/* * Initialize machine setup information and I/O. * * After running setup() unit tests may query how many cpus they have * (nr_cpus), how much memory they have (PHYS_END - PHYS_OFFSET), may * use dynamic memory allocation (malloc, etc.), printf, and exit. * Finally, argc and argv are also ready to be passed to main(). * * Copyright (C) 2014, Red Hat Inc, Andrew Jones * * This work is licensed under the terms of the GNU LGPL, version 2. */ #include #include #include #include #include #include #include #include #include #include extern unsigned long stacktop; extern void io_init(void); char *initrd; u32 initrd_size; u64 cpus[NR_CPUS] = { [0 ... NR_CPUS-1] = (u64)~0 }; int nr_cpus; struct mem_region mem_regions[NR_MEM_REGIONS]; phys_addr_t __phys_offset, __phys_end; int mpidr_to_cpu(uint64_t mpidr) { int i; for (i = 0; i < nr_cpus; ++i) if (cpus[i] == (mpidr & MPIDR_HWID_BITMASK)) return i; return -1; } static void cpu_set(int fdtnode __unused, u64 regval, void *info __unused) { int cpu = nr_cpus++; assert_msg(cpu < NR_CPUS, "Number cpus exceeds maximum supported (%d).", NR_CPUS); cpus[cpu] = regval; set_cpu_present(cpu, true); } static void cpu_init(void) { int ret; nr_cpus = 0; ret = dt_for_each_cpu_node(cpu_set, NULL); assert(ret == 0); set_cpu_online(0, true); } static void mem_init(phys_addr_t freemem_start) { struct dt_pbus_reg regs[NR_MEM_REGIONS]; struct mem_region primary, mem = { .start = (phys_addr_t)-1, }; int nr_regs, i; nr_regs = dt_get_memory_params(regs, NR_MEM_REGIONS); assert(nr_regs > 0); primary.end = 0; for (i = 0; i < nr_regs; ++i) { mem_regions[i].start = regs[i].addr; mem_regions[i].end = regs[i].addr + regs[i].size; /* * pick the region we're in for our primary region */ if (freemem_start >= mem_regions[i].start && freemem_start < mem_regions[i].end) { mem_regions[i].flags |= MR_F_PRIMARY; primary = mem_regions[i]; } /* * set the lowest and highest addresses found, * ignoring potential gaps */ if (mem_regions[i].start < mem.start) mem.start = mem_regions[i].start; if (mem_regions[i].end > mem.end) mem.end = mem_regions[i].end; } assert(primary.end != 0); assert(!(mem.start & ~PHYS_MASK) && !((mem.end - 1) & ~PHYS_MASK)); __phys_offset = mem.start; /* PHYS_OFFSET */ __phys_end = mem.end; /* PHYS_END */ phys_alloc_init(freemem_start, primary.end - freemem_start); phys_alloc_set_minimum_alignment(SMP_CACHE_BYTES); mmu_enable_idmap(); } void setup(const void *fdt) { void *freemem = &stacktop; const char *bootargs, *tmp; u32 fdt_size; int ret; /* * Before calling mem_init we need to move the fdt and initrd * to safe locations. We move them to construct the memory * map illustrated below: * * +----------------------+ <-- top of physical memory * | | * ~ ~ * | | * +----------------------+ <-- top of initrd * | | * +----------------------+ <-- top of FDT * | | * +----------------------+ <-- top of cpu0's stack * | | * +----------------------+ <-- top of text/data/bss sections, * | | see arm/flat.lds * | | * +----------------------+ <-- load address * | | * +----------------------+ */ fdt_size = fdt_totalsize(fdt); ret = fdt_move(fdt, freemem, fdt_size); assert(ret == 0); ret = dt_init(freemem); assert(ret == 0); freemem += fdt_size; ret = dt_get_initrd(&tmp, &initrd_size); assert(ret == 0 || ret == -FDT_ERR_NOTFOUND); if (ret == 0) { initrd = freemem; memmove(initrd, tmp, initrd_size); freemem += initrd_size; } /* call init functions */ cpu_init(); /* cpu_init must be called before thread_info_init */ thread_info_init(current_thread_info(), 0); /* thread_info_init must be called before mem_init */ mem_init(PAGE_ALIGN((unsigned long)freemem)); /* mem_init must be called before io_init */ io_init(); /* finish setup */ ret = dt_get_bootargs(&bootargs); assert(ret == 0 || ret == -FDT_ERR_NOTFOUND); setup_args_progname(bootargs); if (initrd) { /* environ is currently the only file in the initrd */ char *env = malloc(initrd_size); memcpy(env, initrd, initrd_size); setup_env(env, initrd_size); } }