// SPDX-License-Identifier: GPL-2.0-or-later /*************************************************************************** * Copyright (C) 2017 by Intel Corporation * Leandro Pereira * Daniel Glöckner * * Copyright (C) 2021 by Synopsys, Inc. * Evgeniy Didin ***************************************************************************/ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include "helper/log.h" #include "helper/types.h" #include "rtos.h" #include "rtos_standard_stackings.h" #include "target/target.h" #include "target/target_type.h" #include "target/armv7m.h" #include "target/arc.h" #define UNIMPLEMENTED 0xFFFFFFFFU /* ARC specific defines */ #define ARC_AUX_SEC_BUILD_REG 0xdb #define ARC_REG_NUM 38 /* ARM specific defines */ #define ARM_XPSR_OFFSET 28 struct zephyr_thread { uint32_t ptr, next_ptr; uint32_t entry; uint32_t stack_pointer; uint8_t state; uint8_t user_options; int8_t prio; char name[64]; }; enum zephyr_offsets { OFFSET_VERSION, OFFSET_K_CURR_THREAD, OFFSET_K_THREADS, OFFSET_T_ENTRY, OFFSET_T_NEXT_THREAD, OFFSET_T_STATE, OFFSET_T_USER_OPTIONS, OFFSET_T_PRIO, OFFSET_T_STACK_POINTER, OFFSET_T_NAME, OFFSET_T_ARCH, OFFSET_T_PREEMPT_FLOAT, OFFSET_T_COOP_FLOAT, OFFSET_T_ARM_EXC_RETURN, OFFSET_MAX }; struct zephyr_params { const char *target_name; uint8_t size_width; uint8_t pointer_width; uint32_t num_offsets; uint32_t offsets[OFFSET_MAX]; const struct rtos_register_stacking *callee_saved_stacking; const struct rtos_register_stacking *cpu_saved_nofp_stacking; const struct rtos_register_stacking *cpu_saved_fp_stacking; int (*get_cpu_state)(struct rtos *rtos, target_addr_t *addr, struct zephyr_params *params, struct rtos_reg *callee_saved_reg_list, struct rtos_reg **reg_list, int *num_regs); }; static const struct stack_register_offset arm_callee_saved[] = { { ARMV7M_R13, 32, 32 }, { ARMV7M_R4, 0, 32 }, { ARMV7M_R5, 4, 32 }, { ARMV7M_R6, 8, 32 }, { ARMV7M_R7, 12, 32 }, { ARMV7M_R8, 16, 32 }, { ARMV7M_R9, 20, 32 }, { ARMV7M_R10, 24, 32 }, { ARMV7M_R11, 28, 32 }, }; static const struct stack_register_offset arc_callee_saved[] = { { ARC_R13, 0, 32 }, { ARC_R14, 4, 32 }, { ARC_R15, 8, 32 }, { ARC_R16, 12, 32 }, { ARC_R17, 16, 32 }, { ARC_R18, 20, 32 }, { ARC_R19, 24, 32 }, { ARC_R20, 28, 32 }, { ARC_R21, 32, 32 }, { ARC_R22, 36, 32 }, { ARC_R23, 40, 32 }, { ARC_R24, 44, 32 }, { ARC_R25, 48, 32 }, { ARC_GP, 52, 32 }, { ARC_FP, 56, 32 }, { ARC_R30, 60, 32 } }; static const struct rtos_register_stacking arm_callee_saved_stacking = { .stack_registers_size = 36, .stack_growth_direction = -1, .num_output_registers = ARRAY_SIZE(arm_callee_saved), .register_offsets = arm_callee_saved, }; static const struct rtos_register_stacking arc_callee_saved_stacking = { .stack_registers_size = 64, .stack_growth_direction = -1, .num_output_registers = ARRAY_SIZE(arc_callee_saved), .register_offsets = arc_callee_saved, }; static const struct stack_register_offset arm_cpu_saved[] = { { ARMV7M_R0, 0, 32 }, { ARMV7M_R1, 4, 32 }, { ARMV7M_R2, 8, 32 }, { ARMV7M_R3, 12, 32 }, { ARMV7M_R4, -1, 32 }, { ARMV7M_R5, -1, 32 }, { ARMV7M_R6, -1, 32 }, { ARMV7M_R7, -1, 32 }, { ARMV7M_R8, -1, 32 }, { ARMV7M_R9, -1, 32 }, { ARMV7M_R10, -1, 32 }, { ARMV7M_R11, -1, 32 }, { ARMV7M_R12, 16, 32 }, { ARMV7M_R13, -2, 32 }, { ARMV7M_R14, 20, 32 }, { ARMV7M_PC, 24, 32 }, { ARMV7M_XPSR, 28, 32 }, }; static struct stack_register_offset arc_cpu_saved[] = { { ARC_R0, -1, 32 }, { ARC_R1, -1, 32 }, { ARC_R2, -1, 32 }, { ARC_R3, -1, 32 }, { ARC_R4, -1, 32 }, { ARC_R5, -1, 32 }, { ARC_R6, -1, 32 }, { ARC_R7, -1, 32 }, { ARC_R8, -1, 32 }, { ARC_R9, -1, 32 }, { ARC_R10, -1, 32 }, { ARC_R11, -1, 32 }, { ARC_R12, -1, 32 }, { ARC_R13, -1, 32 }, { ARC_R14, -1, 32 }, { ARC_R15, -1, 32 }, { ARC_R16, -1, 32 }, { ARC_R17, -1, 32 }, { ARC_R18, -1, 32 }, { ARC_R19, -1, 32 }, { ARC_R20, -1, 32 }, { ARC_R21, -1, 32 }, { ARC_R22, -1, 32 }, { ARC_R23, -1, 32 }, { ARC_R24, -1, 32 }, { ARC_R25, -1, 32 }, { ARC_GP, -1, 32 }, { ARC_FP, -1, 32 }, { ARC_SP, -1, 32 }, { ARC_ILINK, -1, 32 }, { ARC_R30, -1, 32 }, { ARC_BLINK, 0, 32 }, { ARC_LP_COUNT, -1, 32 }, { ARC_PCL, -1, 32 }, { ARC_PC, -1, 32 }, { ARC_LP_START, -1, 32 }, { ARC_LP_END, -1, 32 }, { ARC_STATUS32, 4, 32 } }; enum zephyr_symbol_values { ZEPHYR_VAL__KERNEL, ZEPHYR_VAL__KERNEL_OPENOCD_OFFSETS, ZEPHYR_VAL__KERNEL_OPENOCD_SIZE_T_SIZE, ZEPHYR_VAL__KERNEL_OPENOCD_NUM_OFFSETS, ZEPHYR_VAL_COUNT }; static target_addr_t zephyr_cortex_m_stack_align(struct target *target, const uint8_t *stack_data, const struct rtos_register_stacking *stacking, target_addr_t stack_ptr) { return rtos_cortex_m_stack_align(target, stack_data, stacking, stack_ptr, ARM_XPSR_OFFSET); } static const struct rtos_register_stacking arm_cpu_saved_nofp_stacking = { .stack_registers_size = 32, .stack_growth_direction = -1, .num_output_registers = ARRAY_SIZE(arm_cpu_saved), .calculate_process_stack = zephyr_cortex_m_stack_align, .register_offsets = arm_cpu_saved, }; static const struct rtos_register_stacking arm_cpu_saved_fp_stacking = { .stack_registers_size = 32 + 18 * 4, .stack_growth_direction = -1, .num_output_registers = ARRAY_SIZE(arm_cpu_saved), .calculate_process_stack = zephyr_cortex_m_stack_align, .register_offsets = arm_cpu_saved, }; /* stack_registers_size is 8 because besides caller registers * there are only blink and Status32 registers on stack left */ static struct rtos_register_stacking arc_cpu_saved_stacking = { .stack_registers_size = 8, .stack_growth_direction = -1, .num_output_registers = ARRAY_SIZE(arc_cpu_saved), .register_offsets = arc_cpu_saved, }; /* ARCv2 specific implementation */ static int zephyr_get_arc_state(struct rtos *rtos, target_addr_t *addr, struct zephyr_params *params, struct rtos_reg *callee_saved_reg_list, struct rtos_reg **reg_list, int *num_regs) { uint32_t real_stack_addr; int retval = 0; int num_callee_saved_regs; const struct rtos_register_stacking *stacking; /* Getting real stack address from Kernel thread struct */ retval = target_read_u32(rtos->target, *addr, &real_stack_addr); if (retval != ERROR_OK) return retval; /* Getting callee registers */ retval = rtos_generic_stack_read(rtos->target, params->callee_saved_stacking, real_stack_addr, &callee_saved_reg_list, &num_callee_saved_regs); if (retval != ERROR_OK) return retval; stacking = params->cpu_saved_nofp_stacking; /* Getting blink and status32 registers */ retval = rtos_generic_stack_read(rtos->target, stacking, real_stack_addr + num_callee_saved_regs * 4, reg_list, num_regs); if (retval != ERROR_OK) return retval; for (int i = 0; i < num_callee_saved_regs; i++) buf_cpy(callee_saved_reg_list[i].value, (*reg_list)[callee_saved_reg_list[i].number].value, callee_saved_reg_list[i].size); /* The blink, sp, pc offsets in arc_cpu_saved structure may be changed, * but the registers number shall not. So the next code searches the * offsetst of these registers in arc_cpu_saved structure. */ unsigned short blink_offset = 0, pc_offset = 0, sp_offset = 0; for (size_t i = 0; i < ARRAY_SIZE(arc_cpu_saved); i++) { if (arc_cpu_saved[i].number == ARC_BLINK) blink_offset = i; if (arc_cpu_saved[i].number == ARC_SP) sp_offset = i; if (arc_cpu_saved[i].number == ARC_PC) pc_offset = i; } if (blink_offset == 0 || sp_offset == 0 || pc_offset == 0) { LOG_ERROR("Basic registers offsets are missing, check struct"); return ERROR_FAIL; } /* Put blink value into PC */ buf_cpy((*reg_list)[blink_offset].value, (*reg_list)[pc_offset].value, sizeof((*reg_list)[blink_offset].value)); /* Put address after callee/caller in SP. */ int64_t stack_top; stack_top = real_stack_addr + num_callee_saved_regs * 4 + arc_cpu_saved_stacking.stack_registers_size; buf_cpy(&stack_top, (*reg_list)[sp_offset].value, sizeof(stack_top)); return retval; } /* ARM Cortex-M-specific implementation */ static int zephyr_get_arm_state(struct rtos *rtos, target_addr_t *addr, struct zephyr_params *params, struct rtos_reg *callee_saved_reg_list, struct rtos_reg **reg_list, int *num_regs) { int retval = 0; int num_callee_saved_regs; const struct rtos_register_stacking *stacking; retval = rtos_generic_stack_read(rtos->target, params->callee_saved_stacking, *addr, &callee_saved_reg_list, &num_callee_saved_regs); if (retval != ERROR_OK) return retval; *addr = target_buffer_get_u32(rtos->target, callee_saved_reg_list[0].value); if (params->offsets[OFFSET_T_PREEMPT_FLOAT] != UNIMPLEMENTED) stacking = params->cpu_saved_fp_stacking; else stacking = params->cpu_saved_nofp_stacking; retval = rtos_generic_stack_read(rtos->target, stacking, *addr, reg_list, num_regs); if (retval != ERROR_OK) return retval; for (int i = 1; i < num_callee_saved_regs; i++) buf_cpy(callee_saved_reg_list[i].value, (*reg_list)[callee_saved_reg_list[i].number].value, callee_saved_reg_list[i].size); return 0; } static struct zephyr_params zephyr_params_list[] = { { .target_name = "cortex_m", .pointer_width = 4, .callee_saved_stacking = &arm_callee_saved_stacking, .cpu_saved_nofp_stacking = &arm_cpu_saved_nofp_stacking, .cpu_saved_fp_stacking = &arm_cpu_saved_fp_stacking, .get_cpu_state = &zephyr_get_arm_state, }, { .target_name = "cortex_r4", .pointer_width = 4, .callee_saved_stacking = &arm_callee_saved_stacking, .cpu_saved_nofp_stacking = &arm_cpu_saved_nofp_stacking, .cpu_saved_fp_stacking = &arm_cpu_saved_fp_stacking, .get_cpu_state = &zephyr_get_arm_state, }, { .target_name = "hla_target", .pointer_width = 4, .callee_saved_stacking = &arm_callee_saved_stacking, .cpu_saved_nofp_stacking = &arm_cpu_saved_nofp_stacking, .cpu_saved_fp_stacking = &arm_cpu_saved_fp_stacking, .get_cpu_state = &zephyr_get_arm_state, }, { .target_name = "arcv2", .pointer_width = 4, .callee_saved_stacking = &arc_callee_saved_stacking, .cpu_saved_nofp_stacking = &arc_cpu_saved_stacking, .get_cpu_state = &zephyr_get_arc_state, }, { .target_name = NULL } }; static const struct symbol_table_elem zephyr_symbol_list[] = { { .symbol_name = "_kernel", .optional = false }, { .symbol_name = "_kernel_thread_info_offsets", .optional = false }, { .symbol_name = "_kernel_thread_info_size_t_size", .optional = false }, { .symbol_name = "_kernel_thread_info_num_offsets", .optional = true }, { .symbol_name = NULL } }; static bool zephyr_detect_rtos(struct target *target) { if (!target->rtos->symbols) { LOG_INFO("Zephyr: no symbols while detecting RTOS"); return false; } for (enum zephyr_symbol_values symbol = ZEPHYR_VAL__KERNEL; symbol != ZEPHYR_VAL_COUNT; symbol++) { LOG_INFO("Zephyr: does it have symbol %d (%s)?", symbol, target->rtos->symbols[symbol].optional ? "optional" : "mandatory"); if (target->rtos->symbols[symbol].optional) continue; if (target->rtos->symbols[symbol].address == 0) return false; } LOG_INFO("Zephyr: all mandatory symbols found"); return true; } static int zephyr_create(struct target *target) { const char *name; name = target_type_name(target); LOG_INFO("Zephyr: looking for target: %s", name); /* ARC specific, check if EM target has security subsystem * In case of ARC_HAS_SECURE zephyr option enabled * the thread stack contains blink,sec_stat,status32 register * values. If ARC_HAS_SECURE is disabled, only blink and status32 * register values are saved on stack. */ if (!strcmp(name, "arcv2")) { uint32_t value; struct arc_common *arc = target_to_arc(target); /* Reading SEC_BUILD bcr */ CHECK_RETVAL(arc_jtag_read_aux_reg_one(&arc->jtag_info, ARC_AUX_SEC_BUILD_REG, &value)); if (value != 0) { LOG_DEBUG("ARC EM board has security subsystem, changing offsets"); arc_cpu_saved[ARC_REG_NUM - 1].offset = 8; /* After reading callee registers in stack * now blink,sec_stat,status32 registers * are located. */ arc_cpu_saved_stacking.stack_registers_size = 12; } } for (struct zephyr_params *p = zephyr_params_list; p->target_name; p++) { if (!strcmp(p->target_name, name)) { LOG_INFO("Zephyr: target known, params at %p", p); target->rtos->rtos_specific_params = p; return ERROR_OK; } } LOG_ERROR("Could not find target in Zephyr compatibility list"); return ERROR_FAIL; } struct zephyr_array { void *ptr; size_t elements; }; static void zephyr_array_init(struct zephyr_array *array) { array->ptr = NULL; array->elements = 0; } static void zephyr_array_free(struct zephyr_array *array) { free(array->ptr); zephyr_array_init(array); } static void *zephyr_array_append(struct zephyr_array *array, size_t size) { if (!(array->elements % 16)) { void *ptr = realloc(array->ptr, (array->elements + 16) * size); if (!ptr) { LOG_ERROR("Out of memory"); return NULL; } array->ptr = ptr; } return (unsigned char *)array->ptr + (array->elements++) * size; } static void *zephyr_array_detach_ptr(struct zephyr_array *array) { void *ptr = array->ptr; zephyr_array_init(array); return ptr; } static uint32_t zephyr_kptr(const struct rtos *rtos, enum zephyr_offsets off) { const struct zephyr_params *params = rtos->rtos_specific_params; return rtos->symbols[ZEPHYR_VAL__KERNEL].address + params->offsets[off]; } static int zephyr_fetch_thread(const struct rtos *rtos, struct zephyr_thread *thread, uint32_t ptr) { const struct zephyr_params *param = rtos->rtos_specific_params; int retval; thread->ptr = ptr; retval = target_read_u32(rtos->target, ptr + param->offsets[OFFSET_T_ENTRY], &thread->entry); if (retval != ERROR_OK) return retval; retval = target_read_u32(rtos->target, ptr + param->offsets[OFFSET_T_NEXT_THREAD], &thread->next_ptr); if (retval != ERROR_OK) return retval; retval = target_read_u32(rtos->target, ptr + param->offsets[OFFSET_T_STACK_POINTER], &thread->stack_pointer); if (retval != ERROR_OK) return retval; retval = target_read_u8(rtos->target, ptr + param->offsets[OFFSET_T_STATE], &thread->state); if (retval != ERROR_OK) return retval; retval = target_read_u8(rtos->target, ptr + param->offsets[OFFSET_T_USER_OPTIONS], &thread->user_options); if (retval != ERROR_OK) return retval; uint8_t prio; retval = target_read_u8(rtos->target, ptr + param->offsets[OFFSET_T_PRIO], &prio); if (retval != ERROR_OK) return retval; thread->prio = prio; thread->name[0] = '\0'; if (param->offsets[OFFSET_T_NAME] != UNIMPLEMENTED) { retval = target_read_buffer(rtos->target, ptr + param->offsets[OFFSET_T_NAME], sizeof(thread->name) - 1, (uint8_t *)thread->name); if (retval != ERROR_OK) return retval; thread->name[sizeof(thread->name) - 1] = '\0'; } LOG_DEBUG("Fetched thread%" PRIx32 ": {entry@0x%" PRIx32 ", state=%" PRIu8 ", useropts=%" PRIu8 ", prio=%" PRId8 "}", ptr, thread->entry, thread->state, thread->user_options, thread->prio); return ERROR_OK; } static int zephyr_fetch_thread_list(struct rtos *rtos, uint32_t current_thread) { struct zephyr_array thread_array; struct zephyr_thread thread; struct thread_detail *td; int64_t curr_id = -1; uint32_t curr; int retval; retval = target_read_u32(rtos->target, zephyr_kptr(rtos, OFFSET_K_THREADS), &curr); if (retval != ERROR_OK) { LOG_ERROR("Could not fetch current thread pointer"); return retval; } zephyr_array_init(&thread_array); for (; curr; curr = thread.next_ptr) { retval = zephyr_fetch_thread(rtos, &thread, curr); if (retval != ERROR_OK) goto error; td = zephyr_array_append(&thread_array, sizeof(*td)); if (!td) goto error; td->threadid = thread.ptr; td->exists = true; if (thread.name[0]) td->thread_name_str = strdup(thread.name); else td->thread_name_str = alloc_printf("thr_%" PRIx32 "_%" PRIx32, thread.entry, thread.ptr); td->extra_info_str = alloc_printf("prio:%" PRId8 ",useropts:%" PRIu8, thread.prio, thread.user_options); if (!td->thread_name_str || !td->extra_info_str) goto error; if (td->threadid == current_thread) curr_id = (int64_t)thread_array.elements - 1; } LOG_DEBUG("Got information for %zu threads", thread_array.elements); rtos_free_threadlist(rtos); rtos->thread_count = (int)thread_array.elements; rtos->thread_details = zephyr_array_detach_ptr(&thread_array); rtos->current_threadid = curr_id; rtos->current_thread = current_thread; return ERROR_OK; error: td = thread_array.ptr; for (size_t i = 0; i < thread_array.elements; i++) { free(td[i].thread_name_str); free(td[i].extra_info_str); } zephyr_array_free(&thread_array); return ERROR_FAIL; } static int zephyr_update_threads(struct rtos *rtos) { struct zephyr_params *param; int retval; if (!rtos->rtos_specific_params) return ERROR_FAIL; param = (struct zephyr_params *)rtos->rtos_specific_params; if (!rtos->symbols) { LOG_ERROR("No symbols for Zephyr"); return ERROR_FAIL; } if (rtos->symbols[ZEPHYR_VAL__KERNEL].address == 0) { LOG_ERROR("Can't obtain kernel struct from Zephyr"); return ERROR_FAIL; } if (rtos->symbols[ZEPHYR_VAL__KERNEL_OPENOCD_OFFSETS].address == 0) { LOG_ERROR("Please build Zephyr with CONFIG_OPENOCD option set"); return ERROR_FAIL; } retval = target_read_u8(rtos->target, rtos->symbols[ZEPHYR_VAL__KERNEL_OPENOCD_SIZE_T_SIZE].address, ¶m->size_width); if (retval != ERROR_OK) { LOG_ERROR("Couldn't determine size of size_t from host"); return retval; } if (param->size_width != 4) { LOG_ERROR("Only size_t of 4 bytes are supported"); return ERROR_FAIL; } if (rtos->symbols[ZEPHYR_VAL__KERNEL_OPENOCD_NUM_OFFSETS].address) { retval = target_read_u32(rtos->target, rtos->symbols[ZEPHYR_VAL__KERNEL_OPENOCD_NUM_OFFSETS].address, ¶m->num_offsets); if (retval != ERROR_OK) { LOG_ERROR("Couldn't not fetch number of offsets from Zephyr"); return retval; } if (param->num_offsets <= OFFSET_T_STACK_POINTER) { LOG_ERROR("Number of offsets too small"); return ERROR_FAIL; } } else { retval = target_read_u32(rtos->target, rtos->symbols[ZEPHYR_VAL__KERNEL_OPENOCD_OFFSETS].address, ¶m->offsets[OFFSET_VERSION]); if (retval != ERROR_OK) { LOG_ERROR("Couldn't not fetch offsets from Zephyr"); return retval; } if (param->offsets[OFFSET_VERSION] > 1) { LOG_ERROR("Unexpected OpenOCD support version %" PRIu32, param->offsets[OFFSET_VERSION]); return ERROR_FAIL; } switch (param->offsets[OFFSET_VERSION]) { case 0: param->num_offsets = OFFSET_T_STACK_POINTER + 1; break; case 1: param->num_offsets = OFFSET_T_COOP_FLOAT + 1; break; } } /* We can fetch the whole array for version 0, as they're supposed * to grow only */ uint32_t address; address = rtos->symbols[ZEPHYR_VAL__KERNEL_OPENOCD_OFFSETS].address; for (size_t i = 0; i < OFFSET_MAX; i++, address += param->size_width) { if (i >= param->num_offsets) { param->offsets[i] = UNIMPLEMENTED; continue; } retval = target_read_u32(rtos->target, address, ¶m->offsets[i]); if (retval != ERROR_OK) { LOG_ERROR("Could not fetch offsets from Zephyr"); return ERROR_FAIL; } } LOG_DEBUG("Zephyr OpenOCD support version %" PRId32, param->offsets[OFFSET_VERSION]); uint32_t current_thread; retval = target_read_u32(rtos->target, zephyr_kptr(rtos, OFFSET_K_CURR_THREAD), ¤t_thread); if (retval != ERROR_OK) { LOG_ERROR("Could not obtain current thread ID"); return retval; } retval = zephyr_fetch_thread_list(rtos, current_thread); if (retval != ERROR_OK) { LOG_ERROR("Could not obtain thread list"); return retval; } return ERROR_OK; } static int zephyr_get_thread_reg_list(struct rtos *rtos, int64_t thread_id, struct rtos_reg **reg_list, int *num_regs) { struct zephyr_params *params; struct rtos_reg *callee_saved_reg_list = NULL; target_addr_t addr; int retval; LOG_INFO("Getting thread %" PRId64 " reg list", thread_id); if (!rtos) return ERROR_FAIL; if (thread_id == 0) return ERROR_FAIL; params = rtos->rtos_specific_params; if (!params) return ERROR_FAIL; addr = thread_id + params->offsets[OFFSET_T_STACK_POINTER] - params->callee_saved_stacking->register_offsets[0].offset; retval = params->get_cpu_state(rtos, &addr, params, callee_saved_reg_list, reg_list, num_regs); free(callee_saved_reg_list); return retval; } static int zephyr_get_symbol_list_to_lookup(struct symbol_table_elem **symbol_list) { *symbol_list = malloc(sizeof(zephyr_symbol_list)); if (!*symbol_list) { LOG_ERROR("Out of memory"); return ERROR_FAIL; } memcpy(*symbol_list, zephyr_symbol_list, sizeof(zephyr_symbol_list)); return ERROR_OK; } const struct rtos_type zephyr_rtos = { .name = "Zephyr", .detect_rtos = zephyr_detect_rtos, .create = zephyr_create, .update_threads = zephyr_update_threads, .get_thread_reg_list = zephyr_get_thread_reg_list, .get_symbol_list_to_lookup = zephyr_get_symbol_list_to_lookup, };