/* $OpenBSD: fdt.c,v 1.19 2016/08/23 18:12:09 kettenis Exp $ */ /* * Copyright (c) 2009 Dariusz Swiderski * Copyright (c) 2009 Mark Kettenis * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include /* XXX */ #define OPROMMAXPARAM 32 unsigned int fdt_check_head(void *); char *fdt_get_str(u_int32_t); void *skip_property(u_int32_t *); void *skip_props(u_int32_t *); void *skip_node_name(u_int32_t *); void *skip_node(void *); void *skip_nops(u_int32_t *); void *fdt_parent_node_recurse(void *, void *); void *fdt_find_phandle_recurse(void *, uint32_t); int fdt_node_property_int(void *, char *, int *); int fdt_node_property_ints(void *, char *, int *, int); int fdt_translate_reg(void *, struct fdt_reg *); #ifdef DEBUG void fdt_print_node_recurse(void *, int); #endif static int tree_inited = 0; static struct fdt tree; unsigned int fdt_check_head(void *fdt) { struct fdt_head *fh; u_int32_t *ptr, *tok; fh = fdt; ptr = (u_int32_t *)fdt; if (betoh32(fh->fh_magic) != FDT_MAGIC) return 0; if (betoh32(fh->fh_version) > FDT_CODE_VERSION) return 0; tok = skip_nops(ptr + (betoh32(fh->fh_struct_off) / 4)); if (betoh32(*tok) != FDT_NODE_BEGIN) return 0; /* check for end signature on version 17 blob */ if ((betoh32(fh->fh_version) >= 17) && (betoh32(*(ptr + (betoh32(fh->fh_struct_off) / 4) + (betoh32(fh->fh_struct_size) / 4) - 1)) != FDT_END)) return 0; return betoh32(fh->fh_version); } /* * Initializes internal structures of module. * Has to be called once, preferably in machdep.c. */ int fdt_init(void *fdt) { int version; bzero(&tree, sizeof(struct fdt)); tree_inited = 0; if (!fdt) return 0; if (!(version = fdt_check_head(fdt))) return 0; tree.header = (struct fdt_head *)fdt; tree.tree = (char *)fdt + betoh32(tree.header->fh_struct_off); tree.strings = (char *)fdt + betoh32(tree.header->fh_strings_off); tree.memory = (char *)fdt + betoh32(tree.header->fh_reserve_off); tree.version = version; tree.strings_size = betoh32(tree.header->fh_strings_size); tree_inited = 1; return version; } /* * Return the size of the FDT. */ size_t fdt_get_size(void *fdt) { if (!fdt) return 0; if (!fdt_check_head(fdt)) return 0; return betoh32(((struct fdt_head *)fdt)->fh_size); } /* * Retrieve string pointer from strings table. */ char * fdt_get_str(u_int32_t num) { if (num > tree.strings_size) return NULL; return (tree.strings) ? (tree.strings + num) : NULL; } /* * Utility functions for skipping parts of tree. */ void * skip_nops(u_int32_t *ptr) { while (betoh32(*ptr) == FDT_NOP) ptr++; return ptr; } void * skip_property(u_int32_t *ptr) { u_int32_t size; size = betoh32(*(ptr + 1)); /* move forward by magic + size + nameid + rounded up property size */ ptr += 3 + roundup(size, sizeof(u_int32_t)) / sizeof(u_int32_t); return skip_nops(ptr); } void * skip_props(u_int32_t *ptr) { while (betoh32(*ptr) == FDT_PROPERTY) { ptr = skip_property(ptr); } return ptr; } void * skip_node_name(u_int32_t *ptr) { /* skip name, aligned to 4 bytes, this is NULL term., so must add 1 */ ptr += roundup(strlen((char *)ptr) + 1, sizeof(u_int32_t)) / sizeof(u_int32_t); return skip_nops(ptr); } /* * Retrieves node property, the returned pointer is inside the fdt tree, * so we should not modify content pointed by it directly. */ int fdt_node_property(void *node, char *name, char **out) { u_int32_t *ptr; u_int32_t nameid; char *tmp; if (!tree_inited) return -1; ptr = (u_int32_t *)node; if (betoh32(*ptr) != FDT_NODE_BEGIN) return -1; ptr = skip_node_name(ptr + 1); while (betoh32(*ptr) == FDT_PROPERTY) { nameid = betoh32(*(ptr + 2)); /* id of name in strings table */ tmp = fdt_get_str(nameid); if (!strcmp(name, tmp)) { *out = (char *)(ptr + 3); /* beginning of the value */ return betoh32(*(ptr + 1)); /* size of value */ } ptr = skip_property(ptr); } return -1; } /* * Retrieves next node, skipping all the children nodes of the pointed node, * returns pointer to next node, no matter if it exists or not. */ void * skip_node(void *node) { u_int32_t *ptr = node; ptr++; ptr = skip_node_name(ptr); ptr = skip_props(ptr); /* skip children */ while (betoh32(*ptr) == FDT_NODE_BEGIN) ptr = skip_node(ptr); return skip_nops(ptr + 1); } /* * Retrieves next node, skipping all the children nodes of the pointed node, * returns pointer to next node if exists, otherwise returns NULL. * If passed 0 will return first node of the tree (root). */ void * fdt_next_node(void *node) { u_int32_t *ptr; if (!tree_inited) return NULL; ptr = node; if (node == NULL) { ptr = skip_nops(tree.tree); return (betoh32(*ptr) == FDT_NODE_BEGIN) ? ptr : NULL; } if (betoh32(*ptr) != FDT_NODE_BEGIN) return NULL; ptr++; ptr = skip_node_name(ptr); ptr = skip_props(ptr); /* skip children */ while (betoh32(*ptr) == FDT_NODE_BEGIN) ptr = skip_node(ptr); if (betoh32(*ptr) != FDT_NODE_END) return NULL; ptr = skip_nops(ptr + 1); if (betoh32(*ptr) != FDT_NODE_BEGIN) return NULL; return ptr; } int fdt_next_property(void *node, char *name, char **nextname) { u_int32_t *ptr; u_int32_t nameid; if (!tree_inited) return 0; ptr = (u_int32_t *)node; if (betoh32(*ptr) != FDT_NODE_BEGIN) return 0; ptr = skip_node_name(ptr + 1); while (betoh32(*ptr) == FDT_PROPERTY) { nameid = betoh32(*(ptr + 2)); /* id of name in strings table */ if (strcmp(name, "") == 0) { *nextname = fdt_get_str(nameid); return 1; } if (strcmp(name, fdt_get_str(nameid)) == 0) { ptr = skip_property(ptr); if (betoh32(*ptr) != FDT_PROPERTY) break; nameid = betoh32(*(ptr + 2)); *nextname = fdt_get_str(nameid); return 1; } ptr = skip_property(ptr); } *nextname = ""; return 1; } /* * Retrieves node property as integers and puts them in the given * integer array. */ int fdt_node_property_ints(void *node, char *name, int *out, int outlen) { int *data; int i, inlen; inlen = fdt_node_property(node, name, (char **)&data) / sizeof(int); if (inlen <= 0) return -1; for (i = 0; i < inlen && i < outlen; i++) out[i] = betoh32(data[i]); return i; } /* * Retrieves node property as an integer. */ int fdt_node_property_int(void *node, char *name, int *out) { return fdt_node_property_ints(node, name, out, 1); } /* * Retrieves next node, skipping all the children nodes of the pointed node */ void * fdt_child_node(void *node) { u_int32_t *ptr; if (!tree_inited) return NULL; ptr = node; if (betoh32(*ptr) != FDT_NODE_BEGIN) return NULL; ptr++; ptr = skip_node_name(ptr); ptr = skip_props(ptr); /* check if there is a child node */ return (betoh32(*ptr) == FDT_NODE_BEGIN) ? (ptr) : NULL; } /* * Retrieves node name. */ char * fdt_node_name(void *node) { u_int32_t *ptr; if (!tree_inited) return NULL; ptr = node; if (betoh32(*ptr) != FDT_NODE_BEGIN) return NULL; return (char *)(ptr + 1); } void * fdt_find_node(char *name) { void *node = fdt_next_node(0); const char *p = name; if (!tree_inited) return NULL; if (*p != '/') return NULL; while (*p) { void *child; const char *q; while (*p == '/') p++; if (*p == 0) return node; q = strchr(p, '/'); if (q == NULL) q = p + strlen(p); for (child = fdt_child_node(node); child; child = fdt_next_node(child)) { if (strncmp(p, fdt_node_name(child), q - p) == 0) { node = child; break; } } if (child == NULL) return NULL; /* No match found. */ p = q; } return node; } void * fdt_parent_node_recurse(void *pnode, void *child) { void *node = fdt_child_node(pnode); void *tmp; while (node && (node != child)) { if ((tmp = fdt_parent_node_recurse(node, child))) return tmp; node = fdt_next_node(node); } return (node) ? pnode : NULL; } void * fdt_parent_node(void *node) { void *pnode = fdt_next_node(0); if (!tree_inited) return NULL; if (node == pnode) return NULL; return fdt_parent_node_recurse(pnode, node); } void * fdt_find_phandle_recurse(void *node, uint32_t phandle) { void *child; char *data; void *tmp; int len; len = fdt_node_property(node, "phandle", &data); if (len < 0) len = fdt_node_property(node, "linux,phandle", &data); if (len == sizeof(uint32_t) && bemtoh32(data) == phandle) return node; for (child = fdt_child_node(node); child; child = fdt_next_node(child)) if ((tmp = fdt_find_phandle_recurse(child, phandle))) return tmp; return NULL; } void * fdt_find_phandle(uint32_t phandle) { return fdt_find_phandle_recurse(fdt_next_node(0), phandle); } /* * Translate memory address depending on parent's range. * * Ranges are a way of mapping one address to another. This ranges attribute * is set on a node's parent. This means if a node does not have a parent, * there's nothing to translate. If it does have a parent and the parent does * not have a ranges attribute, there's nothing to translate either. * * If the parent has a ranges attribute and the attribute is not empty, the * node's memory address has to be in one of the given ranges. This range is * then used to translate the memory address. * * If the parent has a ranges attribute, but the attribute is empty, there's * nothing to translate. But it's not a translation barrier. It can be treated * as a simple 1:1 mapping. * * Translation does not end here. We need to check if the parent's parent also * has a ranges attribute and ask the same questions again. */ int fdt_translate_reg(void *node, struct fdt_reg *reg) { void *parent; int pac, psc, ac, sc, ret, rlen, rone, *range; uint64_t from, to, size; /* No parent, no translation. */ parent = fdt_parent_node(node); if (parent == NULL) return 0; /* Extract ranges property from node. */ rlen = fdt_node_property(node, "ranges", (char **)&range) / sizeof(int); /* No ranges means translation barrier. Translation stops here. */ if (range == NULL) return 0; /* Empty ranges means 1:1 mapping. Continue translation on parent. */ if (rlen <= 0) return fdt_translate_reg(parent, reg); /* We only support 32-bit (1), and 64-bit (2) wide addresses here. */ ret = fdt_node_property_int(parent, "#address-cells", &pac); if (ret != 1 || pac <= 0 || pac > 2) return EINVAL; /* We only support 32-bit (1), and 64-bit (2) wide sizes here. */ ret = fdt_node_property_int(parent, "#size-cells", &psc); if (ret != 1 || psc <= 0 || psc > 2) return EINVAL; /* We only support 32-bit (1), and 64-bit (2) wide addresses here. */ ret = fdt_node_property_int(node, "#address-cells", &ac); if (ret <= 0) ac = pac; else if (ret > 1 || ac <= 0 || ac > 2) return EINVAL; /* We only support 32-bit (1), and 64-bit (2) wide sizes here. */ ret = fdt_node_property_int(node, "#size-cells", &sc); if (ret <= 0) sc = psc; else if (ret > 1 || sc <= 0 || sc > 2) return EINVAL; /* Must have at least one range. */ rone = pac + ac + sc; if (rlen < rone) return ESRCH; /* For each range. */ for (; rlen >= rone; rlen -= rone, range += rone) { /* Extract from and size, so we can see if we fit. */ from = betoh32(range[0]); if (ac == 2) from = (from << 32) + betoh32(range[1]); size = betoh32(range[ac + pac]); if (sc == 2) size = (size << 32) + betoh32(range[ac + pac + 1]); /* Try next, if we're not in the range. */ if (reg->addr < from || (reg->addr + reg->size) > (from + size)) continue; /* All good, extract to address and translate. */ to = betoh32(range[ac]); if (pac == 2) to = (to << 32) + betoh32(range[ac + 1]); reg->addr -= from; reg->addr += to; return fdt_translate_reg(parent, reg); } /* To be successful, we must have returned in the for-loop. */ return ESRCH; } /* * Parse the memory address and size of a node. */ int fdt_get_reg(void *node, int idx, struct fdt_reg *reg) { void *parent; int ac, sc, off, ret, *in, inlen; if (node == NULL || reg == NULL) return EINVAL; parent = fdt_parent_node(node); if (parent == NULL) return EINVAL; /* We only support 32-bit (1), and 64-bit (2) wide addresses here. */ ret = fdt_node_property_int(parent, "#address-cells", &ac); if (ret != 1 || ac <= 0 || ac > 2) return EINVAL; /* We only support 32-bit (1), and 64-bit (2) wide sizes here. */ ret = fdt_node_property_int(parent, "#size-cells", &sc); if (ret != 1 || sc <= 0 || sc > 2) return EINVAL; inlen = fdt_node_property(node, "reg", (char **)&in) / sizeof(int); if (inlen < ((idx + 1) * (ac + sc))) return EINVAL; off = idx * (ac + sc); reg->addr = betoh32(in[off]); if (ac == 2) reg->addr = (reg->addr << 32) + betoh32(in[off + 1]); reg->size = betoh32(in[off + ac]); if (sc == 2) reg->size = (reg->size << 32) + betoh32(in[off + ac + 1]); return fdt_translate_reg(parent, reg); } int fdt_is_compatible(void *node, const char *name) { char *data; int len; len = fdt_node_property(node, "compatible", &data); while (len > 0) { if (strcmp(data, name) == 0) return 1; len -= strlen(data) + 1; data += strlen(data) + 1; } return 0; } #ifdef DEBUG /* * Debug methods for printing whole tree, particular odes and properies */ void * fdt_print_property(void *node, int level) { u_int32_t *ptr; char *tmp, *value; int cnt; u_int32_t nameid, size; ptr = (u_int32_t *)node; if (!tree_inited) return NULL; if (betoh32(*ptr) != FDT_PROPERTY) return ptr; /* should never happen */ /* extract property name_id and size */ size = betoh32(*++ptr); nameid = betoh32(*++ptr); for (cnt = 0; cnt < level; cnt++) printf("\t"); tmp = fdt_get_str(nameid); printf("\t%s : ", tmp ? tmp : "NO_NAME"); ptr++; value = (char *)ptr; if (!strcmp(tmp, "device_type") || !strcmp(tmp, "compatible") || !strcmp(tmp, "model") || !strcmp(tmp, "bootargs") || !strcmp(tmp, "linux,stdout-path")) { printf("%s", value); } else if (!strcmp(tmp, "clock-frequency") || !strcmp(tmp, "timebase-frequency")) { printf("%d", betoh32(*((unsigned int *)value))); } else { for (cnt = 0; cnt < size; cnt++) { if ((cnt % sizeof(u_int32_t)) == 0) printf(" "); printf("%02x", value[cnt]); } } ptr += roundup(size, sizeof(u_int32_t)) / sizeof(u_int32_t); printf("\n"); return ptr; } void fdt_print_node(void *node, int level) { u_int32_t *ptr; int cnt; ptr = (u_int32_t *)node; if (betoh32(*ptr) != FDT_NODE_BEGIN) return; ptr++; for (cnt = 0; cnt < level; cnt++) printf("\t"); printf("%s :\n", fdt_node_name(node)); ptr = skip_node_name(ptr); while (betoh32(*ptr) == FDT_PROPERTY) ptr = fdt_print_property(ptr, level); } void fdt_print_node_recurse(void *node, int level) { void *child; fdt_print_node(node, level); for (child = fdt_child_node(node); child; child = fdt_next_node(child)) fdt_print_node_recurse(child, level + 1); } void fdt_print_tree(void) { fdt_print_node_recurse(fdt_next_node(0), 0); } #endif int OF_peer(int handle) { void *node = (char *)tree.header + handle; if (handle == 0) node = fdt_find_node("/"); else node = fdt_next_node(node); return node ? ((char *)node - (char *)tree.header) : 0; } int OF_child(int handle) { void *node = (char *)tree.header + handle; node = fdt_child_node(node); return node ? ((char *)node - (char *)tree.header) : 0; } int OF_parent(int handle) { void *node = (char *)tree.header + handle; node = fdt_parent_node(node); return node ? ((char *)node - (char *)tree.header) : 0; } int OF_finddevice(char *name) { void *node; node = fdt_find_node(name); return node ? ((char *)node - (char *)tree.header) : -1; } int OF_getnodebyname(int handle, const char *name) { void *node = (char *)tree.header + handle; if (handle == 0) node = fdt_find_node("/"); while (node) { if (strcmp(name, fdt_node_name(node)) == 0) break; node = fdt_next_node(node); } return node ? ((char *)node - (char *)tree.header) : 0; } int OF_getnodebyphandle(uint32_t phandle) { void *node; node = fdt_find_phandle(phandle); return node ? ((char *)node - (char *)tree.header) : 0; } int OF_getproplen(int handle, char *prop) { void *node = (char *)tree.header + handle; char *data, *name; int len; len = fdt_node_property(node, prop, &data); /* * The "name" property is optional since version 16 of the * flattened device tree specification, so we synthesize one * from the unit name of the node if it is missing. */ if (len < 0 && strcmp(prop, "name") == 0) { name = fdt_node_name(node); data = strchr(name, '@'); if (data) len = data - name; else len = strlen(name); return len + 1; } return len; } int OF_getprop(int handle, char *prop, void *buf, int buflen) { void *node = (char *)tree.header + handle; char *data; int len; len = fdt_node_property(node, prop, &data); /* * The "name" property is optional since version 16 of the * flattened device tree specification, so we synthesize one * from the unit name of the node if it is missing. */ if (len < 0 && strcmp(prop, "name") == 0) { data = fdt_node_name(node); if (data) { len = strlcpy(buf, data, buflen); data = strchr(buf, '@'); if (data) { *data = 0; len = data - (char *)buf; } return len + 1; } } if (len > 0) memcpy(buf, data, min(len, buflen)); return len; } uint32_t OF_getpropint(int handle, char *prop, uint32_t defval) { uint32_t val; int len; len = OF_getprop(handle, prop, &val, sizeof(val)); if (len != sizeof(val)) return defval; return betoh32(val); } int OF_getpropintarray(int handle, char *prop, uint32_t *buf, int buflen) { int len; int i; len = OF_getprop(handle, prop, buf, buflen); if (len < 0 || (len % sizeof(uint32_t))) return -1; for (i = 0; i < len / sizeof(uint32_t); i++) buf[i] = betoh32(buf[i]); return len; } int OF_nextprop(int handle, char *prop, void *nextprop) { void *node = (char *)tree.header + handle; char *data; if (fdt_node_property(node, "name", &data) == -1) { if (strcmp(prop, "") == 0) return strlcpy(nextprop, "name", OPROMMAXPARAM); if (strcmp(prop, "name") == 0) prop = ""; } if (fdt_next_property(node, prop, &data)) return strlcpy(nextprop, data, OPROMMAXPARAM); return -1; } int OF_is_compatible(int handle, const char *name) { void *node = (char *)tree.header + handle; return (fdt_is_compatible(node, name)); }