/* * QEMU S390 bootmap interpreter * * Copyright (c) 2009 Alexander Graf * * This work is licensed under the terms of the GNU GPL, version 2 or (at * your option) any later version. See the COPYING file in the top-level * directory. */ #include "s390-ccw.h" #include "bootmap.h" #include "virtio.h" #ifdef DEBUG /* #define DEBUG_FALLBACK */ #endif #ifdef DEBUG_FALLBACK #define dputs(txt) \ do { sclp_print("zipl: " txt); } while (0) #else #define dputs(fmt, ...) \ do { } while (0) #endif /* Scratch space */ static uint8_t sec[MAX_SECTOR_SIZE*4] __attribute__((__aligned__(PAGE_SIZE))); typedef struct ResetInfo { uint32_t ipl_mask; uint32_t ipl_addr; uint32_t ipl_continue; } ResetInfo; ResetInfo save; static void jump_to_IPL_2(void) { ResetInfo *current = 0; void (*ipl)(void) = (void *) (uint64_t) current->ipl_continue; debug_print_addr("set IPL addr to", ipl); /* Ensure the guest output starts fresh */ sclp_print("\n"); *current = save; ipl(); /* should not return */ } static void jump_to_IPL_code(uint64_t address) { /* * The IPL PSW is at address 0. We also must not overwrite the * content of non-BIOS memory after we loaded the guest, so we * save the original content and restore it in jump_to_IPL_2. */ ResetInfo *current = 0; save = *current; current->ipl_addr = (uint32_t) (uint64_t) &jump_to_IPL_2; current->ipl_continue = address & 0x7fffffff; /* * HACK ALERT. * We use the load normal reset to keep r15 unchanged. jump_to_IPL_2 * can then use r15 as its stack pointer. */ asm volatile("lghi 1,1\n\t" "diag 1,1,0x308\n\t" : : : "1", "memory"); virtio_panic("\n! IPL returns !\n"); } /*********************************************************************** * IPL an ECKD DASD (CDL or LDL/CMS format) */ static unsigned char _bprs[8*1024]; /* guessed "max" ECKD sector size */ const int max_bprs_entries = sizeof(_bprs) / sizeof(ExtEckdBlockPtr); static bool eckd_valid_address(BootMapPointer *p) { const uint64_t cylinder = p->eckd.cylinder + ((p->eckd.head & 0xfff0) << 12); const uint64_t head = p->eckd.head & 0x000f; if (head >= virtio_get_heads() || p->eckd.sector > virtio_get_sectors() || p->eckd.sector <= 0) { return false; } if (!virtio_guessed_disk_nature() && cylinder >= virtio_get_cylinders()) { return false; } return true; } static block_number_t eckd_block_num(BootMapPointer *p) { const uint64_t sectors = virtio_get_sectors(); const uint64_t heads = virtio_get_heads(); const uint64_t cylinder = p->eckd.cylinder + ((p->eckd.head & 0xfff0) << 12); const uint64_t head = p->eckd.head & 0x000f; const block_number_t block = sectors * heads * cylinder + sectors * head + p->eckd.sector - 1; /* block nr starts with zero */ return block; } static block_number_t load_eckd_segments(block_number_t blk, uint64_t *address) { block_number_t block_nr; int j, rc; BootMapPointer *bprs = (void *)_bprs; bool more_data; memset(_bprs, FREE_SPACE_FILLER, sizeof(_bprs)); read_block(blk, bprs, "BPRS read failed"); do { more_data = false; for (j = 0;; j++) { block_nr = eckd_block_num((void *)&(bprs[j].xeckd)); if (is_null_block_number(block_nr)) { /* end of chunk */ break; } /* we need the updated blockno for the next indirect entry * in the chain, but don't want to advance address */ if (j == (max_bprs_entries - 1)) { break; } IPL_assert(block_size_ok(bprs[j].xeckd.bptr.size), "bad chunk block size"); IPL_assert(eckd_valid_address(&bprs[j]), "bad chunk ECKD addr"); if ((bprs[j].xeckd.bptr.count == 0) && unused_space(&(bprs[j+1]), sizeof(EckdBlockPtr))) { /* This is a "continue" pointer. * This ptr should be the last one in the current * script section. * I.e. the next ptr must point to the unused memory area */ memset(_bprs, FREE_SPACE_FILLER, sizeof(_bprs)); read_block(block_nr, bprs, "BPRS continuation read failed"); more_data = true; break; } /* Load (count+1) blocks of code at (block_nr) * to memory (address). */ rc = virtio_read_many(block_nr, (void *)(*address), bprs[j].xeckd.bptr.count+1); IPL_assert(rc == 0, "code chunk read failed"); *address += (bprs[j].xeckd.bptr.count+1) * virtio_get_block_size(); } } while (more_data); return block_nr; } static void run_eckd_boot_script(block_number_t mbr_block_nr) { int i; block_number_t block_nr; uint64_t address; ScsiMbr *scsi_mbr = (void *)sec; BootMapScript *bms = (void *)sec; memset(sec, FREE_SPACE_FILLER, sizeof(sec)); read_block(mbr_block_nr, sec, "Cannot read MBR"); block_nr = eckd_block_num((void *)&(scsi_mbr->blockptr)); memset(sec, FREE_SPACE_FILLER, sizeof(sec)); read_block(block_nr, sec, "Cannot read Boot Map Script"); for (i = 0; bms->entry[i].type == BOOT_SCRIPT_LOAD; i++) { address = bms->entry[i].address.load_address; block_nr = eckd_block_num(&(bms->entry[i].blkptr)); do { block_nr = load_eckd_segments(block_nr, &address); } while (block_nr != -1); } IPL_assert(bms->entry[i].type == BOOT_SCRIPT_EXEC, "Unknown script entry type"); jump_to_IPL_code(bms->entry[i].address.load_address); /* no return */ } static void ipl_eckd(void) { XEckdMbr *mbr; Ipl2 *ipl2 = (void *)sec; IplVolumeLabel *vlbl = (void *)sec; block_number_t block_nr; sclp_print("Using ECKD scheme.\n"); if (virtio_guessed_disk_nature()) { sclp_print("Using guessed DASD geometry.\n"); virtio_assume_eckd(); } /* we have just read the block #0 and recognized it as "IPL1" */ memset(sec, FREE_SPACE_FILLER, sizeof(sec)); read_block(1, ipl2, "Cannot read IPL2 record at block 1"); IPL_assert(magic_match(ipl2, IPL2_MAGIC), "No IPL2 record"); mbr = &ipl2->u.x.mbr; IPL_assert(magic_match(mbr, ZIPL_MAGIC), "No zIPL section in IPL2 record."); IPL_assert(block_size_ok(mbr->blockptr.xeckd.bptr.size), "Bad block size in zIPL section of IPL2 record."); IPL_assert(mbr->dev_type == DEV_TYPE_ECKD, "Non-ECKD device type in zIPL section of IPL2 record."); /* save pointer to Boot Script */ block_nr = eckd_block_num((void *)&(mbr->blockptr)); memset(sec, FREE_SPACE_FILLER, sizeof(sec)); read_block(2, vlbl, "Cannot read Volume Label at block 2"); IPL_assert(magic_match(vlbl->key, VOL1_MAGIC), "Invalid magic of volume label block"); IPL_assert(magic_match(vlbl->f.key, VOL1_MAGIC), "Invalid magic of volser block"); print_volser(vlbl->f.volser); run_eckd_boot_script(block_nr); /* no return */ } /*********************************************************************** * IPL a SCSI disk */ static void zipl_load_segment(ComponentEntry *entry) { const int max_entries = (MAX_SECTOR_SIZE / sizeof(ScsiBlockPtr)); ScsiBlockPtr *bprs = (void *)sec; const int bprs_size = sizeof(sec); block_number_t blockno; uint64_t address; int i; char err_msg[] = "zIPL failed to read BPRS at 0xZZZZZZZZZZZZZZZZ"; char *blk_no = &err_msg[30]; /* where to print blockno in (those ZZs) */ blockno = entry->data.blockno; address = entry->load_address; debug_print_int("loading segment at block", blockno); debug_print_int("addr", address); do { memset(bprs, FREE_SPACE_FILLER, bprs_size); fill_hex_val(blk_no, &blockno, sizeof(blockno)); read_block(blockno, bprs, err_msg); for (i = 0;; i++) { uint64_t *cur_desc = (void *)&bprs[i]; blockno = bprs[i].blockno; if (!blockno) { break; } /* we need the updated blockno for the next indirect entry in the chain, but don't want to advance address */ if (i == (max_entries - 1)) { break; } if (bprs[i].blockct == 0 && unused_space(&bprs[i + 1], sizeof(ScsiBlockPtr))) { /* This is a "continue" pointer. * This ptr is the last one in the current script section. * I.e. the next ptr must point to the unused memory area. * The blockno is not zero, so the upper loop must continue * reading next section of BPRS. */ break; } address = virtio_load_direct(cur_desc[0], cur_desc[1], 0, (void *)address); IPL_assert(address != -1, "zIPL load segment failed"); } } while (blockno); } /* Run a zipl program */ static void zipl_run(ScsiBlockPtr *pte) { ComponentHeader *header; ComponentEntry *entry; uint8_t tmp_sec[MAX_SECTOR_SIZE]; read_block(pte->blockno, tmp_sec, "Cannot read header"); header = (ComponentHeader *)tmp_sec; IPL_assert(magic_match(tmp_sec, ZIPL_MAGIC), "No zIPL magic"); IPL_assert(header->type == ZIPL_COMP_HEADER_IPL, "Bad header type"); dputs("start loading images\n"); /* Load image(s) into RAM */ entry = (ComponentEntry *)(&header[1]); while (entry->component_type == ZIPL_COMP_ENTRY_LOAD) { zipl_load_segment(entry); entry++; IPL_assert((uint8_t *)(&entry[1]) <= (tmp_sec + MAX_SECTOR_SIZE), "Wrong entry value"); } IPL_assert(entry->component_type == ZIPL_COMP_ENTRY_EXEC, "No EXEC entry"); /* should not return */ jump_to_IPL_code(entry->load_address); } static void ipl_scsi(void) { ScsiMbr *mbr = (void *)sec; uint8_t *ns, *ns_end; int program_table_entries = 0; const int pte_len = sizeof(ScsiBlockPtr); ScsiBlockPtr *prog_table_entry; /* The 0-th block (MBR) was already read into sec[] */ sclp_print("Using SCSI scheme.\n"); debug_print_int("program table", mbr->blockptr.blockno); /* Parse the program table */ read_block(mbr->blockptr.blockno, sec, "Error reading Program Table"); IPL_assert(magic_match(sec, ZIPL_MAGIC), "No zIPL magic"); ns_end = sec + virtio_get_block_size(); for (ns = (sec + pte_len); (ns + pte_len) < ns_end; ns++) { prog_table_entry = (ScsiBlockPtr *)ns; if (!prog_table_entry->blockno) { break; } program_table_entries++; } debug_print_int("program table entries", program_table_entries); IPL_assert(program_table_entries != 0, "Empty Program Table"); /* Run the default entry */ prog_table_entry = (ScsiBlockPtr *)(sec + pte_len); zipl_run(prog_table_entry); /* no return */ } /*********************************************************************** * IPL starts here */ void zipl_load(void) { ScsiMbr *mbr = (void *)sec; /* Grab the MBR */ memset(sec, FREE_SPACE_FILLER, sizeof(sec)); read_block(0, mbr, "Cannot read block 0"); dputs("checking magic\n"); if (magic_match(mbr->magic, ZIPL_MAGIC)) { ipl_scsi(); /* no return */ } if (magic_match(mbr->magic, IPL1_MAGIC)) { ipl_eckd(); /* CDL ECKD; no return */ } virtio_panic("\n* invalid MBR magic *\n"); }