/* * Copyright (c) 2008 Jiri Svoboda * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * - Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * - 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. * - The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 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. */ /** @addtogroup rtld * @brief * @{ */ /** * @file */ #include #include #include #include #include #include rtld_t *runtime_env; static rtld_t rt_env_static; /** Initialize the runtime linker for use in a statically-linked executable. */ errno_t rtld_init_static(void) { errno_t rc; runtime_env = &rt_env_static; list_initialize(&runtime_env->modules); list_initialize(&runtime_env->imodules); runtime_env->program = NULL; runtime_env->next_id = 1; rc = module_create_static_exec(runtime_env, NULL); if (rc != EOK) return rc; modules_process_tls(runtime_env); return EOK; } /** Initialize and process a dynamically linked executable. * * @param p_info Program info * @return EOK on success or non-zero error code */ errno_t rtld_prog_process(elf_finfo_t *p_info, rtld_t **rre) { rtld_t *env; module_t *prog; DPRINTF("Load dynamically linked program.\n"); /* Allocate new RTLD environment to pass to the loaded program */ env = calloc(1, sizeof(rtld_t)); if (env == NULL) return ENOMEM; env->next_id = 1; prog = calloc(1, sizeof(module_t)); if (prog == NULL) { free(env); return ENOMEM; } /* * First we need to process dynamic sections of the executable * program and insert it into the module graph. */ DPRINTF("Parse program .dynamic section at %p\n", p_info->dynamic); dynamic_parse(p_info->dynamic, 0, &prog->dyn); prog->bias = 0; prog->dyn.soname = "[program]"; prog->rtld = env; prog->id = rtld_get_next_id(env); prog->exec = true; prog->local = false; prog->tdata = p_info->tls.tdata; prog->tdata_size = p_info->tls.tdata_size; prog->tbss_size = p_info->tls.tbss_size; prog->tls_align = p_info->tls.tls_align; DPRINTF("prog tdata at %p size %zu, tbss size %zu\n", prog->tdata, prog->tdata_size, prog->tbss_size); /* Initialize list of loaded modules */ list_initialize(&env->modules); list_initialize(&env->imodules); list_append(&prog->modules_link, &env->modules); /* Pointer to program module. Used as root of the module graph. */ env->program = prog; /* * Now we can continue with loading all other modules. */ DPRINTF("Load all program dependencies\n"); module_load_deps(prog, 0); /* Compute static TLS size */ modules_process_tls(env); /* * Now relocate/link all modules together. */ /* Process relocations in all modules */ DPRINTF("Relocate all modules\n"); modules_process_relocs(env, prog); *rre = env; return EOK; } /** Create TLS (Thread Local Storage) data structures. * * @return Pointer to TCB. */ tcb_t *rtld_tls_make(rtld_t *rtld) { tcb_t *tcb; void **dtv; size_t nmods; size_t i; tcb = tls_alloc_arch(rtld->tls_size, rtld->tls_align); if (tcb == NULL) return NULL; /** Allocate dynamic thread vector */ nmods = list_count(&rtld->imodules); dtv = malloc((nmods + 1) * sizeof(void *)); if (dtv == NULL) { tls_free(tcb); return NULL; } /* * We define generation number to be equal to vector length. * We start with a vector covering the initially loaded modules. */ DTV_GN(dtv) = nmods; /* * Copy thread local data from the initialization images of initial * modules. Zero out thread-local uninitialized data. */ i = 1; list_foreach(rtld->imodules, imodules_link, module_t, m) { assert(i++ == m->id); dtv[m->id] = (void *) tcb + m->tpoff; assert(((uintptr_t) dtv[m->id]) % m->tls_align == 0); memcpy(dtv[m->id], m->tdata, m->tdata_size); memset(dtv[m->id] + m->tdata_size, 0, m->tbss_size); } tcb->dtv = dtv; return tcb; } unsigned long rtld_get_next_id(rtld_t *rtld) { return rtld->next_id++; } /** Get address of thread-local variable. * * @param rtld RTLD instance * @param tcb TCB of the thread whose instance to return * @param mod_id Module ID * @param offset Offset within TLS block of the module * * @return Address of thread-local variable */ void *rtld_tls_get_addr(rtld_t *rtld, tcb_t *tcb, unsigned long mod_id, unsigned long offset) { module_t *m; size_t dtv_len; void *tls_block; dtv_len = DTV_GN(tcb->dtv); if (dtv_len < mod_id) { /* Vector is short */ tcb->dtv = realloc(tcb->dtv, (1 + mod_id) * sizeof(void *)); /* XXX This can fail if OOM */ assert(tcb->dtv != NULL); /* Zero out new part of vector */ memset(tcb->dtv + (1 + dtv_len), 0, (mod_id - dtv_len) * sizeof(void *)); } if (tcb->dtv[mod_id] == NULL) { /* TLS block is not allocated */ m = module_by_id(rtld, mod_id); assert(m != NULL); /* Should not be initial module, those have TLS pre-allocated */ assert(!link_used(&m->imodules_link)); tls_block = memalign(m->tls_align, m->tdata_size + m->tbss_size); /* XXX This can fail if OOM */ assert(tls_block != NULL); /* Copy tdata */ memcpy(tls_block, m->tdata, m->tdata_size); /* Zero out tbss */ memset(tls_block + m->tdata_size, 0, m->tbss_size); tcb->dtv[mod_id] = tls_block; } return (uint8_t *)(tcb->dtv[mod_id]) + offset; } /** @} */