/* $NetBSD: machdep.c,v 1.21 2023/12/20 14:12:25 thorpej Exp $ */ /* * Copyright 2001, 2002 Wasabi Systems, Inc. * All rights reserved. * * Written by Jason R. Thorpe and Simon Burge for Wasabi Systems, Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed for the NetBSD Project by * Wasabi Systems, Inc. * 4. The name of Wasabi Systems, Inc. may not be used to endorse * or promote products derived from this software without specific prior * written permission. * * THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL WASABI SYSTEMS, INC * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ /* * Copyright (c) 1988 University of Utah. * Copyright (c) 1992, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department, The Mach Operating System project at * Carnegie-Mellon University and Ralph Campbell. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)machdep.c 8.3 (Berkeley) 1/12/94 * from: Utah Hdr: machdep.c 1.63 91/04/24 */ #include __KERNEL_RCSID(0, "$NetBSD: machdep.c,v 1.21 2023/12/20 14:12:25 thorpej Exp $"); #define __INTR_PRIVATE #include "opt_multiprocessor.h" #include "opt_ddb.h" #include "opt_com.h" #include "opt_execfmt.h" #include "opt_memsize.h" #include "rmixl_pcix.h" #include "rmixl_pcie.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ksyms.h" #if NKSYMS || defined(DDB) || defined(LKM) #include #include #endif #include #include #include #include #include "com.h" #if NCOM == 0 #error no serial console #endif #include #include #include #include #include #include #include #include #include #include #ifdef MACHDEP_DEBUG int machdep_debug=MACHDEP_DEBUG; # define DPRINTF(x) do { if (machdep_debug) printf x ; } while(0) #else # define DPRINTF(x) #endif #ifndef CONSFREQ # define CONSFREQ 66000000 #endif #ifndef CONSPEED # define CONSPEED 38400 #endif #ifndef CONMODE # define CONMODE ((TTYDEF_CFLAG & ~(CSIZE | PARENB)) | CS8) #endif #ifndef CONSADDR # define CONSADDR RMIXL_IO_DEV_UART_1 #endif int comcnfreq = CONSFREQ; int comcnspeed = CONSPEED; tcflag_t comcnmode = CONMODE; bus_addr_t comcnaddr = (bus_addr_t)CONSADDR; struct rmixl_config rmixl_configuration; /* * array of tested firmware versions * if you find new ones and they work * please add them */ typedef struct rmiclfw_psb_id { uint64_t psb_version; rmixlfw_psb_type_t psb_type; } rmiclfw_psb_id_t; static rmiclfw_psb_id_t rmiclfw_psb_id[] = { { 0x4958d4fb00000056ULL, PSB_TYPE_RMI }, { 0x4aacdb6a00000056ULL, PSB_TYPE_RMI }, { 0x4b67d03200000056ULL, PSB_TYPE_RMI }, { 0x4c17058b00000056ULL, PSB_TYPE_RMI }, { 0x49a5a8fa00000056ULL, PSB_TYPE_DELL }, { 0x4b8ead3100000056ULL, PSB_TYPE_DELL }, }; #define RMICLFW_PSB_VERSIONS_LEN \ (sizeof(rmiclfw_psb_id)/sizeof(rmiclfw_psb_id[0])) /* * storage for fixed extent used to allocate physical address regions * because extent(9) start and end values are u_long, they are only * 32 bits on a 32 bit kernel, which is insuffucuent since XLS physical * address is 40 bits wide. So the "physaddr" map stores regions * in units of megabytes. */ static u_long rmixl_physaddr_storage[ EXTENT_FIXED_STORAGE_SIZE(32)/sizeof(u_long) ]; /* Maps for VM objects. */ struct vm_map *phys_map = NULL; int netboot; /* Are we netbooting? */ phys_ram_seg_t mem_clusters[VM_PHYSSEG_MAX]; u_quad_t mem_cluster_maxaddr; u_int mem_cluster_cnt; void configure(void); void mach_init(int, int32_t *, void *, int64_t); static uint64_t rmixlfw_init(int64_t); static uint64_t mem_clusters_init(rmixlfw_mmap_t *, rmixlfw_mmap_t *); static void __attribute__((__noreturn__)) rmixl_reset(void); static void rmixl_physaddr_init(void); static u_int ram_seg_resv(phys_ram_seg_t *, u_int, u_quad_t, u_quad_t); void rmixlfw_mmap_print(rmixlfw_mmap_t *); #ifdef MULTIPROCESSOR static bool rmixl_fixup_cop0_oscratch(int32_t, uint32_t [2], void *); void rmixl_get_wakeup_info(struct rmixl_config *); #ifdef MACHDEP_DEBUG static void rmixl_wakeup_info_print(volatile rmixlfw_cpu_wakeup_info_t *); #endif /* MACHDEP_DEBUG */ #endif /* MULTIPROCESSOR */ static void rmixl_fixup_curcpu(void); /* * Do all the stuff that locore normally does before calling main(). */ void mach_init(int argc, int32_t *argv, void *envp, int64_t infop) { struct rmixl_config *rcp = &rmixl_configuration; void *kernend; uint64_t memsize; extern char edata[], end[]; rmixl_pcr_init_core(); /* * Clear the BSS segment. */ kernend = (void *)mips_round_page(end); memset(edata, 0, (char *)kernend - edata); /* * Set up the exception vectors and CPU-specific function * vectors early on. We need the wbflush() vector set up * before comcnattach() is called (or at least before the * first printf() after that is called). * Also clears the I+D caches. * * specify chip-specific EIRR/EIMR based spl functions */ #ifdef MULTIPROCESSOR mips_vector_init(&rmixl_splsw, true); #else mips_vector_init(&rmixl_splsw, false); #endif /* mips_vector_init initialized mips_options */ cpu_setmodel("%s", mips_options.mips_cpu->cpu_name); /* get system info from firmware */ memsize = rmixlfw_init(infop); uvm_md_init(); physmem = btoc(memsize); rmixl_obio_eb_bus_mem_init(&rcp->rc_obio_eb_memt, rcp); #if NCOM > 0 rmixl_com_cnattach(comcnaddr, comcnspeed, comcnfreq, COM_TYPE_NORMAL, comcnmode); #endif printf("\nNetBSD/rmixl\n"); printf("memsize = %#"PRIx64"\n", memsize); #ifdef MEMLIMIT printf("memlimit = %#"PRIx64"\n", (uint64_t)MEMLIMIT); #endif #if defined(MULTIPROCESSOR) && defined(MACHDEP_DEBUG) rmixl_wakeup_info_print(rcp->rc_cpu_wakeup_info); rmixl_wakeup_info_print(rcp->rc_cpu_wakeup_info + 1); printf("cpu_wakeup_info %p, cpu_wakeup_end %p\n", rcp->rc_cpu_wakeup_info, rcp->rc_cpu_wakeup_end); printf("userapp_cpu_map: %#"PRIx64"\n", rcp->rc_psb_info.userapp_cpu_map); printf("wakeup: %#"PRIx64"\n", rcp->rc_psb_info.wakeup); { register_t sp; asm volatile ("move %0, $sp\n" : "=r"(sp)); printf("sp: %#"PRIx64"\n", sp); } #endif rmixl_physaddr_init(); /* * Obtain the cpu frequency * Compute the number of ticks for hz. * Compute the delay divisor. * Double the Hz if this CPU runs at twice the * external/cp0-count frequency */ curcpu()->ci_cpu_freq = rcp->rc_psb_info.cpu_frequency; curcpu()->ci_cctr_freq = curcpu()->ci_cpu_freq; curcpu()->ci_cycles_per_hz = (curcpu()->ci_cpu_freq + hz / 2) / hz; curcpu()->ci_divisor_delay = ((curcpu()->ci_cpu_freq + 500000) / 1000000); if (mips_options.mips_cpu_flags & CPU_MIPS_DOUBLE_COUNT) curcpu()->ci_cpu_freq *= 2; /* * Look at arguments passed to us and compute boothowto. * - rmixl firmware gives us a 32 bit argv[i], so adapt * by forcing sign extension in cast to (char *) */ boothowto = RB_AUTOBOOT; for (int i = 1; i < argc; i++) { for (char *cp = (char *)(intptr_t)argv[i]; *cp; cp++) { int howto; /* Ignore superfluous '-', if there is one */ if (*cp == '-') continue; howto = 0; BOOT_FLAG(*cp, howto); if (howto != 0) boothowto |= howto; #ifdef DIAGNOSTIC else printf("bootflag '%c' not recognised\n", *cp); #endif } } #ifdef DIAGNOSTIC printf("boothowto %#x\n", boothowto); #endif /* * Reserve pages from the VM system. */ /* reserve 0..start..kernend pages */ mem_cluster_cnt = ram_seg_resv(mem_clusters, mem_cluster_cnt, 0, round_page(MIPS_KSEG0_TO_PHYS(kernend))); /* reserve reset exception vector page */ /* should never be in our clusters anyway... */ mem_cluster_cnt = ram_seg_resv(mem_clusters, mem_cluster_cnt, 0x1FC00000, 0x1FC00000+NBPG); #ifdef MULTIPROCEESOR /* reserve the cpu_wakeup_info area */ mem_cluster_cnt = ram_seg_resv(mem_clusters, mem_cluster_cnt, (u_quad_t)trunc_page(rcp->rc_cpu_wakeup_info), (u_quad_t)round_page(rcp->rc_cpu_wakeup_end)); #endif #ifdef MEMLIMIT /* reserve everything >= MEMLIMIT */ mem_cluster_cnt = ram_seg_resv(mem_clusters, mem_cluster_cnt, (u_quad_t)MEMLIMIT, (u_quad_t)~0); #endif /* get maximum RAM address from the VM clusters */ mem_cluster_maxaddr = 0; for (u_int i=0; i < mem_cluster_cnt; i++) { u_quad_t tmp = round_page( mem_clusters[i].start + mem_clusters[i].size); if (tmp > mem_cluster_maxaddr) mem_cluster_maxaddr = tmp; } DPRINTF(("mem_cluster_maxaddr %#"PRIx64"\n", mem_cluster_maxaddr)); /* * Load mem_clusters[] into the VM system. */ mips_page_physload(MIPS_KSEG0_START, (vaddr_t) kernend, mem_clusters, mem_cluster_cnt, NULL, 0); /* * Initialize error message buffer (at end of core). */ mips_init_msgbuf(); pmap_bootstrap(); /* * Allocate uarea page for lwp0 and set it. */ mips_init_lwp0_uarea(); #if defined(DDB) if (boothowto & RB_KDB) Debugger(); #endif /* * store (cpu#0) curcpu in COP0 OSSCRATCH0 * used in exception vector */ __asm __volatile("dmtc0 %0,$%1" :: "r"(&cpu_info_store), "n"(MIPS_COP_0_OSSCRATCH)); #ifdef MULTIPROCESSOR mips_fixup_exceptions(rmixl_fixup_cop0_oscratch, NULL); #endif rmixl_fixup_curcpu(); } /* * set up Processor Control Regs for this core */ void rmixl_pcr_init_core(void) { uint32_t r; #ifdef MULTIPROCESSOR rmixl_mtcr(RMIXL_PCR_MMU_SETUP, __BITS(2,0)); /* enable MMU clock gating */ /* 4 threads active -- why needed if Global? */ /* enable global TLB mode */ #else rmixl_mtcr(RMIXL_PCR_THREADEN, 1); /* disable all threads except #0 */ rmixl_mtcr(RMIXL_PCR_MMU_SETUP, 0); /* enable MMU clock gating */ /* set single MMU Thread Mode */ /* TLB is partitioned (1 partition) */ #endif r = rmixl_mfcr(RMIXL_PCR_L1D_CONFIG0); r &= ~__BIT(14); /* disable Unaligned Access */ rmixl_mtcr(RMIXL_PCR_L1D_CONFIG0, r); #if defined(DDB) && defined(MIPS_DDB_WATCH) /* * clear IEU_DEFEATURE[DBE] * this enables COP0 watchpoint to trigger T_WATCH exception * instead of signaling JTAG. */ r = rmixl_mfcr(RMIXL_PCR_IEU_DEFEATURE); r &= ~__BIT(7); rmixl_mtcr(RMIXL_PCR_IEU_DEFEATURE, r); #endif } #ifdef MULTIPROCESSOR static bool rmixl_fixup_cop0_oscratch(int32_t load_addr, uint32_t new_insns[2], void *arg) { size_t offset = load_addr - (intptr_t)&cpu_info_store; KASSERT(MIPS_KSEG0_P(load_addr)); KASSERT(offset < sizeof(struct cpu_info)); /* * Fixup this direct load cpu_info_store to actually get the current * CPU's cpu_info from COP0 OSSCRATCH0 and then fix the load to be * relative from the start of struct cpu_info. */ /* [0] = [d]mfc0 rX, $22 (OSScratch) */ new_insns[0] = (020 << 26) #ifdef _LP64 | (1 << 21) /* double move */ #endif | (new_insns[0] & 0x001f0000) | (MIPS_COP_0_OSSCRATCH << 11) | (0 << 0); /* [1] = [ls][dw] rX, offset(rX) */ new_insns[1] = (new_insns[1] & 0xffff0000) | offset; return true; } #endif /* MULTIPROCESSOR */ /* * The following changes all lX rN, L_CPU(MIPS_CURLWP) [curlwp->l_cpu] * to [d]mfc0 rN, $22 [MIPS_COP_0_OSSCRATCH] * * the mfc0 is 3 cycles shorter than the load. */ #define LOAD_CURCPU_0 ((MIPS_CURLWP_REG << 21) | offsetof(lwp_t, l_cpu)) #define MFC0_CURCPU_0 ((OP_COP0 << 26) | (MIPS_COP_0_OSSCRATCH << 11)) #ifdef _LP64 #define LOAD_CURCPU ((uint32_t)(OP_LD << 26) | LOAD_CURCPU_0) #define MFC0_CURCPU ((uint32_t)(OP_DMF << 21) | MFC0_CURCPU_0) #else #define LOAD_CURCPU ((uint32_t)(OP_LW << 26) | LOAD_CURCPU_0) #define MFC0_CURCPU ((uint32_t)(OP_MF << 21) | MFC0_CURCPU_0) #endif #define LOAD_CURCPU_MASK 0xffe0ffff static void rmixl_fixup_curcpu(void) { extern uint32_t _ftext[]; extern uint32_t _etext[]; for (uint32_t *insnp = _ftext; insnp < _etext; insnp++) { const uint32_t insn = *insnp; if (__predict_false((insn & LOAD_CURCPU_MASK) == LOAD_CURCPU)) { /* * Since the register to loaded is located in bits * 16-20 for the mfc0 and the load instruction we can * just change the instruction bits around it. */ *insnp = insn ^ LOAD_CURCPU ^ MFC0_CURCPU; mips_icache_sync_range((vaddr_t)insnp, 4); } } } /* * ram_seg_resv - cut reserved regions out of segs, fragmenting as needed * * we simply build a new table of segs, then copy it back over the given one * this is inefficient but simple and called only a few times * * note: 'last' here means 1st addr past the end of the segment (start+size) */ static u_int ram_seg_resv(phys_ram_seg_t *segs, u_int nsegs, u_quad_t resv_first, u_quad_t resv_last) { u_quad_t first, last; int new_nsegs=0; int resv_flag; phys_ram_seg_t new_segs[VM_PHYSSEG_MAX]; for (u_int i=0; i < nsegs; i++) { resv_flag = 0; first = trunc_page(segs[i].start); last = round_page(segs[i].start + segs[i].size); KASSERT(new_nsegs < VM_PHYSSEG_MAX); if ((resv_first <= first) && (resv_last >= last)) { /* whole segment is resverved */ continue; } if ((resv_first > first) && (resv_first < last)) { u_quad_t new_last; /* * reserved start in segment * salvage the leading fragment */ resv_flag = 1; new_last = last - (last - resv_first); KASSERT (new_last > first); new_segs[new_nsegs].start = first; new_segs[new_nsegs].size = new_last - first; new_nsegs++; } if ((resv_last > first) && (resv_last < last)) { u_quad_t new_first; /* * reserved end in segment * salvage the trailing fragment */ resv_flag = 1; new_first = first + (resv_last - first); KASSERT (last > (new_first + NBPG)); new_segs[new_nsegs].start = new_first; new_segs[new_nsegs].size = last - new_first; new_nsegs++; } if (resv_flag == 0) { /* * nothing reserved here, take it all */ new_segs[new_nsegs].start = first; new_segs[new_nsegs].size = last - first; new_nsegs++; } } memcpy(segs, new_segs, sizeof(new_segs)); return new_nsegs; } /* * create an extent for physical address space * these are in units of MB for sake of compression (for sake of 32 bit kernels) * allocate the regions where we have known functions (DRAM, IO, etc) * what remains can be allocated as needed for other stuff * e.g. to configure BARs that are not already initialized and enabled. */ static void rmixl_physaddr_init(void) { struct extent *ext; unsigned long start = 0UL; unsigned long end = (__BIT(40) / (1024 * 1024)) -1; u_long base; u_long size; uint32_t r; ext = extent_create("physaddr", start, end, (void *)rmixl_physaddr_storage, sizeof(rmixl_physaddr_storage), EX_NOWAIT | EX_NOCOALESCE); if (ext == NULL) panic("%s: extent_create failed", __func__); /* * grab regions per DRAM BARs */ for (u_int i=0; i < RMIXL_SBC_DRAM_NBARS; i++) { r = RMIXL_IOREG_READ(RMIXL_SBC_DRAM_BAR(i)); if ((r & RMIXL_DRAM_BAR_STATUS) == 0) continue; /* not enabled */ base = (u_long)(DRAM_BAR_TO_BASE((uint64_t)r) / (1024 * 1024)); size = (u_long)(DRAM_BAR_TO_SIZE((uint64_t)r) / (1024 * 1024)); DPRINTF(("%s: %d: %d: 0x%08x -- 0x%010lx:%lu MB\n", __func__, __LINE__, i, r, base * (1024 * 1024), size)); if (extent_alloc_region(ext, base, size, EX_NOWAIT) != 0) panic("%s: extent_alloc_region(%p, %#lx, %#lx, %#x) " "failed", __func__, ext, base, size, EX_NOWAIT); } /* * get chip-dependent physaddr regions */ switch(cpu_rmixl_chip_type(mips_options.mips_cpu)) { case CIDFL_RMI_TYPE_XLR: #if NRMIXL_PCIX rmixl_physaddr_init_pcix(ext); #endif break; case CIDFL_RMI_TYPE_XLS: #if NRMIXL_PCIE rmixl_physaddr_init_pcie(ext); #endif break; case CIDFL_RMI_TYPE_XLP: /* XXX TBD */ panic("%s: RMI XLP not yet supported", __func__); } /* * at this point all regions left in "physaddr" extent * are unused holes in the physical address space * available for use as needed. */ rmixl_configuration.rc_phys_ex = ext; #ifdef MACHDEP_DEBUG extent_print(ext); #endif } static uint64_t rmixlfw_init(int64_t infop) { struct rmixl_config *rcp = &rmixl_configuration; #ifdef MULTIPROCESSOR rmixl_get_wakeup_info(rcp); #endif infop |= MIPS_KSEG0_START; rcp->rc_psb_info = *(rmixlfw_info_t *)(intptr_t)infop; rcp->rc_psb_type = PSB_TYPE_UNKNOWN; for (int i=0; i < RMICLFW_PSB_VERSIONS_LEN; i++) { if (rmiclfw_psb_id[i].psb_version == rcp->rc_psb_info.psb_version) { rcp->rc_psb_type = rmiclfw_psb_id[i].psb_type; goto found; } } rcp->rc_io_pbase = RMIXL_IO_DEV_PBASE; rmixl_putchar_init(rcp->rc_io_pbase); #ifdef DIAGNOSTIC rmixl_puts("\r\nWARNING: untested psb_version: "); rmixl_puthex64(rcp->rc_psb_info.psb_version); rmixl_puts("\r\n"); #endif #ifdef MEMSIZE /* XXX trust and use MEMSIZE */ mem_clusters[0].start = 0; mem_clusters[0].size = MEMSIZE; mem_cluster_cnt = 1; return MEMSIZE; #else rmixl_puts("\r\nERROR: configure MEMSIZE\r\n"); cpu_reboot(RB_HALT, NULL); /* NOTREACHED */ #endif found: rcp->rc_io_pbase = MIPS_KSEG1_TO_PHYS(rcp->rc_psb_info.io_base); rmixl_putchar_init(rcp->rc_io_pbase); #ifdef MACHDEP_DEBUG rmixl_puts("\r\ninfop: "); rmixl_puthex64((uint64_t)(intptr_t)infop); #endif #ifdef DIAGNOSTIC rmixl_puts("\r\nrecognized psb_version="); rmixl_puthex64(rcp->rc_psb_info.psb_version); rmixl_puts(", psb_type="); rmixl_puts(rmixlfw_psb_type_name(rcp->rc_psb_type)); rmixl_puts("\r\n"); #endif return mem_clusters_init( (rmixlfw_mmap_t *)(intptr_t)rcp->rc_psb_info.psb_physaddr_map, (rmixlfw_mmap_t *)(intptr_t)rcp->rc_psb_info.avail_mem_map); } void rmixlfw_mmap_print(rmixlfw_mmap_t *map) { #ifdef MACHDEP_DEBUG for (uint32_t i=0; i < map->nmmaps; i++) { rmixl_puthex32(i); rmixl_puts(", "); rmixl_puthex64(map->entry[i].start); rmixl_puts(", "); rmixl_puthex64(map->entry[i].size); rmixl_puts(", "); rmixl_puthex32(map->entry[i].type); rmixl_puts("\r\n"); } #endif } /* * mem_clusters_init * * initialize mem_clusters[] table based on memory address mapping * provided by boot firmware. * * prefer avail_mem_map if we can, otherwise use psb_physaddr_map. * these will be limited by MEMSIZE if it is configured. * if neither are available, just use MEMSIZE. */ static uint64_t mem_clusters_init( rmixlfw_mmap_t *psb_physaddr_map, rmixlfw_mmap_t *avail_mem_map) { rmixlfw_mmap_t *map = NULL; const char *mapname; uint64_t sz; uint64_t sum; u_int cnt; #ifdef MEMSIZE uint64_t memsize = MEMSIZE; #endif #ifdef MACHDEP_DEBUG rmixl_puts("psb_physaddr_map: "); rmixl_puthex64((uint64_t)(intptr_t)psb_physaddr_map); rmixl_puts("\r\n"); #endif if (psb_physaddr_map != NULL) { map = psb_physaddr_map; mapname = "psb_physaddr_map"; rmixlfw_mmap_print(map); } #ifdef DIAGNOSTIC else { rmixl_puts("WARNING: no psb_physaddr_map\r\n"); } #endif #ifdef MACHDEP_DEBUG rmixl_puts("avail_mem_map: "); rmixl_puthex64((uint64_t)(intptr_t)avail_mem_map); rmixl_puts("\r\n"); #endif if (avail_mem_map != NULL) { map = avail_mem_map; mapname = "avail_mem_map"; rmixlfw_mmap_print(map); } #ifdef DIAGNOSTIC else { rmixl_puts("WARNING: no avail_mem_map\r\n"); } #endif if (map == NULL) { #ifndef MEMSIZE rmixl_puts("panic: no firmware memory map, " "must configure MEMSIZE\r\n"); for(;;); /* XXX */ #else #ifdef DIAGNOSTIC rmixl_puts("WARNING: no avail_mem_map, " "using MEMSIZE\r\n"); #endif mem_clusters[0].start = 0; mem_clusters[0].size = MEMSIZE; mem_cluster_cnt = 1; return MEMSIZE; #endif /* MEMSIZE */ } #ifdef DIAGNOSTIC rmixl_puts("using "); rmixl_puts(mapname); rmixl_puts("\r\n"); #endif #ifdef MACHDEP_DEBUG rmixl_puts("memory clusters:\r\n"); #endif sum = 0; cnt = 0; for (uint32_t i=0; i < map->nmmaps; i++) { if (map->entry[i].type != RMIXLFW_MMAP_TYPE_RAM) continue; mem_clusters[cnt].start = map->entry[i].start; sz = map->entry[i].size; sum += sz; mem_clusters[cnt].size = sz; #ifdef MACHDEP_DEBUG rmixl_puthex32(i); rmixl_puts(": "); rmixl_puthex64(mem_clusters[cnt].start); rmixl_puts(", "); rmixl_puthex64(sz); rmixl_puts(": "); rmixl_puthex64(sum); rmixl_puts("\r\n"); #endif #ifdef MEMSIZE /* * configurably limit memsize */ if (sum == memsize) break; if (sum > memsize) { uint64_t tmp; tmp = sum - memsize; sz -= tmp; sum -= tmp; mem_clusters[cnt].size = sz; cnt++; break; } #endif cnt++; } mem_cluster_cnt = cnt; return sum; } #ifdef MULTIPROCESSOR /* * RMI firmware passes wakeup info structure in CP0 OS Scratch reg #7 * they do not explicitly give us the size of the wakeup area. * we "know" that firmware loader sets wip->gp thusly: * gp = stack_start[vcpu] = round_page(wakeup_end) + (vcpu * (PAGE_SIZE * 2)) * so * round_page(wakeup_end) == gp - (vcpu * (PAGE_SIZE * 2)) * Only the "master" cpu runs this function, so * vcpu = wip->master_cpu */ void rmixl_get_wakeup_info(struct rmixl_config *rcp) { volatile rmixlfw_cpu_wakeup_info_t *wip; int32_t scratch_7; intptr_t end; __asm__ volatile( ".set push" "\n" ".set noreorder" "\n" ".set mips64" "\n" "dmfc0 %0, $22, 7" "\n" ".set pop" "\n" : "=r"(scratch_7)); wip = (volatile rmixlfw_cpu_wakeup_info_t *) (intptr_t)scratch_7; end = wip->entry.gp - (wip->master_cpu & (PAGE_SIZE * 2)); if (wip->valid == 1) { rcp->rc_cpu_wakeup_end = (const void *)end; rcp->rc_cpu_wakeup_info = wip; } }; #ifdef MACHDEP_DEBUG static void rmixl_wakeup_info_print(volatile rmixlfw_cpu_wakeup_info_t *wip) { int i; printf("%s: wip %p, size %lu\n", __func__, wip, sizeof(*wip)); printf("cpu_status %#x\n", wip->cpu_status); printf("valid: %d\n", wip->valid); printf("entry: addr %#x, args %#x, sp %#"PRIx64", gp %#"PRIx64"\n", wip->entry.addr, wip->entry.args, wip->entry.sp, wip->entry.gp); printf("master_cpu %d\n", wip->master_cpu); printf("master_cpu_mask %#x\n", wip->master_cpu_mask); printf("buddy_cpu_mask %#x\n", wip->buddy_cpu_mask); printf("psb_os_cpu_map %#x\n", wip->psb_os_cpu_map); printf("argc %d\n", wip->argc); printf("argv:"); for (i=0; i < wip->argc; i++) printf(" %#x", wip->argv[i]); printf("\n"); printf("valid_tlb_entries %d\n", wip->valid_tlb_entries); printf("tlb_map:\n"); for (i=0; i < wip->valid_tlb_entries; i++) { volatile const struct lib_cpu_tlb_mapping *m = &wip->tlb_map[i]; printf(" %d", m->page_size); printf(", %d", m->asid); printf(", %d", m->coherency); printf(", %d", m->coherency); printf(", %d", m->attr); printf(", %#x", m->virt); printf(", %#"PRIx64"\n", m->phys); } printf("elf segs:\n"); for (i=0; i < MAX_ELF_SEGMENTS; i++) { volatile const struct core_segment_info *e = &wip->seg_info[i]; printf(" %#"PRIx64"", e->vaddr); printf(", %#"PRIx64"", e->memsz); printf(", %#x\n", e->flags); } printf("envc %d\n", wip->envc); for (i=0; i < wip->envc; i++) printf(" %#x \"%s\"", wip->envs[i], (char *)(intptr_t)(int32_t)(wip->envs[i])); printf("\n"); printf("app_mode %d\n", wip->app_mode); printf("printk_lock %#x\n", wip->printk_lock); printf("kseg_master %d\n", wip->kseg_master); printf("kuseg_reentry_function %#x\n", wip->kuseg_reentry_function); printf("kuseg_reentry_args %#x\n", wip->kuseg_reentry_args); printf("app_shared_mem_addr %#"PRIx64"\n", wip->app_shared_mem_addr); printf("app_shared_mem_size %#"PRIx64"\n", wip->app_shared_mem_size); printf("app_shared_mem_orig %#"PRIx64"\n", wip->app_shared_mem_orig); printf("loader_lock %#x\n", wip->loader_lock); printf("global_wakeup_mask %#x\n", wip->global_wakeup_mask); printf("unused_0 %#x\n", wip->unused_0); } #endif /* MACHDEP_DEBUG */ #endif /* MULTIPROCESSOR */ void consinit(void) { /* * Everything related to console initialization is done * in mach_init(). */ } /* * Allocate memory for variable-sized tables, */ void cpu_startup(void) { /* * Virtual memory is bootstrapped -- notify the bus spaces * that memory allocation is now safe. */ rmixl_configuration.rc_mallocsafe = 1; /* Do the usual stuff */ cpu_startup_common(); } int waittime = -1; void cpu_reboot(int howto, char *bootstr) { /* Take a snapshot before clobbering any registers. */ savectx(lwp_getpcb(curlwp)); if (cold) { howto |= RB_HALT; goto haltsys; } /* If "always halt" was specified as a boot flag, obey. */ if (boothowto & RB_HALT) howto |= RB_HALT; boothowto = howto; if ((howto & RB_NOSYNC) == 0 && (waittime < 0)) { waittime = 0; vfs_shutdown(); /* * If we've been adjusting the clock, the todr * will be out of synch; adjust it now. */ resettodr(); } splhigh(); if (howto & RB_DUMP) dumpsys(); haltsys: doshutdownhooks(); if (howto & RB_HALT) { printf("\n"); printf("The operating system has halted.\n"); printf("Please press any key to reboot.\n\n"); cnpollc(1); /* For proper keyboard command handling */ cngetc(); cnpollc(0); } printf("rebooting...\n\n"); rmixl_reset(); } /* * goodbye world */ void __attribute__((__noreturn__)) rmixl_reset(void) { uint32_t r; r = RMIXL_IOREG_READ(RMIXL_IO_DEV_GPIO + RMIXL_GPIO_RESET); r |= RMIXL_GPIO_RESET_RESET; RMIXL_IOREG_WRITE(RMIXL_IO_DEV_GPIO + RMIXL_GPIO_RESET, r); printf("soft reset failed, spinning...\n"); for (;;); }