Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/firewire/fwe/@/dev/fdt/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/firewire/fwe/@/dev/fdt/fdt_common.c |
/*- * Copyright (c) 2009-2010 The FreeBSD Foundation * All rights reserved. * * This software was developed by Semihalf under sponsorship from * the FreeBSD Foundation. * * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/dev/fdt/fdt_common.c 233015 2012-03-15 22:15:06Z raj $"); #include <sys/param.h> #include <sys/systm.h> #include <sys/kernel.h> #include <sys/module.h> #include <sys/bus.h> #include <machine/fdt.h> #include <machine/resource.h> #include <dev/fdt/fdt_common.h> #include <dev/ofw/ofw_bus.h> #include <dev/ofw/ofw_bus_subr.h> #include <dev/ofw/openfirm.h> #include "ofw_bus_if.h" #ifdef DEBUG #define debugf(fmt, args...) do { printf("%s(): ", __func__); \ printf(fmt,##args); } while (0) #else #define debugf(fmt, args...) #endif #define FDT_COMPAT_LEN 255 #define FDT_TYPE_LEN 64 #define FDT_REG_CELLS 4 vm_paddr_t fdt_immr_pa; vm_offset_t fdt_immr_va; vm_offset_t fdt_immr_size; int fdt_immr_addr(vm_offset_t immr_va) { pcell_t ranges[6], *rangesptr; phandle_t node; u_long base, size; pcell_t addr_cells, size_cells, par_addr_cells; int len, tuple_size, tuples; /* * Try to access the SOC node directly i.e. through /aliases/. */ if ((node = OF_finddevice("soc")) != 0) if (fdt_is_compatible_strict(node, "simple-bus")) goto moveon; /* * Find the node the long way. */ if ((node = OF_finddevice("/")) == 0) return (ENXIO); if ((node = fdt_find_compatible(node, "simple-bus", 1)) == 0) return (ENXIO); moveon: if ((fdt_addrsize_cells(node, &addr_cells, &size_cells)) != 0) return (ENXIO); /* * Process 'ranges' property. */ par_addr_cells = fdt_parent_addr_cells(node); if (par_addr_cells > 2) return (ERANGE); len = OF_getproplen(node, "ranges"); if (len > sizeof(ranges)) return (ENOMEM); if (OF_getprop(node, "ranges", ranges, sizeof(ranges)) <= 0) return (EINVAL); tuple_size = sizeof(pcell_t) * (addr_cells + par_addr_cells + size_cells); tuples = len / tuple_size; if (fdt_ranges_verify(ranges, tuples, par_addr_cells, addr_cells, size_cells)) { return (ERANGE); } base = 0; size = 0; rangesptr = &ranges[0]; base = fdt_data_get((void *)rangesptr, addr_cells); rangesptr += addr_cells; base += fdt_data_get((void *)rangesptr, par_addr_cells); rangesptr += par_addr_cells; size = fdt_data_get((void *)rangesptr, size_cells); fdt_immr_pa = base; fdt_immr_va = immr_va; fdt_immr_size = size; return (0); } /* * This routine is an early-usage version of the ofw_bus_is_compatible() when * the ofw_bus I/F is not available (like early console routines and similar). * Note the buffer has to be on the stack since malloc() is usually not * available in such cases either. */ int fdt_is_compatible(phandle_t node, const char *compatstr) { char buf[FDT_COMPAT_LEN]; char *compat; int len, onelen, l, rv; if ((len = OF_getproplen(node, "compatible")) <= 0) return (0); compat = (char *)&buf; bzero(compat, FDT_COMPAT_LEN); if (OF_getprop(node, "compatible", compat, FDT_COMPAT_LEN) < 0) return (0); onelen = strlen(compatstr); rv = 0; while (len > 0) { if (strncasecmp(compat, compatstr, onelen) == 0) { /* Found it. */ rv = 1; break; } /* Slide to the next sub-string. */ l = strlen(compat) + 1; compat += l; len -= l; } return (rv); } int fdt_is_compatible_strict(phandle_t node, const char *compatible) { char compat[FDT_COMPAT_LEN]; if (OF_getproplen(node, "compatible") <= 0) return (0); if (OF_getprop(node, "compatible", compat, FDT_COMPAT_LEN) < 0) return (0); if (strncasecmp(compat, compatible, FDT_COMPAT_LEN) == 0) /* This fits. */ return (1); return (0); } phandle_t fdt_find_compatible(phandle_t start, const char *compat, int strict) { phandle_t child; /* * Traverse all children of 'start' node, and find first with * matching 'compatible' property. */ for (child = OF_child(start); child != 0; child = OF_peer(child)) if (fdt_is_compatible(child, compat)) { if (strict) if (!fdt_is_compatible_strict(child, compat)) continue; return (child); } return (0); } int fdt_is_enabled(phandle_t node) { char *stat; int ena, len; len = OF_getprop_alloc(node, "status", sizeof(char), (void **)&stat); if (len <= 0) /* It is OK if no 'status' property. */ return (1); /* Anything other than 'okay' means disabled. */ ena = 0; if (strncmp((char *)stat, "okay", len) == 0) ena = 1; free(stat, M_OFWPROP); return (ena); } int fdt_is_type(phandle_t node, const char *typestr) { char type[FDT_TYPE_LEN]; if (OF_getproplen(node, "device_type") <= 0) return (0); if (OF_getprop(node, "device_type", type, FDT_TYPE_LEN) < 0) return (0); if (strncasecmp(type, typestr, FDT_TYPE_LEN) == 0) /* This fits. */ return (1); return (0); } int fdt_parent_addr_cells(phandle_t node) { pcell_t addr_cells; /* Find out #address-cells of the superior bus. */ if (OF_searchprop(OF_parent(node), "#address-cells", &addr_cells, sizeof(addr_cells)) <= 0) addr_cells = 2; return ((int)fdt32_to_cpu(addr_cells)); } int fdt_data_verify(void *data, int cells) { uint64_t d64; if (cells > 1) { d64 = fdt64_to_cpu(*((uint64_t *)data)); if (((d64 >> 32) & 0xffffffffull) != 0 || cells > 2) return (ERANGE); } return (0); } int fdt_pm_is_enabled(phandle_t node) { int ret; ret = 1; #if defined(SOC_MV_KIRKWOOD) || defined(SOC_MV_DISCOVERY) ret = fdt_pm(node); #endif return (ret); } u_long fdt_data_get(void *data, int cells) { if (cells == 1) return (fdt32_to_cpu(*((uint32_t *)data))); return (fdt64_to_cpu(*((uint64_t *)data))); } int fdt_addrsize_cells(phandle_t node, int *addr_cells, int *size_cells) { pcell_t cell; int cell_size; /* * Retrieve #{address,size}-cells. */ cell_size = sizeof(cell); if (OF_getprop(node, "#address-cells", &cell, cell_size) < cell_size) cell = 2; *addr_cells = fdt32_to_cpu((int)cell); if (OF_getprop(node, "#size-cells", &cell, cell_size) < cell_size) cell = 1; *size_cells = fdt32_to_cpu((int)cell); if (*addr_cells > 3 || *size_cells > 2) return (ERANGE); return (0); } int fdt_ranges_verify(pcell_t *ranges, int tuples, int par_addr_cells, int this_addr_cells, int this_size_cells) { int i, rv, ulsz; if (par_addr_cells > 2 || this_addr_cells > 2 || this_size_cells > 2) return (ERANGE); /* * This is the max size the resource manager can handle for addresses * and sizes. */ ulsz = sizeof(u_long); if (par_addr_cells <= ulsz && this_addr_cells <= ulsz && this_size_cells <= ulsz) /* We can handle everything */ return (0); rv = 0; for (i = 0; i < tuples; i++) { if (fdt_data_verify((void *)ranges, par_addr_cells)) goto err; ranges += par_addr_cells; if (fdt_data_verify((void *)ranges, this_addr_cells)) goto err; ranges += this_addr_cells; if (fdt_data_verify((void *)ranges, this_size_cells)) goto err; ranges += this_size_cells; } return (0); err: debugf("using address range >%d-bit not supported\n", ulsz * 8); return (ERANGE); } int fdt_data_to_res(pcell_t *data, int addr_cells, int size_cells, u_long *start, u_long *count) { /* Address portion. */ if (fdt_data_verify((void *)data, addr_cells)) return (ERANGE); *start = fdt_data_get((void *)data, addr_cells); data += addr_cells; /* Size portion. */ if (fdt_data_verify((void *)data, size_cells)) return (ERANGE); *count = fdt_data_get((void *)data, size_cells); return (0); } int fdt_regsize(phandle_t node, u_long *base, u_long *size) { pcell_t reg[4]; int addr_cells, len, size_cells; if (fdt_addrsize_cells(OF_parent(node), &addr_cells, &size_cells)) return (ENXIO); if ((sizeof(pcell_t) * (addr_cells + size_cells)) > sizeof(reg)) return (ENOMEM); len = OF_getprop(node, "reg", ®, sizeof(reg)); if (len <= 0) return (EINVAL); *base = fdt_data_get(®[0], addr_cells); *size = fdt_data_get(®[addr_cells], size_cells); return (0); } int fdt_reg_to_rl(phandle_t node, struct resource_list *rl, u_long base) { u_long start, end, count; pcell_t *reg, *regptr; pcell_t addr_cells, size_cells; int tuple_size, tuples; int i, rv; if (fdt_addrsize_cells(OF_parent(node), &addr_cells, &size_cells) != 0) return (ENXIO); tuple_size = sizeof(pcell_t) * (addr_cells + size_cells); tuples = OF_getprop_alloc(node, "reg", tuple_size, (void **)®); debugf("addr_cells = %d, size_cells = %d\n", addr_cells, size_cells); debugf("tuples = %d, tuple size = %d\n", tuples, tuple_size); if (tuples <= 0) /* No 'reg' property in this node. */ return (0); regptr = reg; for (i = 0; i < tuples; i++) { rv = fdt_data_to_res(reg, addr_cells, size_cells, &start, &count); if (rv != 0) { resource_list_free(rl); goto out; } reg += addr_cells + size_cells; /* Calculate address range relative to base. */ start &= 0x000ffffful; start = base + start; end = start + count - 1; debugf("reg addr start = %lx, end = %lx, count = %lx\n", start, end, count); resource_list_add(rl, SYS_RES_MEMORY, i, start, end, count); } rv = 0; out: free(regptr, M_OFWPROP); return (rv); } int fdt_intr_decode(phandle_t intr_parent, pcell_t *intr, int *interrupt, int *trig, int *pol) { fdt_pic_decode_t intr_decode; int i, rv; for (i = 0; fdt_pic_table[i] != NULL; i++) { /* XXX check if pic_handle has interrupt-controller prop? */ intr_decode = fdt_pic_table[i]; rv = intr_decode(intr_parent, intr, interrupt, trig, pol); if (rv == 0) /* This was recognized as our PIC and decoded. */ return (0); } return (ENXIO); } int fdt_intr_to_rl(phandle_t node, struct resource_list *rl, struct fdt_sense_level *intr_sl) { phandle_t intr_par; ihandle_t iph; pcell_t *intr; pcell_t intr_cells; int interrupt, trig, pol; int i, intr_num, irq, rv; if (OF_getproplen(node, "interrupts") <= 0) /* Node does not have 'interrupts' property. */ return (0); /* * Find #interrupt-cells of the interrupt domain. */ if (OF_getprop(node, "interrupt-parent", &iph, sizeof(iph)) <= 0) { debugf("no intr-parent phandle\n"); intr_par = OF_parent(node); } else { iph = fdt32_to_cpu(iph); intr_par = OF_instance_to_package(iph); } if (OF_getprop(intr_par, "#interrupt-cells", &intr_cells, sizeof(intr_cells)) <= 0) { debugf("no intr-cells defined, defaulting to 1\n"); intr_cells = 1; } intr_cells = fdt32_to_cpu(intr_cells); intr_num = OF_getprop_alloc(node, "interrupts", intr_cells * sizeof(pcell_t), (void **)&intr); if (intr_num <= 0 || intr_num > DI_MAX_INTR_NUM) return (ERANGE); rv = 0; for (i = 0; i < intr_num; i++) { interrupt = -1; trig = pol = 0; if (fdt_intr_decode(intr_par, &intr[i * intr_cells], &interrupt, &trig, &pol) != 0) { rv = ENXIO; goto out; } if (interrupt < 0) { rv = ERANGE; goto out; } debugf("decoded intr = %d, trig = %d, pol = %d\n", interrupt, trig, pol); intr_sl[i].trig = trig; intr_sl[i].pol = pol; irq = FDT_MAP_IRQ(intr_par, interrupt); resource_list_add(rl, SYS_RES_IRQ, i, irq, irq, 1); } out: free(intr, M_OFWPROP); return (rv); } int fdt_get_phyaddr(phandle_t node, device_t dev, int *phy_addr, void **phy_sc) { phandle_t phy_node; ihandle_t phy_ihandle; pcell_t phy_handle, phy_reg; uint32_t i; device_t parent, child; if (OF_getprop(node, "phy-handle", (void *)&phy_handle, sizeof(phy_handle)) <= 0) return (ENXIO); phy_ihandle = (ihandle_t)phy_handle; phy_ihandle = fdt32_to_cpu(phy_ihandle); phy_node = OF_instance_to_package(phy_ihandle); if (OF_getprop(phy_node, "reg", (void *)&phy_reg, sizeof(phy_reg)) <= 0) return (ENXIO); *phy_addr = fdt32_to_cpu(phy_reg); /* * Search for softc used to communicate with phy. */ /* * Step 1: Search for ancestor of the phy-node with a "phy-handle" * property set. */ phy_node = OF_parent(phy_node); while (phy_node != 0) { if (OF_getprop(phy_node, "phy-handle", (void *)&phy_handle, sizeof(phy_handle)) > 0) break; phy_node = OF_parent(phy_node); } if (phy_node == 0) return (ENXIO); /* * Step 2: For each device with the same parent and name as ours * compare its node with the one found in step 1, ancestor of phy * node (stored in phy_node). */ parent = device_get_parent(dev); i = 0; child = device_find_child(parent, device_get_name(dev), i); while (child != NULL) { if (ofw_bus_get_node(child) == phy_node) break; i++; child = device_find_child(parent, device_get_name(dev), i); } if (child == NULL) return (ENXIO); /* * Use softc of the device found. */ *phy_sc = (void *)device_get_softc(child); return (0); } int fdt_get_mem_regions(struct mem_region *mr, int *mrcnt, uint32_t *memsize) { pcell_t reg[FDT_REG_CELLS * FDT_MEM_REGIONS]; pcell_t *regp; phandle_t memory; uint32_t memory_size; int addr_cells, size_cells; int i, max_size, reg_len, rv, tuple_size, tuples; max_size = sizeof(reg); memory = OF_finddevice("/memory"); if (memory <= 0) { rv = ENXIO; goto out; } if ((rv = fdt_addrsize_cells(OF_parent(memory), &addr_cells, &size_cells)) != 0) goto out; if (addr_cells > 2) { rv = ERANGE; goto out; } tuple_size = sizeof(pcell_t) * (addr_cells + size_cells); reg_len = OF_getproplen(memory, "reg"); if (reg_len <= 0 || reg_len > sizeof(reg)) { rv = ERANGE; goto out; } if (OF_getprop(memory, "reg", reg, reg_len) <= 0) { rv = ENXIO; goto out; } memory_size = 0; tuples = reg_len / tuple_size; regp = (pcell_t *)® for (i = 0; i < tuples; i++) { rv = fdt_data_to_res(regp, addr_cells, size_cells, (u_long *)&mr[i].mr_start, (u_long *)&mr[i].mr_size); if (rv != 0) goto out; regp += addr_cells + size_cells; memory_size += mr[i].mr_size; } if (memory_size == 0) { rv = ERANGE; goto out; } *mrcnt = i; *memsize = memory_size; rv = 0; out: return (rv); }