page_size); BUG_ON(!r->region_ops); INIT_LIST_HEAD(&r->chunk_list.head); spin_lock_init(&r->chunk_list.lock); result = lv1_allocate_device_dma_region(r->dev->bus_id, r->dev->dev_id, roundup_pow_of_two(r->len), r->page_size, r->region_type, &bus_addr); r->bus_addr = bus_addr; if (result) { DBG("%s:%d: lv1_allocate_device_dma_region failed: %s\n", __func__, __LINE__, ps3_result(result)); r->len = r->bus_addr = 0; } return result; } static int dma_ioc0_region_create(struct ps3_dma_region *r) { int result; u64 bus_addr; INIT_LIST_HEAD(&r->chunk_list.head); spin_lock_init(&r->chunk_list.lock); result = lv1_allocate_io_segment(0, r->len, r->page_size, &bus_addr); r->bus_addr = bus_addr; if (result) { DBG("%s:%d: lv1_allocate_io_segment failed: %s\n", __func__, __LINE__, ps3_result(result)); r->len = r->bus_addr = 0; } DBG("%s: len=%#lx, pg=%d, bus=%#lx\n", __func__, r->len, r->page_size, r->bus_addr); return result; } /** * dma_region_free - Free a device dma region. * @r: Pointer to a struct ps3_dma_region. * * This is the lowest level dma region free routine, and is the one that * will make the HV call to free the region. */ static int dma_sb_region_free(struct ps3_dma_region *r) { int result; struct dma_chunk *c; struct dma_chunk *tmp; BUG_ON(!r); if (!r->dev->bus_id) { pr_info("%s:%d: %llu:%llu no dma\n", __func__, __LINE__, r->dev->bus_id, r->dev->dev_id); return 0; } list_for_each_entry_safe(c, tmp, &r->chunk_list.head, link) { list_del(&c->link); dma_sb_free_chunk(c); } result = lv1_free_device_dma_region(r->dev->bus_id, r->dev->dev_id, r->bus_addr); if (result) DBG("%s:%d: lv1_free_device_dma_region failed: %s\n", __func__, __LINE__, ps3_result(result)); r->bus_addr = 0; return result; } static int dma_ioc0_region_free(struct ps3_dma_region *r) { int result; struct dma_chunk *c, *n; DBG("%s: start\n", __func__); list_for_each_entry_safe(c, n, &r->chunk_list.head, link) { list_del(&c->link); dma_ioc0_free_chunk(c); } result = lv1_release_io_segment(0, r->bus_addr); if (result) DBG("%s:%d: lv1_free_device_dma_region failed: %s\n", __func__, __LINE__, ps3_result(result)); r->bus_addr = 0; DBG("%s: end\n", __func__); return result; } /** * dma_sb_map_area - Map an area of memory into a device dma region. * @r: Pointer to a struct ps3_dma_region. * @virt_addr: Starting virtual address of the area to map. * @len: Length in bytes of the area to map. * @bus_addr: A pointer to return the starting ioc bus address of the area to * map. * * This is the common dma mapping routine. */ static int dma_sb_map_area(struct ps3_dma_region *r, unsigned long virt_addr, unsigned long len, dma_addr_t *bus_addr, u64 iopte_flag) { int result; unsigned long flags; struct dma_chunk *c; unsigned long phys_addr = is_kernel_addr(virt_addr) ? __pa(virt_addr) : virt_addr; unsigned long aligned_phys = _ALIGN_DOWN(phys_addr, 1 << r->page_size); unsigned long aligned_len = _ALIGN_UP(len + phys_addr - aligned_phys, 1 << r->page_size); *bus_addr = dma_sb_lpar_to_bus(r, ps3_mm_phys_to_lpar(phys_addr)); if (!USE_DYNAMIC_DMA) { unsigned long lpar_addr = ps3_mm_phys_to_lpar(phys_addr); DBG(" -> %s:%d\n", __func__, __LINE__); DBG("%s:%d virt_addr %lxh\n", __func__, __LINE__, virt_addr); DBG("%s:%d phys_addr %lxh\n", __func__, __LINE__, phys_addr); DBG("%s:%d lpar_addr %lxh\n", __func__, __LINE__, lpar_addr); DBG("%s:%d len %lxh\n", __func__, __LINE__, len); DBG("%s:%d bus_addr %llxh (%lxh)\n", __func__, __LINE__, *bus_addr, len); } spin_lock_irqsave(&r->chunk_list.lock, flags); c = dma_find_chunk(r, *bus_addr, len); if (c) { DBG("%s:%d: reusing mapped chunk", __func__, __LINE__); dma_dump_chunk(c); c->usage_count++; spin_unlock_irqrestore(&r->chunk_list.lock, flags); return 0; } result = dma_sb_map_pages(r, aligned_phys, aligned_len, &c, iopte_flag); if (result) { *bus_addr = 0; DBG("%s:%d: dma_sb_map_pages failed (%d)\n", __func__, __LINE__, result); spin_unlock_irqrestore(&r->chunk_list.lock, flags); return result; } c->usage_count = 1; spin_unlock_irqrestore(&r->chunk_list.lock, flags); return result; } static int dma_ioc0_map_area(struct ps3_dma_region *r, unsigned long virt_addr, unsigned long len, dma_addr_t *bus_addr, u64 iopte_flag) { int result; unsigned long flags; struct dma_chunk *c; unsigned long phys_addr = is_kernel_addr(virt_addr) ? __pa(virt_addr) : virt_addr; unsigned long aligned_phys = _ALIGN_DOWN(phys_addr, 1 << r->page_size); unsigned long aligned_len = _ALIGN_UP(len + phys_addr - aligned_phys, 1 << r->page_size); DBG(KERN_ERR "%s: vaddr=%#lx, len=%#lx\n", __func__, virt_addr, len); DBG(KERN_ERR "%s: ph=%#lx a_ph=%#lx a_l=%#lx\n", __func__, phys_addr, aligned_phys, aligned_len); spin_lock_irqsave(&r->chunk_list.lock, flags); c = dma_find_chunk_lpar(r, ps3_mm_phys_to_lpar(phys_addr), len); if (c) { /* FIXME */ BUG(); *bus_addr = c->bus_addr + phys_addr - aligned_phys; c->usage_count++; spin_unlock_irqrestore(&r->chunk_list.lock, flags); return 0; } result = dma_ioc0_map_pages(r, aligned_phys, aligned_len, &c, iopte_flag); if (result) { *bus_addr = 0; DBG("%s:%d: dma_ioc0_map_pages failed (%d)\n", __func__, __LINE__, result); spin_unlock_irqrestore(&r->chunk_list.lock, flags); return result; } *bus_addr = c->bus_addr + phys_addr - aligned_phys; DBG("%s: va=%#lx pa=%#lx a_pa=%#lx bus=%#llx\n", __func__, virt_addr, phys_addr, aligned_phys, *bus_addr); c->usage_count = 1; spin_unlock_irqrestore(&r->chunk_list.lock, flags); return result; } /** * dma_sb_unmap_area - Unmap an area of memory from a device dma region. * @r: Pointer to a struct ps3_dma_region. * @bus_addr: The starting ioc bus address of the area to unmap. * @len: Length in bytes of the area to unmap. * * This is the common dma unmap routine. */ static int dma_sb_unmap_area(struct ps3_dma_region *r, dma_addr_t bus_addr, unsigned long len) { unsigned long flags; struct dma_chunk *c; spin_lock_irqsave(&r->chunk_list.lock, flags); c = dma_find_chunk(r, bus_addr, len); if (!c) { unsigned long aligned_bus = _ALIGN_DOWN(bus_addr, 1 << r->page_size); unsigned long aligned_len = _ALIGN_UP(len + bus_addr - aligned_bus, 1 << r->page_size); DBG("%s:%d: not found: bus_addr %llxh\n", __func__, __LINE__, bus_addr); DBG("%s:%d: not found: len %lxh\n", __func__, __LINE__, len); DBG("%s:%d: not found: aligned_bus %lxh\n", __func__, __LINE__, aligned_bus); DBG("%s:%d: not found: aligned_len %lxh\n", __func__, __LINE__, aligned_len); BUG(); } c->usage_count--; if (!c->usage_count) { list_del(&c->link); dma_sb_free_chunk(c); } spin_unlock_irqrestore(&r->chunk_list.lock, flags); return 0; } static int dma_ioc0_unmap_area(struct ps3_dma_region *r, dma_addr_t bus_addr, unsigned long len) { unsigned long flags; struct dma_chunk *c; DBG("%s: start a=%#llx l=%#lx\n", __func__, bus_addr, len); spin_lock_irqsave(&r->chunk_list.lock, flags); c = dma_find_chunk(r, bus_addr, len); if (!c) { unsigned long aligned_bus = _ALIGN_DOWN(bus_addr, 1 << r->page_size); unsigned long aligned_len = _ALIGN_UP(len + bus_addr - aligned_bus, 1 << r->page_size); DBG("%s:%d: not found: bus_addr %llxh\n", __func__, __LINE__, bus_addr); DBG("%s:%d: not found: len %lxh\n", __func__, __LINE__, len); DBG("%s:%d: not found: aligned_bus %lxh\n", __func__, __LINE__, aligned_bus); DBG("%s:%d: not found: aligned_len %lxh\n", __func__, __LINE__, aligned_len); BUG(); } c->usage_count--; if (!c->usage_count) { list_del(&c->link); dma_ioc0_free_chunk(c); } spin_unlock_irqrestore(&r->chunk_list.lock, flags); DBG("%s: end\n", __func__); return 0; } /** * dma_sb_region_create_linear - Setup a linear dma mapping for a device. * @r: Pointer to a struct ps3_dma_region. * * This routine creates an HV dma region for the device and maps all available * ram into the io controller bus address space. */ static int dma_sb_region_create_linear(struct ps3_dma_region *r) { int result; unsigned long virt_addr, len; dma_addr_t tmp; if (r->len > 16*1024*1024) { /* FIXME: need proper fix */ /* force 16M dma pages for linear mapping */ if (r->page_size != PS3_DMA_16M) { pr_info("%s:%d: forcing 16M pages for linear map\n", __func__, __LINE__); r->page_size = PS3_DMA_16M; r->len = _ALIGN_UP(r->len, 1 << r->page_size); } } result = dma_sb_region_create(r); BUG_ON(result); if (r->offset < map.rm.size) { /* Map (part of) 1st RAM chunk */ virt_addr = map.rm.base + r->offset; len = map.rm.size - r->offset; if (len > r->len) len = r->len; result = dma_sb_map_area(r, virt_addr, len, &tmp, CBE_IOPTE_PP_W | CBE_IOPTE_PP_R | CBE_IOPTE_SO_RW | CBE_IOPTE_M); BUG_ON(result); } if (r->offset + r->len > map.rm.size) { /* Map (part of) 2nd RAM chunk */ virt_addr = map.rm.size; len = r->len; if (r->offset >= map.rm.size) virt_addr += r->offset - map.rm.size; else len -= map.rm.size - r->offset; result = dma_sb_map_area(r, virt_addr, len, &tmp, CBE_IOPTE_PP_W | CBE_IOPTE_PP_R | CBE_IOPTE_SO_RW | CBE_IOPTE_M); BUG_ON(result); } return result; } /** * dma_sb_region_free_linear - Free a linear dma mapping for a device. * @r: Pointer to a struct ps3_dma_region. * * This routine will unmap all mapped areas and free the HV dma region. */ static int dma_sb_region_free_linear(struct ps3_dma_region *r) { int result; dma_addr_t bus_addr; unsigned long len, lpar_addr; if (r->offset < map.rm.size) { /* Unmap (part of) 1st RAM chunk */ lpar_addr = map.rm.base + r->offset; len = map.rm.size - r->offset; if (len > r->len) len = r->len; bus_addr = dma_sb_lpar_to_bus(r, lpar_addr); result = dma_sb_unmap_area(r, bus_addr, len); BUG_ON(result); } if (r->offset + r->len > map.rm.size) { /* Unmap (part of) 2nd RAM chunk */ lpar_addr = map.r1.base; len = r->len; if (r->offset >= map.rm.size) lpar_addr += r->offset - map.rm.size; else len -= map.rm.size - r->offset; bus_addr = dma_sb_lpar_to_bus(r, lpar_addr); result = dma_sb_unmap_area(r, bus_addr, len); BUG_ON(result); } result = dma_sb_region_free(r); BUG_ON(result); return result; } /** * dma_sb_map_area_linear - Map an area of memory into a device dma region. * @r: Pointer to a struct ps3_dma_region. * @virt_addr: Starting virtual address of the area to map. * @len: Length in bytes of the area to map. * @bus_addr: A pointer to return the starting ioc bus address of the area to * map. * * This routine just returns the corresponding bus address. Actual mapping * occurs in dma_region_create_linear(). */ static int dma_sb_map_area_linear(struct ps3_dma_region *r, unsigned long virt_addr, unsigned long len, dma_addr_t *bus_addr, u64 iopte_flag) { unsigned long phys_addr = is_kernel_addr(virt_addr) ? __pa(virt_addr) : virt_addr; *bus_addr = dma_sb_lpar_to_bus(r, ps3_mm_phys_to_lpar(phys_addr)); return 0; } /** * dma_unmap_area_linear - Unmap an area of memory from a device dma region. * @r: Pointer to a struct ps3_dma_region. * @bus_addr: The starting ioc bus address of the area to unmap. * @len: Length in bytes of the area to unmap. * * This routine does nothing. Unmapping occurs in dma_sb_region_free_linear(). */ static int dma_sb_unmap_area_linear(struct ps3_dma_region *r, dma_addr_t bus_addr, unsigned long len) { return 0; }; static const struct ps3_dma_region_ops ps3_dma_sb_region_ops = { .create = dma_sb_region_create, .free = dma_sb_region_free, .map = dma_sb_map_area, .unmap = dma_sb_unmap_area }; static const struct ps3_dma_region_ops ps3_dma_sb_region_linear_ops = { .create = dma_sb_region_create_linear, .free = dma_sb_region_free_linear, .map = dma_sb_map_area_linear, .unmap = dma_sb_unmap_area_linear }; static const struct ps3_dma_region_ops ps3_dma_ioc0_region_ops = { .create = dma_ioc0_region_create, .free = dma_ioc0_region_free, .map = dma_ioc0_map_area, .unmap = dma_ioc0_unmap_area }; int ps3_dma_region_init(struct ps3_system_bus_device *dev, struct ps3_dma_region *r, enum ps3_dma_page_size page_size, enum ps3_dma_region_type region_type, void *addr, unsigned long len) { unsigned long lpar_addr; lpar_addr = addr ? ps3_mm_phys_to_lpar(__pa(addr)) : 0; r->dev = dev; r->page_size = page_size; r->region_type = region_type; r->offset = lpar_addr; if (r->offset >= map.rm.size) r->offset -= map.r1.offset; r->len = len ? len : _ALIGN_UP(map.total, 1 << r->page_size); switch (dev->dev_type) { case PS3_DEVICE_TYPE_SB: r->region_ops = (USE_DYNAMIC_DMA) ? &ps3_dma_sb_region_ops : &ps3_dma_sb_region_linear_ops; break; case PS3_DEVICE_TYPE_IOC0: r->region_ops = &ps3_dma_ioc0_region_ops; break; default: BUG(); return -EINVAL; } return 0; } EXPORT_SYMBOL(ps3_dma_region_init); int ps3_dma_region_create(struct ps3_dma_region *r) { BUG_ON(!r); BUG_ON(!r->region_ops); BUG_ON(!r->region_ops->create); return r->region_ops->create(r); } EXPORT_SYMBOL(ps3_dma_region_create); int ps3_dma_region_free(struct ps3_dma_region *r) { BUG_ON(!r); BUG_ON(!r->region_ops); BUG_ON(!r->region_ops->free); return r->region_ops->free(r); } EXPORT_SYMBOL(ps3_dma_region_free); int ps3_dma_map(struct ps3_dma_region *r, unsigned long virt_addr, unsigned long len, dma_addr_t *bus_addr, u64 iopte_flag) { return r->region_ops->map(r, virt_addr, len, bus_addr, iopte_flag); } int ps3_dma_unmap(struct ps3_dma_region *r, dma_addr_t bus_addr, unsigned long len) { return r->region_ops->unmap(r, bus_addr, len); } /*============================================================================*/ /* system startup routines */ /*============================================================================*/ /** * ps3_mm_init - initialize the address space state variables */ void __init ps3_mm_init(void) { int result; DBG(" -> %s:%d\n", __func__, __LINE__); result = ps3_repository_read_mm_info(&map.rm.base, &map.rm.size, &map.total); if (result) panic("ps3_repository_read_mm_info() failed"); map.rm.offset = map.rm.base; map.vas_id = map.htab_size = 0; /* this implementation assumes map.rm.base is zero */ BUG_ON(map.rm.base); BUG_ON(!map.rm.size); /* Check if we got the highmem region from an earlier boot step */ if (ps3_mm_get_repository_highmem(&map.r1)) { result = ps3_mm_region_create(&map.r1, map.total - map.rm.size); if (!result) ps3_mm_set_repository_highmem(&map.r1); } /* correct map.total for the real total amount of memory we use */ map.total = map.rm.size + map.r1.size; if (!map.r1.size) { DBG("%s:%d: No highmem region found\n", __func__, __LINE__); } else { DBG("%s:%d: Adding highmem region: %llxh %llxh\n", __func__, __LINE__, map.rm.size, map.total - map.rm.size); memblock_add(map.rm.size, map.total - map.rm.size); } DBG(" <- %s:%d\n", __func__, __LINE__); } /** * ps3_mm_shutdown - final cleanup of address space */ void ps3_mm_shutdown(void) { ps3_mm_region_destroy(&map.r1); } |