/*************************************************************************** * Copyright (C) 2005 by Dominic Rath * * Dominic.Rath@gmx.de * * * * Copyright (C) 2007,2008 Øyvind Harboe * * oyvind.harboe@zylin.com * * * * Copyright (C) 2008 by Spencer Oliver * * spen@spen-soft.co.uk * * * * Copyright (C) 2008 by Hongtao Zheng * * hontor@126.com * * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the * * Free Software Foundation, Inc., * * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. * ***************************************************************************/ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "breakpoints.h" #include "embeddedice.h" #include "target_request.h" #include "etm.h" #include #include "arm_simulator.h" #include "algorithm.h" #include "register.h" /** * @file * Hold common code supporting the ARM7 and ARM9 core generations. * * While the ARM core implementations evolved substantially during these * two generations, they look quite similar from the JTAG perspective. * Both have similar debug facilities, based on the same two scan chains * providing access to the core and to an EmbeddedICE module. Both can * support similar ETM and ETB modules, for tracing. And both expose * what could be viewed as "ARM Classic", with multiple processor modes, * shadowed registers, and support for the Thumb instruction set. * * Processor differences include things like presence or absence of MMU * and cache, pipeline sizes, use of a modified Harvard Architecure * (with separate instruction and data busses from the CPU), support * for cpu clock gating during idle, and more. */ static int arm7_9_debug_entry(struct target *target); /** * Clear watchpoints for an ARM7/9 target. * * @param arm7_9 Pointer to the common struct for an ARM7/9 target * @return JTAG error status after executing queue */ static int arm7_9_clear_watchpoints(struct arm7_9_common *arm7_9) { LOG_DEBUG("-"); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], 0x0); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], 0x0); arm7_9->sw_breakpoint_count = 0; arm7_9->sw_breakpoints_added = 0; arm7_9->wp0_used = 0; arm7_9->wp1_used = arm7_9->wp1_used_default; arm7_9->wp_available = arm7_9->wp_available_max; return jtag_execute_queue(); } /** * Assign a watchpoint to one of the two available hardware comparators in an * ARM7 or ARM9 target. * * @param arm7_9 Pointer to the common struct for an ARM7/9 target * @param breakpoint Pointer to the breakpoint to be used as a watchpoint */ static void arm7_9_assign_wp(struct arm7_9_common *arm7_9, struct breakpoint *breakpoint) { if (!arm7_9->wp0_used) { arm7_9->wp0_used = 1; breakpoint->set = 1; arm7_9->wp_available--; } else if (!arm7_9->wp1_used) { arm7_9->wp1_used = 1; breakpoint->set = 2; arm7_9->wp_available--; } else { LOG_ERROR("BUG: no hardware comparator available"); } LOG_DEBUG("BPID: %d (0x%08" PRIx32 ") using hw wp: %d", breakpoint->unique_id, breakpoint->address, breakpoint->set ); } /** * Setup an ARM7/9 target's embedded ICE registers for software breakpoints. * * @param arm7_9 Pointer to common struct for ARM7/9 targets * @return Error codes if there is a problem finding a watchpoint or the result * of executing the JTAG queue */ static int arm7_9_set_software_breakpoints(struct arm7_9_common *arm7_9) { if (arm7_9->sw_breakpoints_added) { return ERROR_OK; } if (arm7_9->wp_available < 1) { LOG_WARNING("can't enable sw breakpoints with no watchpoint unit available"); return ERROR_TARGET_RESOURCE_NOT_AVAILABLE; } arm7_9->wp_available--; /* pick a breakpoint unit */ if (!arm7_9->wp0_used) { arm7_9->sw_breakpoints_added = 1; arm7_9->wp0_used = 3; } else if (!arm7_9->wp1_used) { arm7_9->sw_breakpoints_added = 2; arm7_9->wp1_used = 3; } else { LOG_ERROR("BUG: both watchpoints used, but wp_available >= 1"); return ERROR_FAIL; } if (arm7_9->sw_breakpoints_added == 1) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_VALUE], arm7_9->arm_bkpt); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK], 0x0); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK], 0xffffffffu); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE); } else if (arm7_9->sw_breakpoints_added == 2) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_VALUE], arm7_9->arm_bkpt); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_MASK], 0x0); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_MASK], 0xffffffffu); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], EICE_W_CTRL_ENABLE); } else { LOG_ERROR("BUG: both watchpoints used, but wp_available >= 1"); return ERROR_FAIL; } LOG_DEBUG("SW BP using hw wp: %d", arm7_9->sw_breakpoints_added ); return jtag_execute_queue(); } /** * Setup the common pieces for an ARM7/9 target after reset or on startup. * * @param target Pointer to an ARM7/9 target to setup * @return Result of clearing the watchpoints on the target */ int arm7_9_setup(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); return arm7_9_clear_watchpoints(arm7_9); } /** * Set either a hardware or software breakpoint on an ARM7/9 target. The * breakpoint is set up even if it is already set. Some actions, e.g. reset, * might have erased the values in Embedded ICE. * * @param target Pointer to the target device to set the breakpoints on * @param breakpoint Pointer to the breakpoint to be set * @return For hardware breakpoints, this is the result of executing the JTAG * queue. For software breakpoints, this will be the status of the * required memory reads and writes */ int arm7_9_set_breakpoint(struct target *target, struct breakpoint *breakpoint) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); int retval = ERROR_OK; LOG_DEBUG("BPID: %d, Address: 0x%08" PRIx32 ", Type: %d" , breakpoint->unique_id, breakpoint->address, breakpoint->type); if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } if (breakpoint->type == BKPT_HARD) { /* either an ARM (4 byte) or Thumb (2 byte) breakpoint */ uint32_t mask = (breakpoint->length == 4) ? 0x3u : 0x1u; /* reassign a hw breakpoint */ if (breakpoint->set == 0) { arm7_9_assign_wp(arm7_9, breakpoint); } if (breakpoint->set == 1) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_VALUE], breakpoint->address); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK], mask); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK], 0xffffffffu); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE); } else if (breakpoint->set == 2) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_VALUE], breakpoint->address); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_MASK], mask); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_MASK], 0xffffffffu); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], EICE_W_CTRL_ENABLE); } else { LOG_ERROR("BUG: no hardware comparator available"); return ERROR_OK; } retval = jtag_execute_queue(); } else if (breakpoint->type == BKPT_SOFT) { /* did we already set this breakpoint? */ if (breakpoint->set) return ERROR_OK; if (breakpoint->length == 4) { uint32_t verify = 0xffffffff; /* keep the original instruction in target endianness */ if ((retval = target_read_memory(target, breakpoint->address, 4, 1, breakpoint->orig_instr)) != ERROR_OK) { return retval; } /* write the breakpoint instruction in target endianness (arm7_9->arm_bkpt is host endian) */ if ((retval = target_write_u32(target, breakpoint->address, arm7_9->arm_bkpt)) != ERROR_OK) { return retval; } if ((retval = target_read_u32(target, breakpoint->address, &verify)) != ERROR_OK) { return retval; } if (verify != arm7_9->arm_bkpt) { LOG_ERROR("Unable to set 32 bit software breakpoint at address %08" PRIx32 " - check that memory is read/writable", breakpoint->address); return ERROR_OK; } } else { uint16_t verify = 0xffff; /* keep the original instruction in target endianness */ if ((retval = target_read_memory(target, breakpoint->address, 2, 1, breakpoint->orig_instr)) != ERROR_OK) { return retval; } /* write the breakpoint instruction in target endianness (arm7_9->thumb_bkpt is host endian) */ if ((retval = target_write_u16(target, breakpoint->address, arm7_9->thumb_bkpt)) != ERROR_OK) { return retval; } if ((retval = target_read_u16(target, breakpoint->address, &verify)) != ERROR_OK) { return retval; } if (verify != arm7_9->thumb_bkpt) { LOG_ERROR("Unable to set thumb software breakpoint at address %08" PRIx32 " - check that memory is read/writable", breakpoint->address); return ERROR_OK; } } if ((retval = arm7_9_set_software_breakpoints(arm7_9)) != ERROR_OK) return retval; arm7_9->sw_breakpoint_count++; breakpoint->set = 1; } return retval; } /** * Unsets an existing breakpoint on an ARM7/9 target. If it is a hardware * breakpoint, the watchpoint used will be freed and the Embedded ICE registers * will be updated. Otherwise, the software breakpoint will be restored to its * original instruction if it hasn't already been modified. * * @param target Pointer to ARM7/9 target to unset the breakpoint from * @param breakpoint Pointer to breakpoint to be unset * @return For hardware breakpoints, this is the result of executing the JTAG * queue. For software breakpoints, this will be the status of the * required memory reads and writes */ int arm7_9_unset_breakpoint(struct target *target, struct breakpoint *breakpoint) { int retval = ERROR_OK; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); LOG_DEBUG("BPID: %d, Address: 0x%08" PRIx32, breakpoint->unique_id, breakpoint->address ); if (!breakpoint->set) { LOG_WARNING("breakpoint not set"); return ERROR_OK; } if (breakpoint->type == BKPT_HARD) { LOG_DEBUG("BPID: %d Releasing hw wp: %d", breakpoint->unique_id, breakpoint->set ); if (breakpoint->set == 1) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], 0x0); arm7_9->wp0_used = 0; arm7_9->wp_available++; } else if (breakpoint->set == 2) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], 0x0); arm7_9->wp1_used = 0; arm7_9->wp_available++; } retval = jtag_execute_queue(); breakpoint->set = 0; } else { /* restore original instruction (kept in target endianness) */ if (breakpoint->length == 4) { uint32_t current_instr; /* check that user program as not modified breakpoint instruction */ if ((retval = target_read_memory(target, breakpoint->address, 4, 1, (uint8_t*)¤t_instr)) != ERROR_OK) { return retval; } if (current_instr == arm7_9->arm_bkpt) if ((retval = target_write_memory(target, breakpoint->address, 4, 1, breakpoint->orig_instr)) != ERROR_OK) { return retval; } } else { uint16_t current_instr; /* check that user program as not modified breakpoint instruction */ if ((retval = target_read_memory(target, breakpoint->address, 2, 1, (uint8_t*)¤t_instr)) != ERROR_OK) { return retval; } if (current_instr == arm7_9->thumb_bkpt) if ((retval = target_write_memory(target, breakpoint->address, 2, 1, breakpoint->orig_instr)) != ERROR_OK) { return retval; } } if (--arm7_9->sw_breakpoint_count==0) { /* We have removed the last sw breakpoint, clear the hw breakpoint we used to implement it */ if (arm7_9->sw_breakpoints_added == 1) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], 0); } else if (arm7_9->sw_breakpoints_added == 2) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], 0); } } breakpoint->set = 0; } return retval; } /** * Add a breakpoint to an ARM7/9 target. This makes sure that there are no * dangling breakpoints and that the desired breakpoint can be added. * * @param target Pointer to the target ARM7/9 device to add a breakpoint to * @param breakpoint Pointer to the breakpoint to be added * @return An error status if there is a problem adding the breakpoint or the * result of setting the breakpoint */ int arm7_9_add_breakpoint(struct target *target, struct breakpoint *breakpoint) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if (arm7_9->breakpoint_count == 0) { /* make sure we don't have any dangling breakpoints. This is vital upon * GDB connect/disconnect */ arm7_9_clear_watchpoints(arm7_9); } if ((breakpoint->type == BKPT_HARD) && (arm7_9->wp_available < 1)) { LOG_INFO("no watchpoint unit available for hardware breakpoint"); return ERROR_TARGET_RESOURCE_NOT_AVAILABLE; } if ((breakpoint->length != 2) && (breakpoint->length != 4)) { LOG_INFO("only breakpoints of two (Thumb) or four (ARM) bytes length supported"); return ERROR_TARGET_RESOURCE_NOT_AVAILABLE; } if (breakpoint->type == BKPT_HARD) { arm7_9_assign_wp(arm7_9, breakpoint); } arm7_9->breakpoint_count++; return arm7_9_set_breakpoint(target, breakpoint); } /** * Removes a breakpoint from an ARM7/9 target. This will make sure there are no * dangling breakpoints and updates available watchpoints if it is a hardware * breakpoint. * * @param target Pointer to the target to have a breakpoint removed * @param breakpoint Pointer to the breakpoint to be removed * @return Error status if there was a problem unsetting the breakpoint or the * watchpoints could not be cleared */ int arm7_9_remove_breakpoint(struct target *target, struct breakpoint *breakpoint) { int retval = ERROR_OK; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if ((retval = arm7_9_unset_breakpoint(target, breakpoint)) != ERROR_OK) { return retval; } if (breakpoint->type == BKPT_HARD) arm7_9->wp_available++; arm7_9->breakpoint_count--; if (arm7_9->breakpoint_count == 0) { /* make sure we don't have any dangling breakpoints */ if ((retval = arm7_9_clear_watchpoints(arm7_9)) != ERROR_OK) { return retval; } } return ERROR_OK; } /** * Sets a watchpoint for an ARM7/9 target in one of the watchpoint units. It is * considered a bug to call this function when there are no available watchpoint * units. * * @param target Pointer to an ARM7/9 target to set a watchpoint on * @param watchpoint Pointer to the watchpoint to be set * @return Error status if watchpoint set fails or the result of executing the * JTAG queue */ int arm7_9_set_watchpoint(struct target *target, struct watchpoint *watchpoint) { int retval = ERROR_OK; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); int rw_mask = 1; uint32_t mask; mask = watchpoint->length - 1; if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } if (watchpoint->rw == WPT_ACCESS) rw_mask = 0; else rw_mask = 1; if (!arm7_9->wp0_used) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_VALUE], watchpoint->address); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK], mask); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK], watchpoint->mask); if (watchpoint->mask != 0xffffffffu) embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_VALUE], watchpoint->value); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], 0xff & ~EICE_W_CTRL_nOPC & ~rw_mask); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE | EICE_W_CTRL_nOPC | (watchpoint->rw & 1)); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } watchpoint->set = 1; arm7_9->wp0_used = 2; } else if (!arm7_9->wp1_used) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_VALUE], watchpoint->address); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_MASK], mask); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_MASK], watchpoint->mask); if (watchpoint->mask != 0xffffffffu) embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_VALUE], watchpoint->value); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], 0xff & ~EICE_W_CTRL_nOPC & ~rw_mask); embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], EICE_W_CTRL_ENABLE | EICE_W_CTRL_nOPC | (watchpoint->rw & 1)); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } watchpoint->set = 2; arm7_9->wp1_used = 2; } else { LOG_ERROR("BUG: no hardware comparator available"); return ERROR_OK; } return ERROR_OK; } /** * Unset an existing watchpoint and clear the used watchpoint unit. * * @param target Pointer to the target to have the watchpoint removed * @param watchpoint Pointer to the watchpoint to be removed * @return Error status while trying to unset the watchpoint or the result of * executing the JTAG queue */ int arm7_9_unset_watchpoint(struct target *target, struct watchpoint *watchpoint) { int retval = ERROR_OK; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } if (!watchpoint->set) { LOG_WARNING("breakpoint not set"); return ERROR_OK; } if (watchpoint->set == 1) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], 0x0); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } arm7_9->wp0_used = 0; } else if (watchpoint->set == 2) { embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], 0x0); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } arm7_9->wp1_used = 0; } watchpoint->set = 0; return ERROR_OK; } /** * Add a watchpoint to an ARM7/9 target. If there are no watchpoint units * available, an error response is returned. * * @param target Pointer to the ARM7/9 target to add a watchpoint to * @param watchpoint Pointer to the watchpoint to be added * @return Error status while trying to add the watchpoint */ int arm7_9_add_watchpoint(struct target *target, struct watchpoint *watchpoint) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if (arm7_9->wp_available < 1) { return ERROR_TARGET_RESOURCE_NOT_AVAILABLE; } if ((watchpoint->length != 1) && (watchpoint->length != 2) && (watchpoint->length != 4)) { return ERROR_TARGET_RESOURCE_NOT_AVAILABLE; } arm7_9->wp_available--; return ERROR_OK; } /** * Remove a watchpoint from an ARM7/9 target. The watchpoint will be unset and * the used watchpoint unit will be reopened. * * @param target Pointer to the target to remove a watchpoint from * @param watchpoint Pointer to the watchpoint to be removed * @return Result of trying to unset the watchpoint */ int arm7_9_remove_watchpoint(struct target *target, struct watchpoint *watchpoint) { int retval = ERROR_OK; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if (watchpoint->set) { if ((retval = arm7_9_unset_watchpoint(target, watchpoint)) != ERROR_OK) { return retval; } } arm7_9->wp_available++; return ERROR_OK; } /** * Restarts the target by sending a RESTART instruction and moving the JTAG * state to IDLE. This includes a timeout waiting for DBGACK and SYSCOMP to be * asserted by the processor. * * @param target Pointer to target to issue commands to * @return Error status if there is a timeout or a problem while executing the * JTAG queue */ int arm7_9_execute_sys_speed(struct target *target) { int retval; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm_jtag *jtag_info = &arm7_9->jtag_info; struct reg *dbg_stat = &arm7_9->eice_cache->reg_list[EICE_DBG_STAT]; /* set RESTART instruction */ jtag_set_end_state(TAP_IDLE); if (arm7_9->need_bypass_before_restart) { arm7_9->need_bypass_before_restart = 0; arm_jtag_set_instr(jtag_info, 0xf, NULL); } arm_jtag_set_instr(jtag_info, 0x4, NULL); long long then = timeval_ms(); int timeout; while (!(timeout = ((timeval_ms()-then) > 1000))) { /* read debug status register */ embeddedice_read_reg(dbg_stat); if ((retval = jtag_execute_queue()) != ERROR_OK) return retval; if ((buf_get_u32(dbg_stat->value, EICE_DBG_STATUS_DBGACK, 1)) && (buf_get_u32(dbg_stat->value, EICE_DBG_STATUS_SYSCOMP, 1))) break; if (debug_level >= 3) { alive_sleep(100); } else { keep_alive(); } } if (timeout) { LOG_ERROR("timeout waiting for SYSCOMP & DBGACK, last DBG_STATUS: %" PRIx32 "", buf_get_u32(dbg_stat->value, 0, dbg_stat->size)); return ERROR_TARGET_TIMEOUT; } return ERROR_OK; } /** * Restarts the target by sending a RESTART instruction and moving the JTAG * state to IDLE. This validates that DBGACK and SYSCOMP are set without * waiting until they are. * * @param target Pointer to the target to issue commands to * @return Always ERROR_OK */ int arm7_9_execute_fast_sys_speed(struct target *target) { static int set = 0; static uint8_t check_value[4], check_mask[4]; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm_jtag *jtag_info = &arm7_9->jtag_info; struct reg *dbg_stat = &arm7_9->eice_cache->reg_list[EICE_DBG_STAT]; /* set RESTART instruction */ jtag_set_end_state(TAP_IDLE); if (arm7_9->need_bypass_before_restart) { arm7_9->need_bypass_before_restart = 0; arm_jtag_set_instr(jtag_info, 0xf, NULL); } arm_jtag_set_instr(jtag_info, 0x4, NULL); if (!set) { /* check for DBGACK and SYSCOMP set (others don't care) */ /* NB! These are constants that must be available until after next jtag_execute() and * we evaluate the values upon first execution in lieu of setting up these constants * during early setup. * */ buf_set_u32(check_value, 0, 32, 0x9); buf_set_u32(check_mask, 0, 32, 0x9); set = 1; } /* read debug status register */ embeddedice_read_reg_w_check(dbg_stat, check_value, check_mask); return ERROR_OK; } /** * Get some data from the ARM7/9 target. * * @param target Pointer to the ARM7/9 target to read data from * @param size The number of 32bit words to be read * @param buffer Pointer to the buffer that will hold the data * @return The result of receiving data from the Embedded ICE unit */ int arm7_9_target_request_data(struct target *target, uint32_t size, uint8_t *buffer) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm_jtag *jtag_info = &arm7_9->jtag_info; uint32_t *data; int retval = ERROR_OK; uint32_t i; data = malloc(size * (sizeof(uint32_t))); retval = embeddedice_receive(jtag_info, data, size); /* return the 32-bit ints in the 8-bit array */ for (i = 0; i < size; i++) { h_u32_to_le(buffer + (i * 4), data[i]); } free(data); return retval; } /** * Handles requests to an ARM7/9 target. If debug messaging is enabled, the * target is running and the DCC control register has the W bit high, this will * execute the request on the target. * * @param priv Void pointer expected to be a struct target pointer * @return ERROR_OK unless there are issues with the JTAG queue or when reading * from the Embedded ICE unit */ int arm7_9_handle_target_request(void *priv) { int retval = ERROR_OK; struct target *target = priv; if (!target_was_examined(target)) return ERROR_OK; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm_jtag *jtag_info = &arm7_9->jtag_info; struct reg *dcc_control = &arm7_9->eice_cache->reg_list[EICE_COMMS_CTRL]; if (!target->dbg_msg_enabled) return ERROR_OK; if (target->state == TARGET_RUNNING) { /* read DCC control register */ embeddedice_read_reg(dcc_control); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } /* check W bit */ if (buf_get_u32(dcc_control->value, 1, 1) == 1) { uint32_t request; if ((retval = embeddedice_receive(jtag_info, &request, 1)) != ERROR_OK) { return retval; } if ((retval = target_request(target, request)) != ERROR_OK) { return retval; } } } return ERROR_OK; } /** * Polls an ARM7/9 target for its current status. If DBGACK is set, the target * is manipulated to the right halted state based on its current state. This is * what happens: * * * * * * * *
State Action
TARGET_RUNNING | TARGET_RESET Enters debug mode. If TARGET_RESET, pc may be checked
TARGET_UNKNOWN Warning is logged
TARGET_DEBUG_RUNNING Enters debug mode
TARGET_HALTED Nothing
* * If the target does not end up in the halted state, a warning is produced. If * DBGACK is cleared, then the target is expected to either be running or * running in debug. * * @param target Pointer to the ARM7/9 target to poll * @return ERROR_OK or an error status if a command fails */ int arm7_9_poll(struct target *target) { int retval; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct reg *dbg_stat = &arm7_9->eice_cache->reg_list[EICE_DBG_STAT]; /* read debug status register */ embeddedice_read_reg(dbg_stat); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } if (buf_get_u32(dbg_stat->value, EICE_DBG_STATUS_DBGACK, 1)) { /* LOG_DEBUG("DBGACK set, dbg_state->value: 0x%x", buf_get_u32(dbg_stat->value, 0, 32));*/ if (target->state == TARGET_UNKNOWN) { /* Starting OpenOCD with target in debug-halt */ target->state = TARGET_RUNNING; LOG_DEBUG("DBGACK already set during server startup."); } if ((target->state == TARGET_RUNNING) || (target->state == TARGET_RESET)) { int check_pc = 0; if (target->state == TARGET_RESET) { if (target->reset_halt) { enum reset_types jtag_reset_config = jtag_get_reset_config(); if ((jtag_reset_config & RESET_SRST_PULLS_TRST) == 0) { check_pc = 1; } } } target->state = TARGET_HALTED; if ((retval = arm7_9_debug_entry(target)) != ERROR_OK) return retval; if (check_pc) { struct reg *reg = register_get_by_name(target->reg_cache, "pc", 1); uint32_t t=*((uint32_t *)reg->value); if (t != 0) { LOG_ERROR("PC was not 0. Does this target need srst_pulls_trst?"); } } if ((retval = target_call_event_callbacks(target, TARGET_EVENT_HALTED)) != ERROR_OK) { return retval; } } if (target->state == TARGET_DEBUG_RUNNING) { target->state = TARGET_HALTED; if ((retval = arm7_9_debug_entry(target)) != ERROR_OK) return retval; if ((retval = target_call_event_callbacks(target, TARGET_EVENT_DEBUG_HALTED)) != ERROR_OK) { return retval; } } if (target->state != TARGET_HALTED) { LOG_WARNING("DBGACK set, but the target did not end up in the halted state %d", target->state); } } else { if (target->state != TARGET_DEBUG_RUNNING) target->state = TARGET_RUNNING; } return ERROR_OK; } /** * Asserts the reset (SRST) on an ARM7/9 target. Some -S targets (ARM966E-S in * the STR912 isn't affected, ARM926EJ-S in the LPC3180 and AT91SAM9260 is * affected) completely stop the JTAG clock while the core is held in reset * (SRST). It isn't possible to program the halt condition once reset is * asserted, hence a hook that allows the target to set up its reset-halt * condition is setup prior to asserting reset. * * @param target Pointer to an ARM7/9 target to assert reset on * @return ERROR_FAIL if the JTAG device does not have SRST, otherwise ERROR_OK */ int arm7_9_assert_reset(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); LOG_DEBUG("target->state: %s", target_state_name(target)); enum reset_types jtag_reset_config = jtag_get_reset_config(); if (!(jtag_reset_config & RESET_HAS_SRST)) { LOG_ERROR("Can't assert SRST"); return ERROR_FAIL; } /* At this point trst has been asserted/deasserted once. We would * like to program EmbeddedICE while SRST is asserted, instead of * depending on SRST to leave that module alone. However, many CPUs * gate the JTAG clock while SRST is asserted; or JTAG may need * clock stability guarantees (adaptive clocking might help). * * So we assume JTAG access during SRST is off the menu unless it's * been specifically enabled. */ bool srst_asserted = false; if (((jtag_reset_config & RESET_SRST_PULLS_TRST) == 0) && (jtag_reset_config & RESET_SRST_NO_GATING)) { jtag_add_reset(0, 1); srst_asserted = true; } if (target->reset_halt) { /* * Some targets do not support communication while SRST is asserted. We need to * set up the reset vector catch here. * * If TRST is asserted, then these settings will be reset anyway, so setting them * here is harmless. */ if (arm7_9->has_vector_catch) { /* program vector catch register to catch reset vector */ embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_VEC_CATCH], 0x1); /* extra runtest added as issues were found with certain ARM9 cores (maybe more) - AT91SAM9260 and STR9 */ jtag_add_runtest(1, jtag_get_end_state()); } else { /* program watchpoint unit to match on reset vector address */ embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_VALUE], 0x0); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK], 0x3); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); } } /* here we should issue an SRST only, but we may have to assert TRST as well */ if (jtag_reset_config & RESET_SRST_PULLS_TRST) { jtag_add_reset(1, 1); } else if (!srst_asserted) { jtag_add_reset(0, 1); } target->state = TARGET_RESET; jtag_add_sleep(50000); register_cache_invalidate(arm7_9->armv4_5_common.core_cache); if ((target->reset_halt) && ((jtag_reset_config & RESET_SRST_PULLS_TRST) == 0)) { /* debug entry was already prepared in arm7_9_assert_reset() */ target->debug_reason = DBG_REASON_DBGRQ; } return ERROR_OK; } /** * Deassert the reset (SRST) signal on an ARM7/9 target. If SRST pulls TRST * and the target is being reset into a halt, a warning will be triggered * because it is not possible to reset into a halted mode in this case. The * target is halted using the target's functions. * * @param target Pointer to the target to have the reset deasserted * @return ERROR_OK or an error from polling or halting the target */ int arm7_9_deassert_reset(struct target *target) { int retval = ERROR_OK; LOG_DEBUG("target->state: %s", target_state_name(target)); /* deassert reset lines */ jtag_add_reset(0, 0); enum reset_types jtag_reset_config = jtag_get_reset_config(); if (target->reset_halt && (jtag_reset_config & RESET_SRST_PULLS_TRST) != 0) { LOG_WARNING("srst pulls trst - can not reset into halted mode. Issuing halt after reset."); /* set up embedded ice registers again */ if ((retval = target_examine_one(target)) != ERROR_OK) return retval; if ((retval = target_poll(target)) != ERROR_OK) { return retval; } if ((retval = target_halt(target)) != ERROR_OK) { return retval; } } return retval; } /** * Clears the halt condition for an ARM7/9 target. If it isn't coming out of * reset and if DBGRQ is used, it is progammed to be deasserted. If the reset * vector catch was used, it is restored. Otherwise, the control value is * restored and the watchpoint unit is restored if it was in use. * * @param target Pointer to the ARM7/9 target to have halt cleared * @return Always ERROR_OK */ int arm7_9_clear_halt(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct reg *dbg_ctrl = &arm7_9->eice_cache->reg_list[EICE_DBG_CTRL]; /* we used DBGRQ only if we didn't come out of reset */ if (!arm7_9->debug_entry_from_reset && arm7_9->use_dbgrq) { /* program EmbeddedICE Debug Control Register to deassert DBGRQ */ buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGRQ, 1, 0); embeddedice_store_reg(dbg_ctrl); } else { if (arm7_9->debug_entry_from_reset && arm7_9->has_vector_catch) { /* if we came out of reset, and vector catch is supported, we used * vector catch to enter debug state * restore the register in that case */ embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_VEC_CATCH]); } else { /* restore registers if watchpoint unit 0 was in use */ if (arm7_9->wp0_used) { if (arm7_9->debug_entry_from_reset) { embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_VALUE]); } embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK]); } /* control value always has to be restored, as it was either disabled, * or enabled with possibly different bits */ embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE]); } } return ERROR_OK; } /** * Issue a software reset and halt to an ARM7/9 target. The target is halted * and then there is a wait until the processor shows the halt. This wait can * timeout and results in an error being returned. The software reset involves * clearing the halt, updating the debug control register, changing to ARM mode, * reset of the program counter, and reset of all of the registers. * * @param target Pointer to the ARM7/9 target to be reset and halted by software * @return Error status if any of the commands fail, otherwise ERROR_OK */ int arm7_9_soft_reset_halt(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; struct reg *dbg_stat = &arm7_9->eice_cache->reg_list[EICE_DBG_STAT]; struct reg *dbg_ctrl = &arm7_9->eice_cache->reg_list[EICE_DBG_CTRL]; int i; int retval; /* FIX!!! replace some of this code with tcl commands * * halt # the halt command is synchronous * armv4_5 core_state arm * */ if ((retval = target_halt(target)) != ERROR_OK) return retval; long long then = timeval_ms(); int timeout; while (!(timeout = ((timeval_ms()-then) > 1000))) { if (buf_get_u32(dbg_stat->value, EICE_DBG_STATUS_DBGACK, 1) != 0) break; embeddedice_read_reg(dbg_stat); if ((retval = jtag_execute_queue()) != ERROR_OK) return retval; if (debug_level >= 3) { alive_sleep(100); } else { keep_alive(); } } if (timeout) { LOG_ERROR("Failed to halt CPU after 1 sec"); return ERROR_TARGET_TIMEOUT; } target->state = TARGET_HALTED; /* program EmbeddedICE Debug Control Register to assert DBGACK and INTDIS * ensure that DBGRQ is cleared */ buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGACK, 1, 1); buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGRQ, 1, 0); buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_INTDIS, 1, 1); embeddedice_store_reg(dbg_ctrl); if ((retval = arm7_9_clear_halt(target)) != ERROR_OK) { return retval; } /* if the target is in Thumb state, change to ARM state */ if (buf_get_u32(dbg_stat->value, EICE_DBG_STATUS_ITBIT, 1)) { uint32_t r0_thumb, pc_thumb; LOG_DEBUG("target entered debug from Thumb state, changing to ARM"); /* Entered debug from Thumb mode */ armv4_5->core_state = ARMV4_5_STATE_THUMB; arm7_9->change_to_arm(target, &r0_thumb, &pc_thumb); } /* REVISIT likewise for bit 5 -- switch Jazelle-to-ARM */ /* all register content is now invalid */ register_cache_invalidate(armv4_5->core_cache); /* SVC, ARM state, IRQ and FIQ disabled */ uint32_t cpsr; cpsr = buf_get_u32(armv4_5->cpsr->value, 0, 32); cpsr &= ~0xff; cpsr |= 0xd3; arm_set_cpsr(armv4_5, cpsr); armv4_5->cpsr->dirty = 1; /* start fetching from 0x0 */ buf_set_u32(armv4_5->core_cache->reg_list[15].value, 0, 32, 0x0); armv4_5->core_cache->reg_list[15].dirty = 1; armv4_5->core_cache->reg_list[15].valid = 1; /* reset registers */ for (i = 0; i <= 14; i++) { struct reg *r = arm_reg_current(armv4_5, i); buf_set_u32(r->value, 0, 32, 0xffffffff); r->dirty = 1; r->valid = 1; } if ((retval = target_call_event_callbacks(target, TARGET_EVENT_HALTED)) != ERROR_OK) { return retval; } return ERROR_OK; } /** * Halt an ARM7/9 target. This is accomplished by either asserting the DBGRQ * line or by programming a watchpoint to trigger on any address. It is * considered a bug to call this function while the target is in the * TARGET_RESET state. * * @param target Pointer to the ARM7/9 target to be halted * @return Always ERROR_OK */ int arm7_9_halt(struct target *target) { if (target->state == TARGET_RESET) { LOG_ERROR("BUG: arm7/9 does not support halt during reset. This is handled in arm7_9_assert_reset()"); return ERROR_OK; } struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct reg *dbg_ctrl = &arm7_9->eice_cache->reg_list[EICE_DBG_CTRL]; LOG_DEBUG("target->state: %s", target_state_name(target)); if (target->state == TARGET_HALTED) { LOG_DEBUG("target was already halted"); return ERROR_OK; } if (target->state == TARGET_UNKNOWN) { LOG_WARNING("target was in unknown state when halt was requested"); } if (arm7_9->use_dbgrq) { /* program EmbeddedICE Debug Control Register to assert DBGRQ */ if (arm7_9->set_special_dbgrq) { arm7_9->set_special_dbgrq(target); } else { buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGRQ, 1, 1); embeddedice_store_reg(dbg_ctrl); } } else { /* program watchpoint unit to match on any address */ embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); } target->debug_reason = DBG_REASON_DBGRQ; return ERROR_OK; } /** * Handle an ARM7/9 target's entry into debug mode. The halt is cleared on the * ARM. The JTAG queue is then executed and the reason for debug entry is * examined. Once done, the target is verified to be halted and the processor * is forced into ARM mode. The core registers are saved for the current core * mode and the program counter (register 15) is updated as needed. The core * registers and CPSR and SPSR are saved for restoration later. * * @param target Pointer to target that is entering debug mode * @return Error code if anything fails, otherwise ERROR_OK */ static int arm7_9_debug_entry(struct target *target) { int i; uint32_t context[16]; uint32_t* context_p[16]; uint32_t r0_thumb, pc_thumb; uint32_t cpsr, cpsr_mask = 0; int retval; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; struct reg *dbg_stat = &arm7_9->eice_cache->reg_list[EICE_DBG_STAT]; struct reg *dbg_ctrl = &arm7_9->eice_cache->reg_list[EICE_DBG_CTRL]; #ifdef _DEBUG_ARM7_9_ LOG_DEBUG("-"); #endif /* program EmbeddedICE Debug Control Register to assert DBGACK and INTDIS * ensure that DBGRQ is cleared */ buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGACK, 1, 1); buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGRQ, 1, 0); buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_INTDIS, 1, 1); embeddedice_store_reg(dbg_ctrl); if ((retval = arm7_9_clear_halt(target)) != ERROR_OK) { return retval; } if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } if ((retval = arm7_9->examine_debug_reason(target)) != ERROR_OK) return retval; if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } /* if the target is in Thumb state, change to ARM state */ if (buf_get_u32(dbg_stat->value, EICE_DBG_STATUS_ITBIT, 1)) { LOG_DEBUG("target entered debug from Thumb state"); /* Entered debug from Thumb mode */ armv4_5->core_state = ARMV4_5_STATE_THUMB; cpsr_mask = 1 << 5; arm7_9->change_to_arm(target, &r0_thumb, &pc_thumb); LOG_DEBUG("r0_thumb: 0x%8.8" PRIx32 ", pc_thumb: 0x%8.8" PRIx32, r0_thumb, pc_thumb); } else if (buf_get_u32(dbg_stat->value, 5, 1)) { /* \todo Get some vaguely correct handling of Jazelle, if * anyone ever uses it and full info becomes available. * See ARM9EJS TRM B.7.1 for how to switch J->ARM; and * B.7.3 for the reverse. That'd be the bare minimum... */ LOG_DEBUG("target entered debug from Jazelle state"); armv4_5->core_state = ARMV4_5_STATE_JAZELLE; cpsr_mask = 1 << 24; LOG_ERROR("Jazelle debug entry -- BROKEN!"); } else { LOG_DEBUG("target entered debug from ARM state"); /* Entered debug from ARM mode */ armv4_5->core_state = ARMV4_5_STATE_ARM; } for (i = 0; i < 16; i++) context_p[i] = &context[i]; /* save core registers (r0 - r15 of current core mode) */ arm7_9->read_core_regs(target, 0xffff, context_p); arm7_9->read_xpsr(target, &cpsr, 0); if ((retval = jtag_execute_queue()) != ERROR_OK) return retval; /* Sync our CPSR copy with J or T bits EICE reported, but * which we then erased by putting the core into ARM mode. */ arm_set_cpsr(armv4_5, cpsr | cpsr_mask); if (!is_arm_mode(armv4_5->core_mode)) { target->state = TARGET_UNKNOWN; LOG_ERROR("cpsr contains invalid mode value - communication failure"); return ERROR_TARGET_FAILURE; } LOG_DEBUG("target entered debug state in %s mode", arm_mode_name(armv4_5->core_mode)); if (armv4_5->core_state == ARMV4_5_STATE_THUMB) { LOG_DEBUG("thumb state, applying fixups"); context[0] = r0_thumb; context[15] = pc_thumb; } else if (armv4_5->core_state == ARMV4_5_STATE_ARM) { /* adjust value stored by STM */ context[15] -= 3 * 4; } if ((target->debug_reason != DBG_REASON_DBGRQ) || (!arm7_9->use_dbgrq)) context[15] -= 3 * ((armv4_5->core_state == ARMV4_5_STATE_ARM) ? 4 : 2); else context[15] -= arm7_9->dbgreq_adjust_pc * ((armv4_5->core_state == ARMV4_5_STATE_ARM) ? 4 : 2); for (i = 0; i <= 15; i++) { struct reg *r = arm_reg_current(armv4_5, i); LOG_DEBUG("r%i: 0x%8.8" PRIx32 "", i, context[i]); buf_set_u32(r->value, 0, 32, context[i]); /* r0 and r15 (pc) have to be restored later */ r->dirty = (i == 0) || (i == 15); r->valid = 1; } LOG_DEBUG("entered debug state at PC 0x%" PRIx32 "", context[15]); /* exceptions other than USR & SYS have a saved program status register */ if (armv4_5->spsr) { uint32_t spsr; arm7_9->read_xpsr(target, &spsr, 1); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } buf_set_u32(armv4_5->spsr->value, 0, 32, spsr); armv4_5->spsr->dirty = 0; armv4_5->spsr->valid = 1; } if ((retval = jtag_execute_queue()) != ERROR_OK) return retval; if (arm7_9->post_debug_entry) arm7_9->post_debug_entry(target); return ERROR_OK; } /** * Validate the full context for an ARM7/9 target in all processor modes. If * there are any invalid registers for the target, they will all be read. This * includes the PSR. * * @param target Pointer to the ARM7/9 target to capture the full context from * @return Error if the target is not halted, has an invalid core mode, or if * the JTAG queue fails to execute */ int arm7_9_full_context(struct target *target) { int i; int retval; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; LOG_DEBUG("-"); if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } if (!is_arm_mode(armv4_5->core_mode)) return ERROR_FAIL; /* iterate through processor modes (User, FIQ, IRQ, SVC, ABT, UND) * SYS shares registers with User, so we don't touch SYS */ for (i = 0; i < 6; i++) { uint32_t mask = 0; uint32_t* reg_p[16]; int j; int valid = 1; /* check if there are invalid registers in the current mode */ for (j = 0; j <= 16; j++) { if (ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j).valid == 0) valid = 0; } if (!valid) { uint32_t tmp_cpsr; /* change processor mode (and mask T bit) */ tmp_cpsr = buf_get_u32(armv4_5->cpsr->value, 0, 8) & 0xe0; tmp_cpsr |= armv4_5_number_to_mode(i); tmp_cpsr &= ~0x20; arm7_9->write_xpsr_im8(target, tmp_cpsr & 0xff, 0, 0); for (j = 0; j < 15; j++) { if (ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j).valid == 0) { reg_p[j] = (uint32_t*)ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j).value; mask |= 1 << j; ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j).valid = 1; ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j).dirty = 0; } } /* if only the PSR is invalid, mask is all zeroes */ if (mask) arm7_9->read_core_regs(target, mask, reg_p); /* check if the PSR has to be read */ if (ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), 16).valid == 0) { arm7_9->read_xpsr(target, (uint32_t*)ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), 16).value, 1); ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), 16).valid = 1; ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), 16).dirty = 0; } } } /* restore processor mode (mask T bit) */ arm7_9->write_xpsr_im8(target, buf_get_u32(armv4_5->cpsr->value, 0, 8) & ~0x20, 0, 0); if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } return ERROR_OK; } /** * Restore the processor context on an ARM7/9 target. The full processor * context is analyzed to see if any of the registers are dirty on this end, but * have a valid new value. If this is the case, the processor is changed to the * appropriate mode and the new register values are written out to the * processor. If there happens to be a dirty register with an invalid value, an * error will be logged. * * @param target Pointer to the ARM7/9 target to have its context restored * @return Error status if the target is not halted or the core mode in the * armv4_5 struct is invalid. */ int arm7_9_restore_context(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; struct reg *reg; struct arm_reg *reg_arch_info; enum armv4_5_mode current_mode = armv4_5->core_mode; int i, j; int dirty; int mode_change; LOG_DEBUG("-"); if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } if (arm7_9->pre_restore_context) arm7_9->pre_restore_context(target); if (!is_arm_mode(armv4_5->core_mode)) return ERROR_FAIL; /* iterate through processor modes (User, FIQ, IRQ, SVC, ABT, UND) * SYS shares registers with User, so we don't touch SYS */ for (i = 0; i < 6; i++) { LOG_DEBUG("examining %s mode", arm_mode_name(armv4_5->core_mode)); dirty = 0; mode_change = 0; /* check if there are dirty registers in the current mode */ for (j = 0; j <= 16; j++) { reg = &ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j); reg_arch_info = reg->arch_info; if (reg->dirty == 1) { if (reg->valid == 1) { dirty = 1; LOG_DEBUG("examining dirty reg: %s", reg->name); if ((reg_arch_info->mode != ARMV4_5_MODE_ANY) && (reg_arch_info->mode != current_mode) && !((reg_arch_info->mode == ARMV4_5_MODE_USR) && (armv4_5->core_mode == ARMV4_5_MODE_SYS)) && !((reg_arch_info->mode == ARMV4_5_MODE_SYS) && (armv4_5->core_mode == ARMV4_5_MODE_USR))) { mode_change = 1; LOG_DEBUG("require mode change"); } } else { LOG_ERROR("BUG: dirty register '%s', but no valid data", reg->name); } } } if (dirty) { uint32_t mask = 0x0; int num_regs = 0; uint32_t regs[16]; if (mode_change) { uint32_t tmp_cpsr; /* change processor mode (mask T bit) */ tmp_cpsr = buf_get_u32(armv4_5->cpsr->value, 0, 8) & 0xe0; tmp_cpsr |= armv4_5_number_to_mode(i); tmp_cpsr &= ~0x20; arm7_9->write_xpsr_im8(target, tmp_cpsr & 0xff, 0, 0); current_mode = armv4_5_number_to_mode(i); } for (j = 0; j <= 14; j++) { reg = &ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j); reg_arch_info = reg->arch_info; if (reg->dirty == 1) { regs[j] = buf_get_u32(reg->value, 0, 32); mask |= 1 << j; num_regs++; reg->dirty = 0; reg->valid = 1; LOG_DEBUG("writing register %i mode %s " "with value 0x%8.8" PRIx32, j, arm_mode_name(armv4_5->core_mode), regs[j]); } } if (mask) { arm7_9->write_core_regs(target, mask, regs); } reg = &ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), 16); reg_arch_info = reg->arch_info; if ((reg->dirty) && (reg_arch_info->mode != ARMV4_5_MODE_ANY)) { LOG_DEBUG("writing SPSR of mode %i with value 0x%8.8" PRIx32 "", i, buf_get_u32(reg->value, 0, 32)); arm7_9->write_xpsr(target, buf_get_u32(reg->value, 0, 32), 1); } } } if (!armv4_5->cpsr->dirty && (armv4_5->core_mode != current_mode)) { /* restore processor mode (mask T bit) */ uint32_t tmp_cpsr; tmp_cpsr = buf_get_u32(armv4_5->cpsr->value, 0, 8) & 0xE0; tmp_cpsr |= armv4_5_number_to_mode(i); tmp_cpsr &= ~0x20; LOG_DEBUG("writing lower 8 bit of cpsr with value 0x%2.2x", (unsigned)(tmp_cpsr)); arm7_9->write_xpsr_im8(target, tmp_cpsr & 0xff, 0, 0); } else if (armv4_5->cpsr->dirty) { /* CPSR has been changed, full restore necessary (mask T bit) */ LOG_DEBUG("writing cpsr with value 0x%8.8" PRIx32, buf_get_u32(armv4_5->cpsr->value, 0, 32)); arm7_9->write_xpsr(target, buf_get_u32(armv4_5->cpsr->value, 0, 32) & ~0x20, 0); armv4_5->cpsr->dirty = 0; armv4_5->cpsr->valid = 1; } /* restore PC */ LOG_DEBUG("writing PC with value 0x%8.8" PRIx32 "", buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32)); arm7_9->write_pc(target, buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32)); armv4_5->core_cache->reg_list[15].dirty = 0; if (arm7_9->post_restore_context) arm7_9->post_restore_context(target); return ERROR_OK; } /** * Restart the core of an ARM7/9 target. A RESTART command is sent to the * instruction register and the JTAG state is set to TAP_IDLE causing a core * restart. * * @param target Pointer to the ARM7/9 target to be restarted * @return Result of executing the JTAG queue */ int arm7_9_restart_core(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm_jtag *jtag_info = &arm7_9->jtag_info; /* set RESTART instruction */ jtag_set_end_state(TAP_IDLE); if (arm7_9->need_bypass_before_restart) { arm7_9->need_bypass_before_restart = 0; arm_jtag_set_instr(jtag_info, 0xf, NULL); } arm_jtag_set_instr(jtag_info, 0x4, NULL); jtag_add_runtest(1, jtag_set_end_state(TAP_IDLE)); return jtag_execute_queue(); } /** * Enable the watchpoints on an ARM7/9 target. The target's watchpoints are * iterated through and are set on the target if they aren't already set. * * @param target Pointer to the ARM7/9 target to enable watchpoints on */ void arm7_9_enable_watchpoints(struct target *target) { struct watchpoint *watchpoint = target->watchpoints; while (watchpoint) { if (watchpoint->set == 0) arm7_9_set_watchpoint(target, watchpoint); watchpoint = watchpoint->next; } } /** * Enable the breakpoints on an ARM7/9 target. The target's breakpoints are * iterated through and are set on the target. * * @param target Pointer to the ARM7/9 target to enable breakpoints on */ void arm7_9_enable_breakpoints(struct target *target) { struct breakpoint *breakpoint = target->breakpoints; /* set any pending breakpoints */ while (breakpoint) { arm7_9_set_breakpoint(target, breakpoint); breakpoint = breakpoint->next; } } int arm7_9_resume(struct target *target, int current, uint32_t address, int handle_breakpoints, int debug_execution) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; struct breakpoint *breakpoint = target->breakpoints; struct reg *dbg_ctrl = &arm7_9->eice_cache->reg_list[EICE_DBG_CTRL]; int err, retval = ERROR_OK; LOG_DEBUG("-"); if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } if (!debug_execution) { target_free_all_working_areas(target); } /* current = 1: continue on current pc, otherwise continue at
*/ if (!current) buf_set_u32(armv4_5->core_cache->reg_list[15].value, 0, 32, address); uint32_t current_pc; current_pc = buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32); /* the front-end may request us not to handle breakpoints */ if (handle_breakpoints) { if ((breakpoint = breakpoint_find(target, buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32)))) { LOG_DEBUG("unset breakpoint at 0x%8.8" PRIx32 " (id: %d)", breakpoint->address, breakpoint->unique_id ); if ((retval = arm7_9_unset_breakpoint(target, breakpoint)) != ERROR_OK) { return retval; } /* calculate PC of next instruction */ uint32_t next_pc; if ((retval = arm_simulate_step(target, &next_pc)) != ERROR_OK) { uint32_t current_opcode; target_read_u32(target, current_pc, ¤t_opcode); LOG_ERROR("Couldn't calculate PC of next instruction, current opcode was 0x%8.8" PRIx32 "", current_opcode); return retval; } LOG_DEBUG("enable single-step"); arm7_9->enable_single_step(target, next_pc); target->debug_reason = DBG_REASON_SINGLESTEP; if ((retval = arm7_9_restore_context(target)) != ERROR_OK) { return retval; } if (armv4_5->core_state == ARMV4_5_STATE_ARM) arm7_9->branch_resume(target); else if (armv4_5->core_state == ARMV4_5_STATE_THUMB) { arm7_9->branch_resume_thumb(target); } else { LOG_ERROR("unhandled core state"); return ERROR_FAIL; } buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGACK, 1, 0); embeddedice_write_reg(dbg_ctrl, buf_get_u32(dbg_ctrl->value, 0, dbg_ctrl->size)); err = arm7_9_execute_sys_speed(target); LOG_DEBUG("disable single-step"); arm7_9->disable_single_step(target); if (err != ERROR_OK) { if ((retval = arm7_9_set_breakpoint(target, breakpoint)) != ERROR_OK) { return retval; } target->state = TARGET_UNKNOWN; return err; } arm7_9_debug_entry(target); LOG_DEBUG("new PC after step: 0x%8.8" PRIx32 "", buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32)); LOG_DEBUG("set breakpoint at 0x%8.8" PRIx32 "", breakpoint->address); if ((retval = arm7_9_set_breakpoint(target, breakpoint)) != ERROR_OK) { return retval; } } } /* enable any pending breakpoints and watchpoints */ arm7_9_enable_breakpoints(target); arm7_9_enable_watchpoints(target); if ((retval = arm7_9_restore_context(target)) != ERROR_OK) { return retval; } if (armv4_5->core_state == ARMV4_5_STATE_ARM) { arm7_9->branch_resume(target); } else if (armv4_5->core_state == ARMV4_5_STATE_THUMB) { arm7_9->branch_resume_thumb(target); } else { LOG_ERROR("unhandled core state"); return ERROR_FAIL; } /* deassert DBGACK and INTDIS */ buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGACK, 1, 0); /* INTDIS only when we really resume, not during debug execution */ if (!debug_execution) buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_INTDIS, 1, 0); embeddedice_write_reg(dbg_ctrl, buf_get_u32(dbg_ctrl->value, 0, dbg_ctrl->size)); if ((retval = arm7_9_restart_core(target)) != ERROR_OK) { return retval; } target->debug_reason = DBG_REASON_NOTHALTED; if (!debug_execution) { /* registers are now invalid */ register_cache_invalidate(armv4_5->core_cache); target->state = TARGET_RUNNING; if ((retval = target_call_event_callbacks(target, TARGET_EVENT_RESUMED)) != ERROR_OK) { return retval; } } else { target->state = TARGET_DEBUG_RUNNING; if ((retval = target_call_event_callbacks(target, TARGET_EVENT_DEBUG_RESUMED)) != ERROR_OK) { return retval; } } LOG_DEBUG("target resumed"); return ERROR_OK; } void arm7_9_enable_eice_step(struct target *target, uint32_t next_pc) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; uint32_t current_pc; current_pc = buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32); if (next_pc != current_pc) { /* setup an inverse breakpoint on the current PC * - comparator 1 matches the current address * - rangeout from comparator 1 is connected to comparator 0 rangein * - comparator 0 matches any address, as long as rangein is low */ embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~(EICE_W_CTRL_RANGE | EICE_W_CTRL_nOPC) & 0xff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_VALUE], current_pc); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_MASK], 0); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], 0x0); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); } else { embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], 0x0); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], 0xff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_VALUE], next_pc); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_MASK], 0); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_MASK], 0xffffffff); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], EICE_W_CTRL_ENABLE); embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff); } } void arm7_9_disable_eice_step(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_ADDR_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_DATA_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_VALUE]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W1_ADDR_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W1_DATA_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK]); embeddedice_store_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE]); } int arm7_9_step(struct target *target, int current, uint32_t address, int handle_breakpoints) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; struct breakpoint *breakpoint = NULL; int err, retval; if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } /* current = 1: continue on current pc, otherwise continue at
*/ if (!current) buf_set_u32(armv4_5->core_cache->reg_list[15].value, 0, 32, address); uint32_t current_pc; current_pc = buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32); /* the front-end may request us not to handle breakpoints */ if (handle_breakpoints) if ((breakpoint = breakpoint_find(target, buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32)))) if ((retval = arm7_9_unset_breakpoint(target, breakpoint)) != ERROR_OK) { return retval; } target->debug_reason = DBG_REASON_SINGLESTEP; /* calculate PC of next instruction */ uint32_t next_pc; if ((retval = arm_simulate_step(target, &next_pc)) != ERROR_OK) { uint32_t current_opcode; target_read_u32(target, current_pc, ¤t_opcode); LOG_ERROR("Couldn't calculate PC of next instruction, current opcode was 0x%8.8" PRIx32 "", current_opcode); return retval; } if ((retval = arm7_9_restore_context(target)) != ERROR_OK) { return retval; } arm7_9->enable_single_step(target, next_pc); if (armv4_5->core_state == ARMV4_5_STATE_ARM) { arm7_9->branch_resume(target); } else if (armv4_5->core_state == ARMV4_5_STATE_THUMB) { arm7_9->branch_resume_thumb(target); } else { LOG_ERROR("unhandled core state"); return ERROR_FAIL; } if ((retval = target_call_event_callbacks(target, TARGET_EVENT_RESUMED)) != ERROR_OK) { return retval; } err = arm7_9_execute_sys_speed(target); arm7_9->disable_single_step(target); /* registers are now invalid */ register_cache_invalidate(armv4_5->core_cache); if (err != ERROR_OK) { target->state = TARGET_UNKNOWN; } else { arm7_9_debug_entry(target); if ((retval = target_call_event_callbacks(target, TARGET_EVENT_HALTED)) != ERROR_OK) { return retval; } LOG_DEBUG("target stepped"); } if (breakpoint) if ((retval = arm7_9_set_breakpoint(target, breakpoint)) != ERROR_OK) { return retval; } return err; } static int arm7_9_read_core_reg(struct target *target, struct reg *r, int num, enum armv4_5_mode mode) { uint32_t* reg_p[16]; uint32_t value; int retval; struct arm_reg *areg = r->arch_info; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; if (!is_arm_mode(armv4_5->core_mode)) return ERROR_FAIL; if ((num < 0) || (num > 16)) return ERROR_INVALID_ARGUMENTS; if ((mode != ARMV4_5_MODE_ANY) && (mode != armv4_5->core_mode) && (areg->mode != ARMV4_5_MODE_ANY)) { uint32_t tmp_cpsr; /* change processor mode (mask T bit) */ tmp_cpsr = buf_get_u32(armv4_5->cpsr->value, 0, 8) & 0xE0; tmp_cpsr |= mode; tmp_cpsr &= ~0x20; arm7_9->write_xpsr_im8(target, tmp_cpsr & 0xff, 0, 0); } if ((num >= 0) && (num <= 15)) { /* read a normal core register */ reg_p[num] = &value; arm7_9->read_core_regs(target, 1 << num, reg_p); } else { /* read a program status register * if the register mode is MODE_ANY, we read the cpsr, otherwise a spsr */ arm7_9->read_xpsr(target, &value, areg->mode != ARMV4_5_MODE_ANY); } if ((retval = jtag_execute_queue()) != ERROR_OK) { return retval; } r->valid = 1; r->dirty = 0; buf_set_u32(r->value, 0, 32, value); if ((mode != ARMV4_5_MODE_ANY) && (mode != armv4_5->core_mode) && (areg->mode != ARMV4_5_MODE_ANY)) { /* restore processor mode (mask T bit) */ arm7_9->write_xpsr_im8(target, buf_get_u32(armv4_5->cpsr->value, 0, 8) & ~0x20, 0, 0); } return ERROR_OK; } static int arm7_9_write_core_reg(struct target *target, struct reg *r, int num, enum armv4_5_mode mode, uint32_t value) { uint32_t reg[16]; struct arm_reg *areg = r->arch_info; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; if (!is_arm_mode(armv4_5->core_mode)) return ERROR_FAIL; if ((num < 0) || (num > 16)) return ERROR_INVALID_ARGUMENTS; if ((mode != ARMV4_5_MODE_ANY) && (mode != armv4_5->core_mode) && (areg->mode != ARMV4_5_MODE_ANY)) { uint32_t tmp_cpsr; /* change processor mode (mask T bit) */ tmp_cpsr = buf_get_u32(armv4_5->cpsr->value, 0, 8) & 0xE0; tmp_cpsr |= mode; tmp_cpsr &= ~0x20; arm7_9->write_xpsr_im8(target, tmp_cpsr & 0xff, 0, 0); } if ((num >= 0) && (num <= 15)) { /* write a normal core register */ reg[num] = value; arm7_9->write_core_regs(target, 1 << num, reg); } else { /* write a program status register * if the register mode is MODE_ANY, we write the cpsr, otherwise a spsr */ int spsr = (areg->mode != ARMV4_5_MODE_ANY); /* if we're writing the CPSR, mask the T bit */ if (!spsr) value &= ~0x20; arm7_9->write_xpsr(target, value, spsr); } r->valid = 1; r->dirty = 0; if ((mode != ARMV4_5_MODE_ANY) && (mode != armv4_5->core_mode) && (areg->mode != ARMV4_5_MODE_ANY)) { /* restore processor mode (mask T bit) */ arm7_9->write_xpsr_im8(target, buf_get_u32(armv4_5->cpsr->value, 0, 8) & ~0x20, 0, 0); } return jtag_execute_queue(); } int arm7_9_read_memory(struct target *target, uint32_t address, uint32_t size, uint32_t count, uint8_t *buffer) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; uint32_t reg[16]; uint32_t num_accesses = 0; int thisrun_accesses; int i; uint32_t cpsr; int retval; int last_reg = 0; LOG_DEBUG("address: 0x%8.8" PRIx32 ", size: 0x%8.8" PRIx32 ", count: 0x%8.8" PRIx32 "", address, size, count); if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } /* sanitize arguments */ if (((size != 4) && (size != 2) && (size != 1)) || (count == 0) || !(buffer)) return ERROR_INVALID_ARGUMENTS; if (((size == 4) && (address & 0x3u)) || ((size == 2) && (address & 0x1u))) return ERROR_TARGET_UNALIGNED_ACCESS; /* load the base register with the address of the first word */ reg[0] = address; arm7_9->write_core_regs(target, 0x1, reg); int j = 0; switch (size) { case 4: while (num_accesses < count) { uint32_t reg_list; thisrun_accesses = ((count - num_accesses) >= 14) ? 14 : (count - num_accesses); reg_list = (0xffff >> (15 - thisrun_accesses)) & 0xfffe; if (last_reg <= thisrun_accesses) last_reg = thisrun_accesses; arm7_9->load_word_regs(target, reg_list); /* fast memory reads are only safe when the target is running * from a sufficiently high clock (32 kHz is usually too slow) */ if (arm7_9->fast_memory_access) retval = arm7_9_execute_fast_sys_speed(target); else retval = arm7_9_execute_sys_speed(target); if (retval != ERROR_OK) return retval; arm7_9->read_core_regs_target_buffer(target, reg_list, buffer, 4); /* advance buffer, count number of accesses */ buffer += thisrun_accesses * 4; num_accesses += thisrun_accesses; if ((j++%1024) == 0) { keep_alive(); } } break; case 2: while (num_accesses < count) { uint32_t reg_list; thisrun_accesses = ((count - num_accesses) >= 14) ? 14 : (count - num_accesses); reg_list = (0xffff >> (15 - thisrun_accesses)) & 0xfffe; for (i = 1; i <= thisrun_accesses; i++) { if (i > last_reg) last_reg = i; arm7_9->load_hword_reg(target, i); /* fast memory reads are only safe when the target is running * from a sufficiently high clock (32 kHz is usually too slow) */ if (arm7_9->fast_memory_access) retval = arm7_9_execute_fast_sys_speed(target); else retval = arm7_9_execute_sys_speed(target); if (retval != ERROR_OK) { return retval; } } arm7_9->read_core_regs_target_buffer(target, reg_list, buffer, 2); /* advance buffer, count number of accesses */ buffer += thisrun_accesses * 2; num_accesses += thisrun_accesses; if ((j++%1024) == 0) { keep_alive(); } } break; case 1: while (num_accesses < count) { uint32_t reg_list; thisrun_accesses = ((count - num_accesses) >= 14) ? 14 : (count - num_accesses); reg_list = (0xffff >> (15 - thisrun_accesses)) & 0xfffe; for (i = 1; i <= thisrun_accesses; i++) { if (i > last_reg) last_reg = i; arm7_9->load_byte_reg(target, i); /* fast memory reads are only safe when the target is running * from a sufficiently high clock (32 kHz is usually too slow) */ if (arm7_9->fast_memory_access) retval = arm7_9_execute_fast_sys_speed(target); else retval = arm7_9_execute_sys_speed(target); if (retval != ERROR_OK) { return retval; } } arm7_9->read_core_regs_target_buffer(target, reg_list, buffer, 1); /* advance buffer, count number of accesses */ buffer += thisrun_accesses * 1; num_accesses += thisrun_accesses; if ((j++%1024) == 0) { keep_alive(); } } break; default: LOG_ERROR("BUG: we shouldn't get here"); exit(-1); break; } if (!is_arm_mode(armv4_5->core_mode)) return ERROR_FAIL; for (i = 0; i <= last_reg; i++) { struct reg *r = arm_reg_current(armv4_5, i); r->dirty = r->valid; } arm7_9->read_xpsr(target, &cpsr, 0); if ((retval = jtag_execute_queue()) != ERROR_OK) { LOG_ERROR("JTAG error while reading cpsr"); return ERROR_TARGET_DATA_ABORT; } if (((cpsr & 0x1f) == ARMV4_5_MODE_ABT) && (armv4_5->core_mode != ARMV4_5_MODE_ABT)) { LOG_WARNING("memory read caused data abort (address: 0x%8.8" PRIx32 ", size: 0x%" PRIx32 ", count: 0x%" PRIx32 ")", address, size, count); arm7_9->write_xpsr_im8(target, buf_get_u32(armv4_5->cpsr->value, 0, 8) & ~0x20, 0, 0); return ERROR_TARGET_DATA_ABORT; } return ERROR_OK; } int arm7_9_write_memory(struct target *target, uint32_t address, uint32_t size, uint32_t count, uint8_t *buffer) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); struct arm *armv4_5 = &arm7_9->armv4_5_common; struct reg *dbg_ctrl = &arm7_9->eice_cache->reg_list[EICE_DBG_CTRL]; uint32_t reg[16]; uint32_t num_accesses = 0; int thisrun_accesses; int i; uint32_t cpsr; int retval; int last_reg = 0; #ifdef _DEBUG_ARM7_9_ LOG_DEBUG("address: 0x%8.8x, size: 0x%8.8x, count: 0x%8.8x", address, size, count); #endif if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } /* sanitize arguments */ if (((size != 4) && (size != 2) && (size != 1)) || (count == 0) || !(buffer)) return ERROR_INVALID_ARGUMENTS; if (((size == 4) && (address & 0x3u)) || ((size == 2) && (address & 0x1u))) return ERROR_TARGET_UNALIGNED_ACCESS; /* load the base register with the address of the first word */ reg[0] = address; arm7_9->write_core_regs(target, 0x1, reg); /* Clear DBGACK, to make sure memory fetches work as expected */ buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGACK, 1, 0); embeddedice_store_reg(dbg_ctrl); switch (size) { case 4: while (num_accesses < count) { uint32_t reg_list; thisrun_accesses = ((count - num_accesses) >= 14) ? 14 : (count - num_accesses); reg_list = (0xffff >> (15 - thisrun_accesses)) & 0xfffe; for (i = 1; i <= thisrun_accesses; i++) { if (i > last_reg) last_reg = i; reg[i] = target_buffer_get_u32(target, buffer); buffer += 4; } arm7_9->write_core_regs(target, reg_list, reg); arm7_9->store_word_regs(target, reg_list); /* fast memory writes are only safe when the target is running * from a sufficiently high clock (32 kHz is usually too slow) */ if (arm7_9->fast_memory_access) retval = arm7_9_execute_fast_sys_speed(target); else retval = arm7_9_execute_sys_speed(target); if (retval != ERROR_OK) { return retval; } num_accesses += thisrun_accesses; } break; case 2: while (num_accesses < count) { uint32_t reg_list; thisrun_accesses = ((count - num_accesses) >= 14) ? 14 : (count - num_accesses); reg_list = (0xffff >> (15 - thisrun_accesses)) & 0xfffe; for (i = 1; i <= thisrun_accesses; i++) { if (i > last_reg) last_reg = i; reg[i] = target_buffer_get_u16(target, buffer) & 0xffff; buffer += 2; } arm7_9->write_core_regs(target, reg_list, reg); for (i = 1; i <= thisrun_accesses; i++) { arm7_9->store_hword_reg(target, i); /* fast memory writes are only safe when the target is running * from a sufficiently high clock (32 kHz is usually too slow) */ if (arm7_9->fast_memory_access) retval = arm7_9_execute_fast_sys_speed(target); else retval = arm7_9_execute_sys_speed(target); if (retval != ERROR_OK) { return retval; } } num_accesses += thisrun_accesses; } break; case 1: while (num_accesses < count) { uint32_t reg_list; thisrun_accesses = ((count - num_accesses) >= 14) ? 14 : (count - num_accesses); reg_list = (0xffff >> (15 - thisrun_accesses)) & 0xfffe; for (i = 1; i <= thisrun_accesses; i++) { if (i > last_reg) last_reg = i; reg[i] = *buffer++ & 0xff; } arm7_9->write_core_regs(target, reg_list, reg); for (i = 1; i <= thisrun_accesses; i++) { arm7_9->store_byte_reg(target, i); /* fast memory writes are only safe when the target is running * from a sufficiently high clock (32 kHz is usually too slow) */ if (arm7_9->fast_memory_access) retval = arm7_9_execute_fast_sys_speed(target); else retval = arm7_9_execute_sys_speed(target); if (retval != ERROR_OK) { return retval; } } num_accesses += thisrun_accesses; } break; default: LOG_ERROR("BUG: we shouldn't get here"); exit(-1); break; } /* Re-Set DBGACK */ buf_set_u32(dbg_ctrl->value, EICE_DBG_CONTROL_DBGACK, 1, 1); embeddedice_store_reg(dbg_ctrl); if (!is_arm_mode(armv4_5->core_mode)) return ERROR_FAIL; for (i = 0; i <= last_reg; i++) { struct reg *r = arm_reg_current(armv4_5, i); r->dirty = r->valid; } arm7_9->read_xpsr(target, &cpsr, 0); if ((retval = jtag_execute_queue()) != ERROR_OK) { LOG_ERROR("JTAG error while reading cpsr"); return ERROR_TARGET_DATA_ABORT; } if (((cpsr & 0x1f) == ARMV4_5_MODE_ABT) && (armv4_5->core_mode != ARMV4_5_MODE_ABT)) { LOG_WARNING("memory write caused data abort (address: 0x%8.8" PRIx32 ", size: 0x%" PRIx32 ", count: 0x%" PRIx32 ")", address, size, count); arm7_9->write_xpsr_im8(target, buf_get_u32(armv4_5->cpsr->value, 0, 8) & ~0x20, 0, 0); return ERROR_TARGET_DATA_ABORT; } return ERROR_OK; } static int dcc_count; static uint8_t *dcc_buffer; static int arm7_9_dcc_completion(struct target *target, uint32_t exit_point, int timeout_ms, void *arch_info) { int retval = ERROR_OK; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if ((retval = target_wait_state(target, TARGET_DEBUG_RUNNING, 500)) != ERROR_OK) return retval; int little = target->endianness == TARGET_LITTLE_ENDIAN; int count = dcc_count; uint8_t *buffer = dcc_buffer; if (count > 2) { /* Handle first & last using standard embeddedice_write_reg and the middle ones w/the * core function repeated. */ embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_COMMS_DATA], fast_target_buffer_get_u32(buffer, little)); buffer += 4; struct embeddedice_reg *ice_reg = arm7_9->eice_cache->reg_list[EICE_COMMS_DATA].arch_info; uint8_t reg_addr = ice_reg->addr & 0x1f; struct jtag_tap *tap; tap = ice_reg->jtag_info->tap; embeddedice_write_dcc(tap, reg_addr, buffer, little, count-2); buffer += (count-2)*4; embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_COMMS_DATA], fast_target_buffer_get_u32(buffer, little)); } else { int i; for (i = 0; i < count; i++) { embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_COMMS_DATA], fast_target_buffer_get_u32(buffer, little)); buffer += 4; } } if ((retval = target_halt(target))!= ERROR_OK) { return retval; } return target_wait_state(target, TARGET_HALTED, 500); } static const uint32_t dcc_code[] = { /* r0 == input, points to memory buffer * r1 == scratch */ /* spin until DCC control (c0) reports data arrived */ 0xee101e10, /* w: mrc p14, #0, r1, c0, c0 */ 0xe3110001, /* tst r1, #1 */ 0x0afffffc, /* bne w */ /* read word from DCC (c1), write to memory */ 0xee111e10, /* mrc p14, #0, r1, c1, c0 */ 0xe4801004, /* str r1, [r0], #4 */ /* repeat */ 0xeafffff9 /* b w */ }; extern int armv4_5_run_algorithm_inner(struct target *target, int num_mem_params, struct mem_param *mem_params, int num_reg_params, struct reg_param *reg_params, uint32_t entry_point, uint32_t exit_point, int timeout_ms, void *arch_info, int (*run_it)(struct target *target, uint32_t exit_point, int timeout_ms, void *arch_info)); int arm7_9_bulk_write_memory(struct target *target, uint32_t address, uint32_t count, uint8_t *buffer) { int retval; struct arm7_9_common *arm7_9 = target_to_arm7_9(target); int i; if (!arm7_9->dcc_downloads) return target_write_memory(target, address, 4, count, buffer); /* regrab previously allocated working_area, or allocate a new one */ if (!arm7_9->dcc_working_area) { uint8_t dcc_code_buf[6 * 4]; /* make sure we have a working area */ if (target_alloc_working_area(target, 24, &arm7_9->dcc_working_area) != ERROR_OK) { LOG_INFO("no working area available, falling back to memory writes"); return target_write_memory(target, address, 4, count, buffer); } /* copy target instructions to target endianness */ for (i = 0; i < 6; i++) { target_buffer_set_u32(target, dcc_code_buf + i*4, dcc_code[i]); } /* write DCC code to working area */ if ((retval = target_write_memory(target, arm7_9->dcc_working_area->address, 4, 6, dcc_code_buf)) != ERROR_OK) { return retval; } } struct armv4_5_algorithm armv4_5_info; struct reg_param reg_params[1]; armv4_5_info.common_magic = ARMV4_5_COMMON_MAGIC; armv4_5_info.core_mode = ARMV4_5_MODE_SVC; armv4_5_info.core_state = ARMV4_5_STATE_ARM; init_reg_param(®_params[0], "r0", 32, PARAM_IN_OUT); buf_set_u32(reg_params[0].value, 0, 32, address); dcc_count = count; dcc_buffer = buffer; retval = armv4_5_run_algorithm_inner(target, 0, NULL, 1, reg_params, arm7_9->dcc_working_area->address, arm7_9->dcc_working_area->address + 6*4, 20*1000, &armv4_5_info, arm7_9_dcc_completion); if (retval == ERROR_OK) { uint32_t endaddress = buf_get_u32(reg_params[0].value, 0, 32); if (endaddress != (address + count*4)) { LOG_ERROR("DCC write failed, expected end address 0x%08" PRIx32 " got 0x%0" PRIx32 "", (address + count*4), endaddress); retval = ERROR_FAIL; } } destroy_reg_param(®_params[0]); return retval; } /** * Perform per-target setup that requires JTAG access. */ int arm7_9_examine(struct target *target) { struct arm7_9_common *arm7_9 = target_to_arm7_9(target); int retval; if (!target_was_examined(target)) { struct reg_cache *t, **cache_p; t = embeddedice_build_reg_cache(target, arm7_9); if (t == NULL) return ERROR_FAIL; cache_p = register_get_last_cache_p(&target->reg_cache); (*cache_p) = t; arm7_9->eice_cache = (*cache_p); if (arm7_9->armv4_5_common.etm) (*cache_p)->next = etm_build_reg_cache(target, &arm7_9->jtag_info, arm7_9->armv4_5_common.etm); target_set_examined(target); } retval = embeddedice_setup(target); if (retval == ERROR_OK) retval = arm7_9_setup(target); if (retval == ERROR_OK && arm7_9->armv4_5_common.etm) retval = etm_setup(target); return retval; } COMMAND_HANDLER(handle_arm7_9_dbgrq_command) { struct target *target = get_current_target(CMD_CTX); struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if (!is_arm7_9(arm7_9)) { command_print(CMD_CTX, "current target isn't an ARM7/ARM9 target"); return ERROR_TARGET_INVALID; } if (CMD_ARGC > 0) COMMAND_PARSE_ENABLE(CMD_ARGV[0],arm7_9->use_dbgrq); command_print(CMD_CTX, "use of EmbeddedICE dbgrq instead of breakpoint for target halt %s", (arm7_9->use_dbgrq) ? "enabled" : "disabled"); return ERROR_OK; } COMMAND_HANDLER(handle_arm7_9_fast_memory_access_command) { struct target *target = get_current_target(CMD_CTX); struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if (!is_arm7_9(arm7_9)) { command_print(CMD_CTX, "current target isn't an ARM7/ARM9 target"); return ERROR_TARGET_INVALID; } if (CMD_ARGC > 0) COMMAND_PARSE_ENABLE(CMD_ARGV[0], arm7_9->fast_memory_access); command_print(CMD_CTX, "fast memory access is %s", (arm7_9->fast_memory_access) ? "enabled" : "disabled"); return ERROR_OK; } COMMAND_HANDLER(handle_arm7_9_dcc_downloads_command) { struct target *target = get_current_target(CMD_CTX); struct arm7_9_common *arm7_9 = target_to_arm7_9(target); if (!is_arm7_9(arm7_9)) { command_print(CMD_CTX, "current target isn't an ARM7/ARM9 target"); return ERROR_TARGET_INVALID; } if (CMD_ARGC > 0) COMMAND_PARSE_ENABLE(CMD_ARGV[0], arm7_9->dcc_downloads); command_print(CMD_CTX, "dcc downloads are %s", (arm7_9->dcc_downloads) ? "enabled" : "disabled"); return ERROR_OK; } int arm7_9_init_arch_info(struct target *target, struct arm7_9_common *arm7_9) { int retval = ERROR_OK; struct arm *armv4_5 = &arm7_9->armv4_5_common; arm7_9->common_magic = ARM7_9_COMMON_MAGIC; if ((retval = arm_jtag_setup_connection(&arm7_9->jtag_info)) != ERROR_OK) return retval; /* caller must have allocated via calloc(), so everything's zeroed */ arm7_9->wp_available_max = 2; arm7_9->fast_memory_access = false; arm7_9->dcc_downloads = false; armv4_5->arch_info = arm7_9; armv4_5->read_core_reg = arm7_9_read_core_reg; armv4_5->write_core_reg = arm7_9_write_core_reg; armv4_5->full_context = arm7_9_full_context; if ((retval = armv4_5_init_arch_info(target, armv4_5)) != ERROR_OK) return retval; return target_register_timer_callback(arm7_9_handle_target_request, 1, 1, target); } static const struct command_registration arm7_9_any_command_handlers[] = { { "dbgrq", .handler = &handle_arm7_9_dbgrq_command, .mode = COMMAND_ANY, .usage = "", .help = "use EmbeddedICE dbgrq instead of breakpoint " "for target halt requests", }, { "fast_memory_access", .handler = &handle_arm7_9_fast_memory_access_command, .mode = COMMAND_ANY, .usage = "", .help = "use fast memory accesses instead of slower " "but potentially safer accesses", }, { "dcc_downloads", .handler = &handle_arm7_9_dcc_downloads_command, .mode = COMMAND_ANY, .usage = "", .help = "use DCC downloads for larger memory writes", }, COMMAND_REGISTRATION_DONE }; const struct command_registration arm7_9_command_handlers[] = { { .chain = arm_command_handlers, }, { .chain = etm_command_handlers, }, { .name = "arm7_9", .mode = COMMAND_ANY, .help = "arm7/9 specific commands", .chain = arm7_9_any_command_handlers, }, COMMAND_REGISTRATION_DONE }; href='#n2315'>2315 2316 2317 2318 2319 2320 2321 2322 2323 2324 2325 2326 2327 2328 2329 2330 2331 2332 2333 2334 2335 2336 2337 2338 2339 2340 2341 2342 2343 2344 2345 2346 2347 2348 2349 2350 2351 2352 2353 2354 2355 2356 2357 2358 2359 2360 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