/* * Copyright (c) 2018-2022, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ /* Helper functions to offer easier navigation of Device Tree Blob */ #include #include #include #include #include #include #include #include #include /* * Read cells from a given property of the given node. Any number of 32-bit * cells of the property can be read. Returns 0 on success, or a negative * FDT error value otherwise. */ int fdt_read_uint32_array(const void *dtb, int node, const char *prop_name, unsigned int cells, uint32_t *value) { const fdt32_t *prop; int value_len; assert(dtb != NULL); assert(prop_name != NULL); assert(value != NULL); assert(node >= 0); /* Access property and obtain its length (in bytes) */ prop = fdt_getprop(dtb, node, prop_name, &value_len); if (prop == NULL) { VERBOSE("Couldn't find property %s in dtb\n", prop_name); return -FDT_ERR_NOTFOUND; } /* Verify that property length can fill the entire array. */ if (NCELLS((unsigned int)value_len) < cells) { WARN("Property length mismatch\n"); return -FDT_ERR_BADVALUE; } for (unsigned int i = 0U; i < cells; i++) { value[i] = fdt32_to_cpu(prop[i]); } return 0; } int fdt_read_uint32(const void *dtb, int node, const char *prop_name, uint32_t *value) { return fdt_read_uint32_array(dtb, node, prop_name, 1, value); } uint32_t fdt_read_uint32_default(const void *dtb, int node, const char *prop_name, uint32_t dflt_value) { uint32_t ret = dflt_value; int err = fdt_read_uint32(dtb, node, prop_name, &ret); if (err < 0) { return dflt_value; } return ret; } int fdt_read_uint64(const void *dtb, int node, const char *prop_name, uint64_t *value) { uint32_t array[2] = {0, 0}; int ret; ret = fdt_read_uint32_array(dtb, node, prop_name, 2, array); if (ret < 0) { return ret; } *value = ((uint64_t)array[0] << 32) | array[1]; return 0; } /* * Read bytes from a given property of the given node. Any number of * bytes of the property can be read. The fdt pointer is updated. * Returns 0 on success, and -1 on error. */ int fdtw_read_bytes(const void *dtb, int node, const char *prop, unsigned int length, void *value) { const void *ptr; int value_len; assert(dtb != NULL); assert(prop != NULL); assert(value != NULL); assert(node >= 0); /* Access property and obtain its length (in bytes) */ ptr = fdt_getprop_namelen(dtb, node, prop, (int)strlen(prop), &value_len); if (ptr == NULL) { WARN("Couldn't find property %s in dtb\n", prop); return -1; } /* Verify that property length is not less than number of bytes */ if ((unsigned int)value_len < length) { WARN("Property length mismatch\n"); return -1; } (void)memcpy(value, ptr, length); return 0; } /* * Read string from a given property of the given node. Up to 'size - 1' * characters are read, and a NUL terminator is added. Returns 0 on success, * and -1 upon error. */ int fdtw_read_string(const void *dtb, int node, const char *prop, char *str, size_t size) { const char *ptr; size_t len; assert(dtb != NULL); assert(node >= 0); assert(prop != NULL); assert(str != NULL); assert(size > 0U); ptr = fdt_getprop_namelen(dtb, node, prop, (int)strlen(prop), NULL); if (ptr == NULL) { WARN("Couldn't find property %s in dtb\n", prop); return -1; } len = strlcpy(str, ptr, size); if (len >= size) { WARN("String of property %s in dtb has been truncated\n", prop); return -1; } return 0; } /* * Read UUID from a given property of the given node. Returns 0 on success, * and a negative value upon error. */ int fdtw_read_uuid(const void *dtb, int node, const char *prop, unsigned int length, uint8_t *uuid) { /* Buffer for UUID string (plus NUL terminator) */ char uuid_string[UUID_STRING_LENGTH + 1U]; int err; assert(dtb != NULL); assert(prop != NULL); assert(uuid != NULL); assert(node >= 0); if (length < UUID_BYTES_LENGTH) { return -EINVAL; } err = fdtw_read_string(dtb, node, prop, uuid_string, UUID_STRING_LENGTH + 1U); if (err != 0) { return err; } if (read_uuid(uuid, uuid_string) != 0) { return -FDT_ERR_BADVALUE; } return 0; } /* * Write cells in place to a given property of the given node. At most 2 cells * of the property are written. Returns 0 on success, and -1 upon error. */ int fdtw_write_inplace_cells(void *dtb, int node, const char *prop, unsigned int cells, void *value) { int err, len; assert(dtb != NULL); assert(prop != NULL); assert(value != NULL); assert(node >= 0); /* We expect either 1 or 2 cell property */ assert(cells <= 2U); if (cells == 2U) *(uint64_t *)value = cpu_to_fdt64(*(uint64_t *)value); else *(uint32_t *)value = cpu_to_fdt32(*(uint32_t *)value); len = (int)cells * 4; /* Set property value in place */ err = fdt_setprop_inplace(dtb, node, prop, value, len); if (err != 0) { WARN("Modify property %s failed with error %d\n", prop, err); return -1; } return 0; } /* * Write bytes in place to a given property of the given node. * Any number of bytes of the property can be written. * Returns 0 on success, and < 0 on error. */ int fdtw_write_inplace_bytes(void *dtb, int node, const char *prop, unsigned int length, const void *data) { const void *ptr; int namelen, value_len, err; assert(dtb != NULL); assert(prop != NULL); assert(data != NULL); assert(node >= 0); namelen = (int)strlen(prop); /* Access property and obtain its length in bytes */ ptr = fdt_getprop_namelen(dtb, node, prop, namelen, &value_len); if (ptr == NULL) { WARN("Couldn't find property %s in dtb\n", prop); return -1; } /* Verify that property length is not less than number of bytes */ if ((unsigned int)value_len < length) { WARN("Property length mismatch\n"); return -1; } /* Set property value in place */ err = fdt_setprop_inplace_namelen_partial(dtb, node, prop, namelen, 0, data, (int)length); if (err != 0) { WARN("Set property %s failed with error %d\n", prop, err); } return err; } static uint64_t fdt_read_prop_cells(const fdt32_t *prop, int nr_cells) { uint64_t reg = fdt32_to_cpu(prop[0]); if (nr_cells > 1) { reg = (reg << 32) | fdt32_to_cpu(prop[1]); } return reg; } int fdt_get_reg_props_by_index(const void *dtb, int node, int index, uintptr_t *base, size_t *size) { const fdt32_t *prop; int parent, len; int ac, sc; int cell; parent = fdt_parent_offset(dtb, node); if (parent < 0) { return -FDT_ERR_BADOFFSET; } ac = fdt_address_cells(dtb, parent); sc = fdt_size_cells(dtb, parent); cell = index * (ac + sc); prop = fdt_getprop(dtb, node, "reg", &len); if (prop == NULL) { WARN("Couldn't find \"reg\" property in dtb\n"); return -FDT_ERR_NOTFOUND; } if (((cell + ac + sc) * (int)sizeof(uint32_t)) > len) { return -FDT_ERR_BADVALUE; } if (base != NULL) { *base = (uintptr_t)fdt_read_prop_cells(&prop[cell], ac); } if (size != NULL) { *size = (size_t)fdt_read_prop_cells(&prop[cell + ac], sc); } return 0; } /******************************************************************************* * This function fills reg node info (base & size) with an index found by * checking the reg-names node. * Returns 0 on success and a negative FDT error code on failure. ******************************************************************************/ int fdt_get_reg_props_by_name(const void *dtb, int node, const char *name, uintptr_t *base, size_t *size) { int index; index = fdt_stringlist_search(dtb, node, "reg-names", name); if (index < 0) { return index; } return fdt_get_reg_props_by_index(dtb, node, index, base, size); } /******************************************************************************* * This function gets the stdout path node. * It reads the value indicated inside the device tree. * Returns node offset on success and a negative FDT error code on failure. ******************************************************************************/ int fdt_get_stdout_node_offset(const void *dtb) { int node; const char *prop, *path; int len; /* The /secure-chosen node takes precedence over the standard one. */ node = fdt_path_offset(dtb, "/secure-chosen"); if (node < 0) { node = fdt_path_offset(dtb, "/chosen"); if (node < 0) { return -FDT_ERR_NOTFOUND; } } prop = fdt_getprop(dtb, node, "stdout-path", NULL); if (prop == NULL) { return -FDT_ERR_NOTFOUND; } /* Determine the actual path length, as a colon terminates the path. */ path = strchr(prop, ':'); if (path == NULL) { len = strlen(prop); } else { len = path - prop; } /* Aliases cannot start with a '/', so it must be the actual path. */ if (prop[0] == '/') { return fdt_path_offset_namelen(dtb, prop, len); } /* Lookup the alias, as this contains the actual path. */ path = fdt_get_alias_namelen(dtb, prop, len); if (path == NULL) { return -FDT_ERR_NOTFOUND; } return fdt_path_offset(dtb, path); } /******************************************************************************* * Only devices which are direct children of root node use CPU address domain. * All other devices use addresses that are local to the device node and cannot * directly used by CPU. Device tree provides an address translation mechanism * through "ranges" property which provides mappings from local address space to * parent address space. Since a device could be a child of a child node to the * root node, there can be more than one level of address translation needed to * map the device local address space to CPU address space. * fdtw_translate_address() API performs address translation of a local address * to a global address with help of various helper functions. ******************************************************************************/ static bool fdtw_xlat_hit(const uint32_t *value, int child_addr_size, int parent_addr_size, int range_size, uint64_t base_address, uint64_t *translated_addr) { uint64_t local_address, parent_address, addr_range; local_address = fdt_read_prop_cells(value, child_addr_size); parent_address = fdt_read_prop_cells(value + child_addr_size, parent_addr_size); addr_range = fdt_read_prop_cells(value + child_addr_size + parent_addr_size, range_size); VERBOSE("DT: Address %" PRIx64 " mapped to %" PRIx64 " with range %" PRIx64 "\n", local_address, parent_address, addr_range); /* Perform range check */ if ((base_address < local_address) || (base_address >= local_address + addr_range)) { return false; } /* Found hit for the addr range that needs to be translated */ *translated_addr = parent_address + (base_address - local_address); VERBOSE("DT: child address %" PRIx64 "mapped to %" PRIx64 " in parent bus\n", local_address, parent_address); return true; } #define ILLEGAL_ADDR ULL(~0) static uint64_t fdtw_search_all_xlat_entries(const void *dtb, const struct fdt_property *ranges_prop, int local_bus, uint64_t base_address) { uint64_t translated_addr; const uint32_t *next_entry; int parent_bus_node, nxlat_entries, length; int self_addr_cells, parent_addr_cells, self_size_cells, ncells_xlat; /* * The number of cells in one translation entry in ranges is the sum of * the following values: * self#address-cells + parent#address-cells + self#size-cells * Ex: the iofpga ranges property has one translation entry with 4 cells * They represent iofpga#addr-cells + motherboard#addr-cells + iofpga#size-cells * = 1 + 2 + 1 */ parent_bus_node = fdt_parent_offset(dtb, local_bus); self_addr_cells = fdt_address_cells(dtb, local_bus); self_size_cells = fdt_size_cells(dtb, local_bus); parent_addr_cells = fdt_address_cells(dtb, parent_bus_node); /* Number of cells per translation entry i.e., mapping */ ncells_xlat = self_addr_cells + parent_addr_cells + self_size_cells; assert(ncells_xlat > 0); /* * Find the number of translations(mappings) specified in the current * `ranges` property. Note that length represents number of bytes and * is stored in big endian mode. */ length = fdt32_to_cpu(ranges_prop->len); nxlat_entries = (length/sizeof(uint32_t))/ncells_xlat; assert(nxlat_entries > 0); next_entry = (const uint32_t *)ranges_prop->data; /* Iterate over the entries in the "ranges" */ for (int i = 0; i < nxlat_entries; i++) { if (fdtw_xlat_hit(next_entry, self_addr_cells, parent_addr_cells, self_size_cells, base_address, &translated_addr)){ return translated_addr; } next_entry = next_entry + ncells_xlat; } INFO("DT: No translation found for address %" PRIx64 " in node %s\n", base_address, fdt_get_name(dtb, local_bus, NULL)); return ILLEGAL_ADDR; } /******************************************************************************* * address mapping needs to be done recursively starting from current node to * root node through all intermediate parent nodes. * Sample device tree is shown here: smb@0,0 { compatible = "simple-bus"; #address-cells = <2>; #size-cells = <1>; ranges = <0 0 0 0x08000000 0x04000000>, <1 0 0 0x14000000 0x04000000>, <2 0 0 0x18000000 0x04000000>, <3 0 0 0x1c000000 0x04000000>, <4 0 0 0x0c000000 0x04000000>, <5 0 0 0x10000000 0x04000000>; motherboard { arm,v2m-memory-map = "rs1"; compatible = "arm,vexpress,v2m-p1", "simple-bus"; #address-cells = <2>; #size-cells = <1>; ranges; iofpga@3,00000000 { compatible = "arm,amba-bus", "simple-bus"; #address-cells = <1>; #size-cells = <1>; ranges = <0 3 0 0x200000>; v2m_serial1: uart@a0000 { compatible = "arm,pl011", "arm,primecell"; reg = <0x0a0000 0x1000>; interrupts = <0 6 4>; clocks = <&v2m_clk24mhz>, <&v2m_clk24mhz>; clock-names = "uartclk", "apb_pclk"; }; }; }; * As seen above, there are 3 levels of address translations needed. An empty * `ranges` property denotes identity mapping (as seen in `motherboard` node). * Each ranges property can map a set of child addresses to parent bus. Hence * there can be more than 1 (translation) entry in the ranges property as seen * in the `smb` node which has 6 translation entries. ******************************************************************************/ /* Recursive implementation */ uint64_t fdtw_translate_address(const void *dtb, int node, uint64_t base_address) { int length, local_bus_node; const char *node_name; uint64_t global_address; local_bus_node = fdt_parent_offset(dtb, node); node_name = fdt_get_name(dtb, local_bus_node, NULL); /* * In the example given above, starting from the leaf node: * uart@a000 represents the current node * iofpga@3,00000000 represents the local bus * motherboard represents the parent bus */ /* Read the ranges property */ const struct fdt_property *property = fdt_get_property(dtb, local_bus_node, "ranges", &length); if (property == NULL) { if (local_bus_node == 0) { /* * root node doesn't have range property as addresses * are in CPU address space. */ return base_address; } INFO("DT: Couldn't find ranges property in node %s\n", node_name); return ILLEGAL_ADDR; } else if (length == 0) { /* empty ranges indicates identity map to parent bus */ return fdtw_translate_address(dtb, local_bus_node, base_address); } VERBOSE("DT: Translation lookup in node %s at offset %d\n", node_name, local_bus_node); global_address = fdtw_search_all_xlat_entries(dtb, property, local_bus_node, base_address); if (global_address == ILLEGAL_ADDR) { return ILLEGAL_ADDR; } /* Translate the local device address recursively */ return fdtw_translate_address(dtb, local_bus_node, global_address); } /* * For every CPU node (`/cpus/cpu@n`) in an FDT, execute a callback passing a * pointer to the FDT and the offset of the CPU node. If the return value of the * callback is negative, it is treated as an error and the loop is aborted. In * this situation, the value of the callback is returned from the function. * * Returns `0` on success, or a negative integer representing an error code. */ int fdtw_for_each_cpu(const void *dtb, int (*callback)(const void *dtb, int node, uintptr_t mpidr)) { int ret = 0; int parent, node = 0; parent = fdt_path_offset(dtb, "/cpus"); if (parent < 0) { return parent; } fdt_for_each_subnode(node, dtb, parent) { const char *name; int len; uintptr_t mpidr = 0U; name = fdt_get_name(dtb, node, &len); if (strncmp(name, "cpu@", 4) != 0) { continue; } ret = fdt_get_reg_props_by_index(dtb, node, 0, &mpidr, NULL); if (ret < 0) { break; } ret = callback(dtb, node, mpidr); if (ret < 0) { break; } } return ret; } /* * Find a given node in device tree. If not present, add it. * Returns offset of node found/added on success, and < 0 on error. */ int fdtw_find_or_add_subnode(void *fdt, int parentoffset, const char *name) { int offset; offset = fdt_subnode_offset(fdt, parentoffset, name); if (offset == -FDT_ERR_NOTFOUND) { offset = fdt_add_subnode(fdt, parentoffset, name); } if (offset < 0) { ERROR("%s: %s: %s\n", __func__, name, fdt_strerror(offset)); } return offset; }