// SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause) /* Copyright (C) 2015-2018 Netronome Systems, Inc. */ /* * nfp_rtsym.c * Interface for accessing run-time symbol table * Authors: Jakub Kicinski * Jason McMullan * Espen Skoglund * Francois H. Theron */ #include #include #include #include #include #include "nfp.h" #include "nfp_cpp.h" #include "nfp_nffw.h" #include "nfp6000/nfp6000.h" /* These need to match the linker */ #define SYM_TGT_LMEM 0 #define SYM_TGT_EMU_CACHE 0x17 struct nfp_rtsym_entry { u8 type; u8 target; u8 island; u8 addr_hi; __le32 addr_lo; __le16 name; u8 menum; u8 size_hi; __le32 size_lo; }; struct nfp_rtsym_table { struct nfp_cpp *cpp; int num; char *strtab; struct nfp_rtsym symtab[]; }; static int nfp_meid(u8 island_id, u8 menum) { return (island_id & 0x3F) == island_id && menum < 12 ? (island_id << 4) | (menum + 4) : -1; } static void nfp_rtsym_sw_entry_init(struct nfp_rtsym_table *cache, u32 strtab_size, struct nfp_rtsym *sw, struct nfp_rtsym_entry *fw) { sw->type = fw->type; sw->name = cache->strtab + le16_to_cpu(fw->name) % strtab_size; sw->addr = ((u64)fw->addr_hi << 32) | le32_to_cpu(fw->addr_lo); sw->size = ((u64)fw->size_hi << 32) | le32_to_cpu(fw->size_lo); switch (fw->target) { case SYM_TGT_LMEM: sw->target = NFP_RTSYM_TARGET_LMEM; break; case SYM_TGT_EMU_CACHE: sw->target = NFP_RTSYM_TARGET_EMU_CACHE; break; default: sw->target = fw->target; break; } if (fw->menum != 0xff) sw->domain = nfp_meid(fw->island, fw->menum); else if (fw->island != 0xff) sw->domain = fw->island; else sw->domain = -1; } struct nfp_rtsym_table *nfp_rtsym_table_read(struct nfp_cpp *cpp) { struct nfp_rtsym_table *rtbl; const struct nfp_mip *mip; mip = nfp_mip_open(cpp); rtbl = __nfp_rtsym_table_read(cpp, mip); nfp_mip_close(mip); return rtbl; } struct nfp_rtsym_table * __nfp_rtsym_table_read(struct nfp_cpp *cpp, const struct nfp_mip *mip) { const u32 dram = NFP_CPP_ID(NFP_CPP_TARGET_MU, NFP_CPP_ACTION_RW, 0) | NFP_ISL_EMEM0; u32 strtab_addr, symtab_addr, strtab_size, symtab_size; struct nfp_rtsym_entry *rtsymtab; struct nfp_rtsym_table *cache; int err, n, size; if (!mip) return NULL; nfp_mip_strtab(mip, &strtab_addr, &strtab_size); nfp_mip_symtab(mip, &symtab_addr, &symtab_size); if (!symtab_size || !strtab_size || symtab_size % sizeof(*rtsymtab)) return NULL; /* Align to 64 bits */ symtab_size = round_up(symtab_size, 8); strtab_size = round_up(strtab_size, 8); rtsymtab = kmalloc(symtab_size, GFP_KERNEL); if (!rtsymtab) return NULL; size = sizeof(*cache); size += symtab_size / sizeof(*rtsymtab) * sizeof(struct nfp_rtsym); size += strtab_size + 1; cache = kmalloc(size, GFP_KERNEL); if (!cache) goto exit_free_rtsym_raw; cache->cpp = cpp; cache->num = symtab_size / sizeof(*rtsymtab); cache->strtab = (void *)&cache->symtab[cache->num]; err = nfp_cpp_read(cpp, dram, symtab_addr, rtsymtab, symtab_size); if (err != symtab_size) goto exit_free_cache; err = nfp_cpp_read(cpp, dram, strtab_addr, cache->strtab, strtab_size); if (err != strtab_size) goto exit_free_cache; cache->strtab[strtab_size] = '\0'; for (n = 0; n < cache->num; n++) nfp_rtsym_sw_entry_init(cache, strtab_size, &cache->symtab[n], &rtsymtab[n]); kfree(rtsymtab); return cache; exit_free_cache: kfree(cache); exit_free_rtsym_raw: kfree(rtsymtab); return NULL; } /** * nfp_rtsym_count() - Get the number of RTSYM descriptors * @rtbl: NFP RTsym table * * Return: Number of RTSYM descriptors */ int nfp_rtsym_count(struct nfp_rtsym_table *rtbl) { if (!rtbl) return -EINVAL; return rtbl->num; } /** * nfp_rtsym_get() - Get the Nth RTSYM descriptor * @rtbl: NFP RTsym table * @idx: Index (0-based) of the RTSYM descriptor * * Return: const pointer to a struct nfp_rtsym descriptor, or NULL */ const struct nfp_rtsym *nfp_rtsym_get(struct nfp_rtsym_table *rtbl, int idx) { if (!rtbl) return NULL; if (idx >= rtbl->num) return NULL; return &rtbl->symtab[idx]; } /** * nfp_rtsym_lookup() - Return the RTSYM descriptor for a symbol name * @rtbl: NFP RTsym table * @name: Symbol name * * Return: const pointer to a struct nfp_rtsym descriptor, or NULL */ const struct nfp_rtsym * nfp_rtsym_lookup(struct nfp_rtsym_table *rtbl, const char *name) { int n; if (!rtbl) return NULL; for (n = 0; n < rtbl->num; n++) if (strcmp(name, rtbl->symtab[n].name) == 0) return &rtbl->symtab[n]; return NULL; } u64 nfp_rtsym_size(const struct nfp_rtsym *sym) { switch (sym->type) { case NFP_RTSYM_TYPE_NONE: pr_err("rtsym '%s': type NONE\n", sym->name); return 0; default: pr_warn("rtsym '%s': unknown type: %d\n", sym->name, sym->type); /* fall through */ case NFP_RTSYM_TYPE_OBJECT: case NFP_RTSYM_TYPE_FUNCTION: return sym->size; case NFP_RTSYM_TYPE_ABS: return sizeof(u64); } } static int nfp_rtsym_to_dest(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u8 action, u8 token, u64 off, u32 *cpp_id, u64 *addr) { if (sym->type != NFP_RTSYM_TYPE_OBJECT) { nfp_err(cpp, "rtsym '%s': direct access to non-object rtsym\n", sym->name); return -EINVAL; } *addr = sym->addr + off; if (sym->target == NFP_RTSYM_TARGET_EMU_CACHE) { int locality_off = nfp_cpp_mu_locality_lsb(cpp); *addr &= ~(NFP_MU_ADDR_ACCESS_TYPE_MASK << locality_off); *addr |= NFP_MU_ADDR_ACCESS_TYPE_DIRECT << locality_off; *cpp_id = NFP_CPP_ISLAND_ID(NFP_CPP_TARGET_MU, action, token, sym->domain); } else if (sym->target < 0) { nfp_err(cpp, "rtsym '%s': unhandled target encoding: %d\n", sym->name, sym->target); return -EINVAL; } else { *cpp_id = NFP_CPP_ISLAND_ID(sym->target, action, token, sym->domain); } return 0; } int __nfp_rtsym_read(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u8 action, u8 token, u64 off, void *buf, size_t len) { u64 sym_size = nfp_rtsym_size(sym); u32 cpp_id; u64 addr; int err; if (off > sym_size) { nfp_err(cpp, "rtsym '%s': read out of bounds: off: %lld + len: %zd > size: %lld\n", sym->name, off, len, sym_size); return -ENXIO; } len = min_t(size_t, len, sym_size - off); if (sym->type == NFP_RTSYM_TYPE_ABS) { u8 tmp[8]; put_unaligned_le64(sym->addr, tmp); memcpy(buf, &tmp[off], len); return len; } err = nfp_rtsym_to_dest(cpp, sym, action, token, off, &cpp_id, &addr); if (err) return err; return nfp_cpp_read(cpp, cpp_id, addr, buf, len); } int nfp_rtsym_read(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u64 off, void *buf, size_t len) { return __nfp_rtsym_read(cpp, sym, NFP_CPP_ACTION_RW, 0, off, buf, len); } int __nfp_rtsym_readl(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u8 action, u8 token, u64 off, u32 *value) { u32 cpp_id; u64 addr; int err; if (off + 4 > nfp_rtsym_size(sym)) { nfp_err(cpp, "rtsym '%s': readl out of bounds: off: %lld + 4 > size: %lld\n", sym->name, off, nfp_rtsym_size(sym)); return -ENXIO; } err = nfp_rtsym_to_dest(cpp, sym, action, token, off, &cpp_id, &addr); if (err) return err; return nfp_cpp_readl(cpp, cpp_id, addr, value); } int nfp_rtsym_readl(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u64 off, u32 *value) { return __nfp_rtsym_readl(cpp, sym, NFP_CPP_ACTION_RW, 0, off, value); } int __nfp_rtsym_readq(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u8 action, u8 token, u64 off, u64 *value) { u32 cpp_id; u64 addr; int err; if (off + 8 > nfp_rtsym_size(sym)) { nfp_err(cpp, "rtsym '%s': readq out of bounds: off: %lld + 8 > size: %lld\n", sym->name, off, nfp_rtsym_size(sym)); return -ENXIO; } if (sym->type == NFP_RTSYM_TYPE_ABS) { *value = sym->addr; return 0; } err = nfp_rtsym_to_dest(cpp, sym, action, token, off, &cpp_id, &addr); if (err) return err; return nfp_cpp_readq(cpp, cpp_id, addr, value); } int nfp_rtsym_readq(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u64 off, u64 *value) { return __nfp_rtsym_readq(cpp, sym, NFP_CPP_ACTION_RW, 0, off, value); } int __nfp_rtsym_write(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u8 action, u8 token, u64 off, void *buf, size_t len) { u64 sym_size = nfp_rtsym_size(sym); u32 cpp_id; u64 addr; int err; if (off > sym_size) { nfp_err(cpp, "rtsym '%s': write out of bounds: off: %lld + len: %zd > size: %lld\n", sym->name, off, len, sym_size); return -ENXIO; } len = min_t(size_t, len, sym_size - off); err = nfp_rtsym_to_dest(cpp, sym, action, token, off, &cpp_id, &addr); if (err) return err; return nfp_cpp_write(cpp, cpp_id, addr, buf, len); } int nfp_rtsym_write(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u64 off, void *buf, size_t len) { return __nfp_rtsym_write(cpp, sym, NFP_CPP_ACTION_RW, 0, off, buf, len); } int __nfp_rtsym_writel(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u8 action, u8 token, u64 off, u32 value) { u32 cpp_id; u64 addr; int err; if (off + 4 > nfp_rtsym_size(sym)) { nfp_err(cpp, "rtsym '%s': writel out of bounds: off: %lld + 4 > size: %lld\n", sym->name, off, nfp_rtsym_size(sym)); return -ENXIO; } err = nfp_rtsym_to_dest(cpp, sym, action, token, off, &cpp_id, &addr); if (err) return err; return nfp_cpp_writel(cpp, cpp_id, addr, value); } int nfp_rtsym_writel(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u64 off, u32 value) { return __nfp_rtsym_writel(cpp, sym, NFP_CPP_ACTION_RW, 0, off, value); } int __nfp_rtsym_writeq(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u8 action, u8 token, u64 off, u64 value) { u32 cpp_id; u64 addr; int err; if (off + 8 > nfp_rtsym_size(sym)) { nfp_err(cpp, "rtsym '%s': writeq out of bounds: off: %lld + 8 > size: %lld\n", sym->name, off, nfp_rtsym_size(sym)); return -ENXIO; } err = nfp_rtsym_to_dest(cpp, sym, action, token, off, &cpp_id, &addr); if (err) return err; return nfp_cpp_writeq(cpp, cpp_id, addr, value); } int nfp_rtsym_writeq(struct nfp_cpp *cpp, const struct nfp_rtsym *sym, u64 off, u64 value) { return __nfp_rtsym_writeq(cpp, sym, NFP_CPP_ACTION_RW, 0, off, value); } /** * nfp_rtsym_read_le() - Read a simple unsigned scalar value from symbol * @rtbl: NFP RTsym table * @name: Symbol name * @error: Poniter to error code (optional) * * Lookup a symbol, map, read it and return it's value. Value of the symbol * will be interpreted as a simple little-endian unsigned value. Symbol can * be 4 or 8 bytes in size. * * Return: value read, on error sets the error and returns ~0ULL. */ u64 nfp_rtsym_read_le(struct nfp_rtsym_table *rtbl, const char *name, int *error) { const struct nfp_rtsym *sym; u32 val32; u64 val; int err; sym = nfp_rtsym_lookup(rtbl, name); if (!sym) { err = -ENOENT; goto exit; } switch (nfp_rtsym_size(sym)) { case 4: err = nfp_rtsym_readl(rtbl->cpp, sym, 0, &val32); val = val32; break; case 8: err = nfp_rtsym_readq(rtbl->cpp, sym, 0, &val); break; default: nfp_err(rtbl->cpp, "rtsym '%s': unsupported or non-scalar size: %lld\n", name, nfp_rtsym_size(sym)); err = -EINVAL; break; } exit: if (error) *error = err; if (err) return ~0ULL; return val; } /** * nfp_rtsym_write_le() - Write an unsigned scalar value to a symbol * @rtbl: NFP RTsym table * @name: Symbol name * @value: Value to write * * Lookup a symbol and write a value to it. Symbol can be 4 or 8 bytes in size. * If 4 bytes then the lower 32-bits of 'value' are used. Value will be * written as simple little-endian unsigned value. * * Return: 0 on success or error code. */ int nfp_rtsym_write_le(struct nfp_rtsym_table *rtbl, const char *name, u64 value) { const struct nfp_rtsym *sym; int err; sym = nfp_rtsym_lookup(rtbl, name); if (!sym) return -ENOENT; switch (nfp_rtsym_size(sym)) { case 4: err = nfp_rtsym_writel(rtbl->cpp, sym, 0, value); break; case 8: err = nfp_rtsym_writeq(rtbl->cpp, sym, 0, value); break; default: nfp_err(rtbl->cpp, "rtsym '%s': unsupported or non-scalar size: %lld\n", name, nfp_rtsym_size(sym)); err = -EINVAL; break; } return err; } u8 __iomem * nfp_rtsym_map(struct nfp_rtsym_table *rtbl, const char *name, const char *id, unsigned int min_size, struct nfp_cpp_area **area) { const struct nfp_rtsym *sym; u8 __iomem *mem; u32 cpp_id; u64 addr; int err; sym = nfp_rtsym_lookup(rtbl, name); if (!sym) return (u8 __iomem *)ERR_PTR(-ENOENT); err = nfp_rtsym_to_dest(rtbl->cpp, sym, NFP_CPP_ACTION_RW, 0, 0, &cpp_id, &addr); if (err) { nfp_err(rtbl->cpp, "rtsym '%s': mapping failed\n", name); return (u8 __iomem *)ERR_PTR(err); } if (sym->size < min_size) { nfp_err(rtbl->cpp, "rtsym '%s': too small\n", name); return (u8 __iomem *)ERR_PTR(-EINVAL); } mem = nfp_cpp_map_area(rtbl->cpp, id, cpp_id, addr, sym->size, area); if (IS_ERR(mem)) { nfp_err(rtbl->cpp, "rtysm '%s': failed to map: %ld\n", name, PTR_ERR(mem)); return mem; } return mem; }