/*************************************************************************** * Copyright (C) 2005 by Dominic Rath * * Dominic.Rath@gmx.de * * * * Copyright (C) 2006 by Magnus Lundin * * lundin@mlu.mine.nu * * * * Copyright (C) 2008 by Spencer Oliver * * spen@spen-soft.co.uk * * * * Copyright (C) 2009 by Dirk Behme * * dirk.behme@gmail.com - copy from cortex_m3 * * * * 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. * * * * Cortex-A8(tm) TRM, ARM DDI 0344H * * * ***************************************************************************/ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "breakpoints.h" #include "cortex_a8.h" #include "register.h" #include "target_request.h" #include "target_type.h" static int cortex_a8_poll(struct target *target); static int cortex_a8_debug_entry(struct target *target); static int cortex_a8_restore_context(struct target *target); static int cortex_a8_set_breakpoint(struct target *target, struct breakpoint *breakpoint, uint8_t matchmode); static int cortex_a8_unset_breakpoint(struct target *target, struct breakpoint *breakpoint); static int cortex_a8_dap_read_coreregister_u32(struct target *target, uint32_t *value, int regnum); static int cortex_a8_dap_write_coreregister_u32(struct target *target, uint32_t value, int regnum); /* * FIXME do topology discovery using the ROM; don't * assume this is an OMAP3. */ #define swjdp_memoryap 0 #define swjdp_debugap 1 #define OMAP3530_DEBUG_BASE 0x54011000 /* * Cortex-A8 Basic debug access, very low level assumes state is saved */ static int cortex_a8_init_debug_access(struct target *target) { struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; int retval; uint32_t dummy; LOG_DEBUG(" "); /* Unlocking the debug registers for modification */ /* The debugport might be uninitialised so try twice */ retval = mem_ap_write_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_LOCKACCESS, 0xC5ACCE55); if (retval != ERROR_OK) mem_ap_write_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_LOCKACCESS, 0xC5ACCE55); /* Clear Sticky Power Down status Bit in PRSR to enable access to the registers in the Core Power Domain */ retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_PRSR, &dummy); /* Enabling of instruction execution in debug mode is done in debug_entry code */ /* Resync breakpoint registers */ /* Since this is likley called from init or reset, update targtet state information*/ cortex_a8_poll(target); return retval; } /* To reduce needless round-trips, pass in a pointer to the current * DSCR value. Initialize it to zero if you just need to know the * value on return from this function; or (1 << DSCR_INSTR_COMP) if * you happen to know that no instruction is pending. */ static int cortex_a8_exec_opcode(struct target *target, uint32_t opcode, uint32_t *dscr_p) { uint32_t dscr; int retval; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; dscr = dscr_p ? *dscr_p : 0; LOG_DEBUG("exec opcode 0x%08" PRIx32, opcode); /* Wait for InstrCompl bit to be set */ while ((dscr & (1 << DSCR_INSTR_COMP)) == 0) { retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); if (retval != ERROR_OK) { LOG_ERROR("Could not read DSCR register, opcode = 0x%08" PRIx32, opcode); return retval; } } mem_ap_write_u32(swjdp, armv7a->debug_base + CPUDBG_ITR, opcode); do { retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); if (retval != ERROR_OK) { LOG_ERROR("Could not read DSCR register"); return retval; } } while ((dscr & (1 << DSCR_INSTR_COMP)) == 0); /* Wait for InstrCompl bit to be set */ if (dscr_p) *dscr_p = dscr; return retval; } /************************************************************************** Read core register with very few exec_opcode, fast but needs work_area. This can cause problems with MMU active. **************************************************************************/ static int cortex_a8_read_regs_through_mem(struct target *target, uint32_t address, uint32_t * regfile) { int retval = ERROR_OK; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; cortex_a8_dap_read_coreregister_u32(target, regfile, 0); cortex_a8_dap_write_coreregister_u32(target, address, 0); cortex_a8_exec_opcode(target, ARMV4_5_STMIA(0, 0xFFFE, 0, 0), NULL); dap_ap_select(swjdp, swjdp_memoryap); mem_ap_read_buf_u32(swjdp, (uint8_t *)(®file[1]), 4*15, address); dap_ap_select(swjdp, swjdp_debugap); return retval; } static int cortex_a8_read_cp(struct target *target, uint32_t *value, uint8_t CP, uint8_t op1, uint8_t CRn, uint8_t CRm, uint8_t op2) { int retval; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; uint32_t dscr = 0; /* MRC(...) to read coprocessor register into r0 */ cortex_a8_exec_opcode(target, ARMV4_5_MRC(CP, op1, 0, CRn, CRm, op2), &dscr); /* Move R0 to DTRTX */ cortex_a8_exec_opcode(target, ARMV4_5_MCR(14, 0, 0, 0, 5, 0), &dscr); /* Read DCCTX */ retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DTRTX, value); return retval; } static int cortex_a8_write_cp(struct target *target, uint32_t value, uint8_t CP, uint8_t op1, uint8_t CRn, uint8_t CRm, uint8_t op2) { int retval; uint32_t dscr; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; LOG_DEBUG("CP%i, CRn %i, value 0x%08" PRIx32, CP, CRn, value); /* Check that DCCRX is not full */ retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); if (dscr & (1 << DSCR_DTR_RX_FULL)) { LOG_ERROR("DSCR_DTR_RX_FULL, dscr 0x%08" PRIx32, dscr); /* Clear DCCRX with MCR(p14, 0, Rd, c0, c5, 0), opcode 0xEE000E15 */ cortex_a8_exec_opcode(target, ARMV4_5_MRC(14, 0, 0, 0, 5, 0), &dscr); } /* Write DTRRX ... sets DSCR.DTRRXfull but exec_opcode() won't care */ retval = mem_ap_write_u32(swjdp, armv7a->debug_base + CPUDBG_DTRRX, value); /* Move DTRRX to r0 */ cortex_a8_exec_opcode(target, ARMV4_5_MRC(14, 0, 0, 0, 5, 0), &dscr); /* MCR(...) to write r0 to coprocessor */ return cortex_a8_exec_opcode(target, ARMV4_5_MCR(CP, op1, 0, CRn, CRm, op2), &dscr); } static int cortex_a8_read_cp15(struct target *target, uint32_t op1, uint32_t op2, uint32_t CRn, uint32_t CRm, uint32_t *value) { return cortex_a8_read_cp(target, value, 15, op1, CRn, CRm, op2); } static int cortex_a8_write_cp15(struct target *target, uint32_t op1, uint32_t op2, uint32_t CRn, uint32_t CRm, uint32_t value) { return cortex_a8_write_cp(target, value, 15, op1, CRn, CRm, op2); } static int cortex_a8_mrc(struct target *target, int cpnum, uint32_t op1, uint32_t op2, uint32_t CRn, uint32_t CRm, uint32_t *value) { if (cpnum!=15) { LOG_ERROR("Only cp15 is supported"); return ERROR_FAIL; } return cortex_a8_read_cp15(target, op1, op2, CRn, CRm, value); } static int cortex_a8_mcr(struct target *target, int cpnum, uint32_t op1, uint32_t op2, uint32_t CRn, uint32_t CRm, uint32_t value) { if (cpnum!=15) { LOG_ERROR("Only cp15 is supported"); return ERROR_FAIL; } return cortex_a8_write_cp15(target, op1, op2, CRn, CRm, value); } static int cortex_a8_dap_read_coreregister_u32(struct target *target, uint32_t *value, int regnum) { int retval = ERROR_OK; uint8_t reg = regnum&0xFF; uint32_t dscr = 0; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; if (reg > 17) return retval; if (reg < 15) { /* Rn to DCCTX, "MCR p14, 0, Rn, c0, c5, 0" 0xEE00nE15 */ cortex_a8_exec_opcode(target, ARMV4_5_MCR(14, 0, reg, 0, 5, 0), &dscr); } else if (reg == 15) { /* "MOV r0, r15"; then move r0 to DCCTX */ cortex_a8_exec_opcode(target, 0xE1A0000F, &dscr); cortex_a8_exec_opcode(target, ARMV4_5_MCR(14, 0, 0, 0, 5, 0), &dscr); } else { /* "MRS r0, CPSR" or "MRS r0, SPSR" * then move r0 to DCCTX */ cortex_a8_exec_opcode(target, ARMV4_5_MRS(0, reg & 1), &dscr); cortex_a8_exec_opcode(target, ARMV4_5_MCR(14, 0, 0, 0, 5, 0), &dscr); } /* Wait for DTRRXfull then read DTRRTX */ while ((dscr & (1 << DSCR_DTR_TX_FULL)) == 0) { retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); } retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DTRTX, value); LOG_DEBUG("read DCC 0x%08" PRIx32, *value); return retval; } static int cortex_a8_dap_write_coreregister_u32(struct target *target, uint32_t value, int regnum) { int retval = ERROR_OK; uint8_t Rd = regnum&0xFF; uint32_t dscr; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; LOG_DEBUG("register %i, value 0x%08" PRIx32, regnum, value); /* Check that DCCRX is not full */ retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); if (dscr & (1 << DSCR_DTR_RX_FULL)) { LOG_ERROR("DSCR_DTR_RX_FULL, dscr 0x%08" PRIx32, dscr); /* Clear DCCRX with MCR(p14, 0, Rd, c0, c5, 0), opcode 0xEE000E15 */ cortex_a8_exec_opcode(target, ARMV4_5_MRC(14, 0, 0, 0, 5, 0), &dscr); } if (Rd > 17) return retval; /* Write DTRRX ... sets DSCR.DTRRXfull but exec_opcode() won't care */ LOG_DEBUG("write DCC 0x%08" PRIx32, value); retval = mem_ap_write_u32(swjdp, armv7a->debug_base + CPUDBG_DTRRX, value); if (Rd < 15) { /* DCCRX to Rn, "MCR p14, 0, Rn, c0, c5, 0", 0xEE00nE15 */ cortex_a8_exec_opcode(target, ARMV4_5_MRC(14, 0, Rd, 0, 5, 0), &dscr); } else if (Rd == 15) { /* DCCRX to R0, "MCR p14, 0, R0, c0, c5, 0", 0xEE000E15 * then "mov r15, r0" */ cortex_a8_exec_opcode(target, ARMV4_5_MRC(14, 0, 0, 0, 5, 0), &dscr); cortex_a8_exec_opcode(target, 0xE1A0F000, &dscr); } else { /* DCCRX to R0, "MCR p14, 0, R0, c0, c5, 0", 0xEE000E15 * then "MSR CPSR_cxsf, r0" or "MSR SPSR_cxsf, r0" (all fields) */ cortex_a8_exec_opcode(target, ARMV4_5_MRC(14, 0, 0, 0, 5, 0), &dscr); cortex_a8_exec_opcode(target, ARMV4_5_MSR_GP(0, 0xF, Rd & 1), &dscr); /* "Prefetch flush" after modifying execution status in CPSR */ if (Rd == 16) cortex_a8_exec_opcode(target, ARMV4_5_MCR(15, 0, 0, 7, 5, 4), &dscr); } return retval; } /* Write to memory mapped registers directly with no cache or mmu handling */ static int cortex_a8_dap_write_memap_register_u32(struct target *target, uint32_t address, uint32_t value) { int retval; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; retval = mem_ap_write_atomic_u32(swjdp, address, value); return retval; } /* * Cortex-A8 implementation of Debug Programmer's Model * * NOTE the invariant: these routines return with DSCR_INSTR_COMP set, * so there's no need to poll for it before executing an instruction. * * NOTE that in several of these cases the "stall" mode might be useful. * It'd let us queue a few operations together... prepare/finish might * be the places to enable/disable that mode. */ static inline struct cortex_a8_common *dpm_to_a8(struct arm_dpm *dpm) { return container_of(dpm, struct cortex_a8_common, armv7a_common.dpm); } static int cortex_a8_write_dcc(struct cortex_a8_common *a8, uint32_t data) { LOG_DEBUG("write DCC 0x%08" PRIx32, data); return mem_ap_write_u32(&a8->armv7a_common.swjdp_info, a8->armv7a_common.debug_base + CPUDBG_DTRRX, data); } static int cortex_a8_read_dcc(struct cortex_a8_common *a8, uint32_t *data, uint32_t *dscr_p) { struct swjdp_common *swjdp = &a8->armv7a_common.swjdp_info; uint32_t dscr = 1 << DSCR_INSTR_COMP; int retval; if (dscr_p) dscr = *dscr_p; /* Wait for DTRRXfull */ while ((dscr & (1 << DSCR_DTR_TX_FULL)) == 0) { retval = mem_ap_read_atomic_u32(swjdp, a8->armv7a_common.debug_base + CPUDBG_DSCR, &dscr); } retval = mem_ap_read_atomic_u32(swjdp, a8->armv7a_common.debug_base + CPUDBG_DTRTX, data); LOG_DEBUG("read DCC 0x%08" PRIx32, *data); if (dscr_p) *dscr_p = dscr; return retval; } static int cortex_a8_dpm_prepare(struct arm_dpm *dpm) { struct cortex_a8_common *a8 = dpm_to_a8(dpm); struct swjdp_common *swjdp = &a8->armv7a_common.swjdp_info; uint32_t dscr; int retval; /* set up invariant: INSTR_COMP is set after ever DPM operation */ do { retval = mem_ap_read_atomic_u32(swjdp, a8->armv7a_common.debug_base + CPUDBG_DSCR, &dscr); } while ((dscr & (1 << DSCR_INSTR_COMP)) == 0); /* this "should never happen" ... */ if (dscr & (1 << DSCR_DTR_RX_FULL)) { LOG_ERROR("DSCR_DTR_RX_FULL, dscr 0x%08" PRIx32, dscr); /* Clear DCCRX */ retval = cortex_a8_exec_opcode( a8->armv7a_common.armv4_5_common.target, ARMV4_5_MRC(14, 0, 0, 0, 5, 0), &dscr); } return retval; } static int cortex_a8_dpm_finish(struct arm_dpm *dpm) { /* REVISIT what could be done here? */ return ERROR_OK; } static int cortex_a8_instr_write_data_dcc(struct arm_dpm *dpm, uint32_t opcode, uint32_t data) { struct cortex_a8_common *a8 = dpm_to_a8(dpm); int retval; uint32_t dscr = 1 << DSCR_INSTR_COMP; retval = cortex_a8_write_dcc(a8, data); return cortex_a8_exec_opcode( a8->armv7a_common.armv4_5_common.target, opcode, &dscr); } static int cortex_a8_instr_write_data_r0(struct arm_dpm *dpm, uint32_t opcode, uint32_t data) { struct cortex_a8_common *a8 = dpm_to_a8(dpm); uint32_t dscr = 1 << DSCR_INSTR_COMP; int retval; retval = cortex_a8_write_dcc(a8, data); /* DCCRX to R0, "MCR p14, 0, R0, c0, c5, 0", 0xEE000E15 */ retval = cortex_a8_exec_opcode( a8->armv7a_common.armv4_5_common.target, ARMV4_5_MRC(14, 0, 0, 0, 5, 0), &dscr); /* then the opcode, taking data from R0 */ retval = cortex_a8_exec_opcode( a8->armv7a_common.armv4_5_common.target, opcode, &dscr); return retval; } static int cortex_a8_instr_cpsr_sync(struct arm_dpm *dpm) { struct target *target = dpm->arm->target; uint32_t dscr = 1 << DSCR_INSTR_COMP; /* "Prefetch flush" after modifying execution status in CPSR */ return cortex_a8_exec_opcode(target, ARMV4_5_MCR(15, 0, 0, 7, 5, 4), &dscr); } static int cortex_a8_instr_read_data_dcc(struct arm_dpm *dpm, uint32_t opcode, uint32_t *data) { struct cortex_a8_common *a8 = dpm_to_a8(dpm); int retval; uint32_t dscr = 1 << DSCR_INSTR_COMP; /* the opcode, writing data to DCC */ retval = cortex_a8_exec_opcode( a8->armv7a_common.armv4_5_common.target, opcode, &dscr); return cortex_a8_read_dcc(a8, data, &dscr); } static int cortex_a8_instr_read_data_r0(struct arm_dpm *dpm, uint32_t opcode, uint32_t *data) { struct cortex_a8_common *a8 = dpm_to_a8(dpm); uint32_t dscr = 1 << DSCR_INSTR_COMP; int retval; /* the opcode, writing data to R0 */ retval = cortex_a8_exec_opcode( a8->armv7a_common.armv4_5_common.target, opcode, &dscr); /* write R0 to DCC */ retval = cortex_a8_exec_opcode( a8->armv7a_common.armv4_5_common.target, ARMV4_5_MCR(14, 0, 0, 0, 5, 0), &dscr); return cortex_a8_read_dcc(a8, data, &dscr); } static int cortex_a8_dpm_setup(struct cortex_a8_common *a8, uint32_t didr) { struct arm_dpm *dpm = &a8->armv7a_common.dpm; dpm->arm = &a8->armv7a_common.armv4_5_common; dpm->didr = didr; dpm->prepare = cortex_a8_dpm_prepare; dpm->finish = cortex_a8_dpm_finish; dpm->instr_write_data_dcc = cortex_a8_instr_write_data_dcc; dpm->instr_write_data_r0 = cortex_a8_instr_write_data_r0; dpm->instr_cpsr_sync = cortex_a8_instr_cpsr_sync; dpm->instr_read_data_dcc = cortex_a8_instr_read_data_dcc; dpm->instr_read_data_r0 = cortex_a8_instr_read_data_r0; return arm_dpm_setup(dpm); } /* * Cortex-A8 Run control */ static int cortex_a8_poll(struct target *target) { int retval = ERROR_OK; uint32_t dscr; struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); struct armv7a_common *armv7a = &cortex_a8->armv7a_common; struct swjdp_common *swjdp = &armv7a->swjdp_info; enum target_state prev_target_state = target->state; uint8_t saved_apsel = dap_ap_get_select(swjdp); dap_ap_select(swjdp, swjdp_debugap); retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); if (retval != ERROR_OK) { dap_ap_select(swjdp, saved_apsel); return retval; } cortex_a8->cpudbg_dscr = dscr; if ((dscr & 0x3) == 0x3) { if (prev_target_state != TARGET_HALTED) { /* We have a halting debug event */ LOG_DEBUG("Target halted"); target->state = TARGET_HALTED; if ((prev_target_state == TARGET_RUNNING) || (prev_target_state == TARGET_RESET)) { retval = cortex_a8_debug_entry(target); if (retval != ERROR_OK) return retval; target_call_event_callbacks(target, TARGET_EVENT_HALTED); } if (prev_target_state == TARGET_DEBUG_RUNNING) { LOG_DEBUG(" "); retval = cortex_a8_debug_entry(target); if (retval != ERROR_OK) return retval; target_call_event_callbacks(target, TARGET_EVENT_DEBUG_HALTED); } } } else if ((dscr & 0x3) == 0x2) { target->state = TARGET_RUNNING; } else { LOG_DEBUG("Unknown target state dscr = 0x%08" PRIx32, dscr); target->state = TARGET_UNKNOWN; } dap_ap_select(swjdp, saved_apsel); return retval; } static int cortex_a8_halt(struct target *target) { int retval = ERROR_OK; uint32_t dscr; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; uint8_t saved_apsel = dap_ap_get_select(swjdp); dap_ap_select(swjdp, swjdp_debugap); /* * Tell the core to be halted by writing DRCR with 0x1 * and then wait for the core to be halted. */ retval = mem_ap_write_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DRCR, 0x1); /* * enter halting debug mode */ mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); retval = mem_ap_write_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, dscr | (1 << DSCR_HALT_DBG_MODE)); if (retval != ERROR_OK) goto out; do { mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); } while ((dscr & (1 << DSCR_CORE_HALTED)) == 0); target->debug_reason = DBG_REASON_DBGRQ; out: dap_ap_select(swjdp, saved_apsel); return retval; } static int cortex_a8_resume(struct target *target, int current, uint32_t address, int handle_breakpoints, int debug_execution) { struct armv7a_common *armv7a = target_to_armv7a(target); struct arm *armv4_5 = &armv7a->armv4_5_common; struct swjdp_common *swjdp = &armv7a->swjdp_info; // struct breakpoint *breakpoint = NULL; uint32_t resume_pc, dscr; uint8_t saved_apsel = dap_ap_get_select(swjdp); dap_ap_select(swjdp, swjdp_debugap); if (!debug_execution) { target_free_all_working_areas(target); // cortex_m3_enable_breakpoints(target); // cortex_m3_enable_watchpoints(target); } #if 0 if (debug_execution) { /* Disable interrupts */ /* We disable interrupts in the PRIMASK register instead of * masking with C_MASKINTS, * This is probably the same issue as Cortex-M3 Errata 377493: * C_MASKINTS in parallel with disabled interrupts can cause * local faults to not be taken. */ buf_set_u32(armv7m->core_cache->reg_list[ARMV7M_PRIMASK].value, 0, 32, 1); armv7m->core_cache->reg_list[ARMV7M_PRIMASK].dirty = 1; armv7m->core_cache->reg_list[ARMV7M_PRIMASK].valid = 1; /* Make sure we are in Thumb mode */ buf_set_u32(armv7m->core_cache->reg_list[ARMV7M_xPSR].value, 0, 32, buf_get_u32(armv7m->core_cache->reg_list[ARMV7M_xPSR].value, 0, 32) | (1 << 24)); armv7m->core_cache->reg_list[ARMV7M_xPSR].dirty = 1; armv7m->core_cache->reg_list[ARMV7M_xPSR].valid = 1; } #endif /* current = 1: continue on current pc, otherwise continue at
*/ resume_pc = buf_get_u32( armv4_5->core_cache->reg_list[15].value, 0, 32); if (!current) resume_pc = address; /* Make sure that the Armv7 gdb thumb fixups does not * kill the return address */ switch (armv4_5->core_state) { case ARMV4_5_STATE_ARM: resume_pc &= 0xFFFFFFFC; break; case ARMV4_5_STATE_THUMB: case ARM_STATE_THUMB_EE: /* When the return address is loaded into PC * bit 0 must be 1 to stay in Thumb state */ resume_pc |= 0x1; break; case ARMV4_5_STATE_JAZELLE: LOG_ERROR("How do I resume into Jazelle state??"); return ERROR_FAIL; } LOG_DEBUG("resume pc = 0x%08" PRIx32, resume_pc); buf_set_u32(armv4_5->core_cache->reg_list[15].value, 0, 32, resume_pc); armv4_5->core_cache->reg_list[15].dirty = 1; armv4_5->core_cache->reg_list[15].valid = 1; cortex_a8_restore_context(target); #if 0 /* the front-end may request us not to handle breakpoints */ if (handle_breakpoints) { /* Single step past breakpoint at current address */ if ((breakpoint = breakpoint_find(target, resume_pc))) { LOG_DEBUG("unset breakpoint at 0x%8.8x", breakpoint->address); cortex_m3_unset_breakpoint(target, breakpoint); cortex_m3_single_step_core(target); cortex_m3_set_breakpoint(target, breakpoint); } } #endif /* Restart core and wait for it to be started */ mem_ap_write_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DRCR, 0x2); do { mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); } while ((dscr & (1 << DSCR_CORE_RESTARTED)) == 0); target->debug_reason = DBG_REASON_NOTHALTED; target->state = TARGET_RUNNING; /* registers are now invalid */ register_cache_invalidate(armv4_5->core_cache); if (!debug_execution) { target->state = TARGET_RUNNING; target_call_event_callbacks(target, TARGET_EVENT_RESUMED); LOG_DEBUG("target resumed at 0x%" PRIx32, resume_pc); } else { target->state = TARGET_DEBUG_RUNNING; target_call_event_callbacks(target, TARGET_EVENT_DEBUG_RESUMED); LOG_DEBUG("target debug resumed at 0x%" PRIx32, resume_pc); } dap_ap_select(swjdp, saved_apsel); return ERROR_OK; } static int cortex_a8_debug_entry(struct target *target) { int i; uint32_t regfile[16], pc, cpsr, dscr; int retval = ERROR_OK; struct working_area *regfile_working_area = NULL; struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); struct armv7a_common *armv7a = target_to_armv7a(target); struct arm *armv4_5 = &armv7a->armv4_5_common; struct swjdp_common *swjdp = &armv7a->swjdp_info; struct reg *reg; LOG_DEBUG("dscr = 0x%08" PRIx32, cortex_a8->cpudbg_dscr); /* Enable the ITR execution once we are in debug mode */ mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, &dscr); /* REVISIT see A8 TRM 12.11.4 steps 2..3 -- make sure that any * imprecise data aborts get discarded by issuing a Data * Synchronization Barrier: ARMV4_5_MCR(15, 0, 0, 7, 10, 4). */ dscr |= (1 << DSCR_EXT_INT_EN); retval = mem_ap_write_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DSCR, dscr); /* Examine debug reason */ switch ((cortex_a8->cpudbg_dscr >> 2)&0xF) { case 0: /* DRCR[0] write */ case 4: /* EDBGRQ */ target->debug_reason = DBG_REASON_DBGRQ; break; case 1: /* HW breakpoint */ case 3: /* SW BKPT */ case 5: /* vector catch */ target->debug_reason = DBG_REASON_BREAKPOINT; break; case 10: /* precise watchpoint */ target->debug_reason = DBG_REASON_WATCHPOINT; /* REVISIT could collect WFAR later, to see just * which instruction triggered the watchpoint. */ break; default: target->debug_reason = DBG_REASON_UNDEFINED; break; } /* REVISIT fast_reg_read is never set ... */ /* Examine target state and mode */ if (cortex_a8->fast_reg_read) target_alloc_working_area(target, 64, ®file_working_area); /* First load register acessible through core debug port*/ if (!regfile_working_area) { retval = arm_dpm_read_current_registers(&armv7a->dpm); } else { dap_ap_select(swjdp, swjdp_memoryap); cortex_a8_read_regs_through_mem(target, regfile_working_area->address, regfile); dap_ap_select(swjdp, swjdp_memoryap); target_free_working_area(target, regfile_working_area); /* read Current PSR */ cortex_a8_dap_read_coreregister_u32(target, &cpsr, 16); pc = regfile[15]; dap_ap_select(swjdp, swjdp_debugap); LOG_DEBUG("cpsr: %8.8" PRIx32, cpsr); arm_set_cpsr(armv4_5, cpsr); /* update cache */ for (i = 0; i <= ARM_PC; i++) { reg = arm_reg_current(armv4_5, i); buf_set_u32(reg->value, 0, 32, regfile[i]); reg->valid = 1; reg->dirty = 0; } /* Fixup PC Resume Address */ if (cpsr & (1 << 5)) { // T bit set for Thumb or ThumbEE state regfile[ARM_PC] -= 4; } else { // ARM state regfile[ARM_PC] -= 8; } reg = armv4_5->core_cache->reg_list + 15; buf_set_u32(reg->value, 0, 32, regfile[ARM_PC]); reg->dirty = reg->valid; } #if 0 /* TODO, Move this */ uint32_t cp15_control_register, cp15_cacr, cp15_nacr; cortex_a8_read_cp(target, &cp15_control_register, 15, 0, 1, 0, 0); LOG_DEBUG("cp15_control_register = 0x%08x", cp15_control_register); cortex_a8_read_cp(target, &cp15_cacr, 15, 0, 1, 0, 2); LOG_DEBUG("cp15 Coprocessor Access Control Register = 0x%08x", cp15_cacr); cortex_a8_read_cp(target, &cp15_nacr, 15, 0, 1, 1, 2); LOG_DEBUG("cp15 Nonsecure Access Control Register = 0x%08x", cp15_nacr); #endif /* Are we in an exception handler */ // armv4_5->exception_number = 0; if (armv7a->post_debug_entry) armv7a->post_debug_entry(target); return retval; } static void cortex_a8_post_debug_entry(struct target *target) { struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); struct armv7a_common *armv7a = &cortex_a8->armv7a_common; // cortex_a8_read_cp(target, &cp15_control_register, 15, 0, 1, 0, 0); /* examine cp15 control reg */ armv7a->read_cp15(target, 0, 0, 1, 0, &cortex_a8->cp15_control_reg); jtag_execute_queue(); LOG_DEBUG("cp15_control_reg: %8.8" PRIx32, cortex_a8->cp15_control_reg); if (armv7a->armv4_5_mmu.armv4_5_cache.ctype == -1) { uint32_t cache_type_reg; /* identify caches */ armv7a->read_cp15(target, 0, 1, 0, 0, &cache_type_reg); jtag_execute_queue(); /* FIXME the armv4_4 cache info DOES NOT APPLY to Cortex-A8 */ armv4_5_identify_cache(cache_type_reg, &armv7a->armv4_5_mmu.armv4_5_cache); } armv7a->armv4_5_mmu.mmu_enabled = (cortex_a8->cp15_control_reg & 0x1U) ? 1 : 0; armv7a->armv4_5_mmu.armv4_5_cache.d_u_cache_enabled = (cortex_a8->cp15_control_reg & 0x4U) ? 1 : 0; armv7a->armv4_5_mmu.armv4_5_cache.i_cache_enabled = (cortex_a8->cp15_control_reg & 0x1000U) ? 1 : 0; } static int cortex_a8_step(struct target *target, int current, uint32_t address, int handle_breakpoints) { struct armv7a_common *armv7a = target_to_armv7a(target); struct arm *armv4_5 = &armv7a->armv4_5_common; struct breakpoint *breakpoint = NULL; struct breakpoint stepbreakpoint; struct reg *r; int timeout = 100; if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } /* current = 1: continue on current pc, otherwise continue at */ r = armv4_5->core_cache->reg_list + 15; if (!current) { buf_set_u32(r->value, 0, 32, address); } else { address = buf_get_u32(r->value, 0, 32); } /* The front-end may request us not to handle breakpoints. * But since Cortex-A8 uses breakpoint for single step, * we MUST handle breakpoints. */ handle_breakpoints = 1; if (handle_breakpoints) { breakpoint = breakpoint_find(target, address); if (breakpoint) cortex_a8_unset_breakpoint(target, breakpoint); } /* Setup single step breakpoint */ stepbreakpoint.address = address; stepbreakpoint.length = (armv4_5->core_state == ARMV4_5_STATE_THUMB) ? 2 : 4; stepbreakpoint.type = BKPT_HARD; stepbreakpoint.set = 0; /* Break on IVA mismatch */ cortex_a8_set_breakpoint(target, &stepbreakpoint, 0x04); target->debug_reason = DBG_REASON_SINGLESTEP; cortex_a8_resume(target, 1, address, 0, 0); while (target->state != TARGET_HALTED) { cortex_a8_poll(target); if (--timeout == 0) { LOG_WARNING("timeout waiting for target halt"); break; } } cortex_a8_unset_breakpoint(target, &stepbreakpoint); if (timeout > 0) target->debug_reason = DBG_REASON_BREAKPOINT; if (breakpoint) cortex_a8_set_breakpoint(target, breakpoint, 0); if (target->state != TARGET_HALTED) LOG_DEBUG("target stepped"); return ERROR_OK; } static int cortex_a8_restore_context(struct target *target) { struct armv7a_common *armv7a = target_to_armv7a(target); LOG_DEBUG(" "); if (armv7a->pre_restore_context) armv7a->pre_restore_context(target); arm_dpm_write_dirty_registers(&armv7a->dpm); if (armv7a->post_restore_context) armv7a->post_restore_context(target); return ERROR_OK; } /* * Cortex-A8 Breakpoint and watchpoint fuctions */ /* Setup hardware Breakpoint Register Pair */ static int cortex_a8_set_breakpoint(struct target *target, struct breakpoint *breakpoint, uint8_t matchmode) { int retval; int brp_i=0; uint32_t control; uint8_t byte_addr_select = 0x0F; struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); struct armv7a_common *armv7a = &cortex_a8->armv7a_common; struct cortex_a8_brp * brp_list = cortex_a8->brp_list; if (breakpoint->set) { LOG_WARNING("breakpoint already set"); return ERROR_OK; } if (breakpoint->type == BKPT_HARD) { while (brp_list[brp_i].used && (brp_i < cortex_a8->brp_num)) brp_i++ ; if (brp_i >= cortex_a8->brp_num) { LOG_ERROR("ERROR Can not find free Breakpoint Register Pair"); return ERROR_FAIL; } breakpoint->set = brp_i + 1; if (breakpoint->length == 2) { byte_addr_select = (3 << (breakpoint->address & 0x02)); } control = ((matchmode & 0x7) << 20) | (byte_addr_select << 5) | (3 << 1) | 1; brp_list[brp_i].used = 1; brp_list[brp_i].value = (breakpoint->address & 0xFFFFFFFC); brp_list[brp_i].control = control; cortex_a8_dap_write_memap_register_u32(target, armv7a->debug_base + CPUDBG_BVR_BASE + 4 * brp_list[brp_i].BRPn, brp_list[brp_i].value); cortex_a8_dap_write_memap_register_u32(target, armv7a->debug_base + CPUDBG_BCR_BASE + 4 * brp_list[brp_i].BRPn, brp_list[brp_i].control); LOG_DEBUG("brp %i control 0x%0" PRIx32 " value 0x%0" PRIx32, brp_i, brp_list[brp_i].control, brp_list[brp_i].value); } else if (breakpoint->type == BKPT_SOFT) { uint8_t code[4]; if (breakpoint->length == 2) { buf_set_u32(code, 0, 32, ARMV5_T_BKPT(0x11)); } else { buf_set_u32(code, 0, 32, ARMV5_BKPT(0x11)); } retval = target->type->read_memory(target, breakpoint->address & 0xFFFFFFFE, breakpoint->length, 1, breakpoint->orig_instr); if (retval != ERROR_OK) return retval; retval = target->type->write_memory(target, breakpoint->address & 0xFFFFFFFE, breakpoint->length, 1, code); if (retval != ERROR_OK) return retval; breakpoint->set = 0x11; /* Any nice value but 0 */ } return ERROR_OK; } static int cortex_a8_unset_breakpoint(struct target *target, struct breakpoint *breakpoint) { int retval; struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); struct armv7a_common *armv7a = &cortex_a8->armv7a_common; struct cortex_a8_brp * brp_list = cortex_a8->brp_list; if (!breakpoint->set) { LOG_WARNING("breakpoint not set"); return ERROR_OK; } if (breakpoint->type == BKPT_HARD) { int brp_i = breakpoint->set - 1; if ((brp_i < 0) || (brp_i >= cortex_a8->brp_num)) { LOG_DEBUG("Invalid BRP number in breakpoint"); return ERROR_OK; } LOG_DEBUG("rbp %i control 0x%0" PRIx32 " value 0x%0" PRIx32, brp_i, brp_list[brp_i].control, brp_list[brp_i].value); brp_list[brp_i].used = 0; brp_list[brp_i].value = 0; brp_list[brp_i].control = 0; cortex_a8_dap_write_memap_register_u32(target, armv7a->debug_base + CPUDBG_BCR_BASE + 4 * brp_list[brp_i].BRPn, brp_list[brp_i].control); cortex_a8_dap_write_memap_register_u32(target, armv7a->debug_base + CPUDBG_BVR_BASE + 4 * brp_list[brp_i].BRPn, brp_list[brp_i].value); } else { /* restore original instruction (kept in target endianness) */ if (breakpoint->length == 4) { retval = target->type->write_memory(target, breakpoint->address & 0xFFFFFFFE, 4, 1, breakpoint->orig_instr); if (retval != ERROR_OK) return retval; } else { retval = target->type->write_memory(target, breakpoint->address & 0xFFFFFFFE, 2, 1, breakpoint->orig_instr); if (retval != ERROR_OK) return retval; } } breakpoint->set = 0; return ERROR_OK; } static int cortex_a8_add_breakpoint(struct target *target, struct breakpoint *breakpoint) { struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); if ((breakpoint->type == BKPT_HARD) && (cortex_a8->brp_num_available < 1)) { LOG_INFO("no hardware breakpoint available"); return ERROR_TARGET_RESOURCE_NOT_AVAILABLE; } if (breakpoint->type == BKPT_HARD) cortex_a8->brp_num_available--; cortex_a8_set_breakpoint(target, breakpoint, 0x00); /* Exact match */ return ERROR_OK; } static int cortex_a8_remove_breakpoint(struct target *target, struct breakpoint *breakpoint) { struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); #if 0 /* It is perfectly possible to remove brakpoints while the taget is running */ if (target->state != TARGET_HALTED) { LOG_WARNING("target not halted"); return ERROR_TARGET_NOT_HALTED; } #endif if (breakpoint->set) { cortex_a8_unset_breakpoint(target, breakpoint); if (breakpoint->type == BKPT_HARD) cortex_a8->brp_num_available++ ; } return ERROR_OK; } /* * Cortex-A8 Reset fuctions */ static int cortex_a8_assert_reset(struct target *target) { struct armv7a_common *armv7a = target_to_armv7a(target); LOG_DEBUG(" "); /* registers are now invalid */ register_cache_invalidate(armv7a->armv4_5_common.core_cache); target->state = TARGET_RESET; return ERROR_OK; } static int cortex_a8_deassert_reset(struct target *target) { LOG_DEBUG(" "); if (target->reset_halt) { int retval; if ((retval = target_halt(target)) != ERROR_OK) return retval; } return ERROR_OK; } /* * Cortex-A8 Memory access * * This is same Cortex M3 but we must also use the correct * ap number for every access. */ static int cortex_a8_read_memory(struct target *target, uint32_t address, uint32_t size, uint32_t count, uint8_t *buffer) { struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; int retval = ERROR_INVALID_ARGUMENTS; /* cortex_a8 handles unaligned memory access */ // ??? dap_ap_select(swjdp, swjdp_memoryap); if (count && buffer) { switch (size) { case 4: retval = mem_ap_read_buf_u32(swjdp, buffer, 4 * count, address); break; case 2: retval = mem_ap_read_buf_u16(swjdp, buffer, 2 * count, address); break; case 1: retval = mem_ap_read_buf_u8(swjdp, buffer, count, address); break; } } return retval; } static int cortex_a8_write_memory(struct target *target, uint32_t address, uint32_t size, uint32_t count, uint8_t *buffer) { struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; int retval = ERROR_INVALID_ARGUMENTS; // ??? dap_ap_select(swjdp, swjdp_memoryap); if (count && buffer) { switch (size) { case 4: retval = mem_ap_write_buf_u32(swjdp, buffer, 4 * count, address); break; case 2: retval = mem_ap_write_buf_u16(swjdp, buffer, 2 * count, address); break; case 1: retval = mem_ap_write_buf_u8(swjdp, buffer, count, address); break; } } if (retval == ERROR_OK && target->state == TARGET_HALTED) { /* The Cache handling will NOT work with MMU active, the wrong addresses will be invalidated */ /* invalidate I-Cache */ if (armv7a->armv4_5_mmu.armv4_5_cache.i_cache_enabled) { /* Invalidate ICache single entry with MVA, repeat this for all cache lines in the address range, Cortex-A8 has fixed 64 byte line length */ /* Invalidate Cache single entry with MVA to PoU */ for (uint32_t cacheline=address; cachelinewrite_cp15(target, 0, 1, 7, 5, cacheline); /* I-Cache to PoU */ } /* invalidate D-Cache */ if (armv7a->armv4_5_mmu.armv4_5_cache.d_u_cache_enabled) { /* Invalidate Cache single entry with MVA to PoC */ for (uint32_t cacheline=address; cachelinewrite_cp15(target, 0, 1, 7, 6, cacheline); /* U/D cache to PoC */ } } return retval; } static int cortex_a8_bulk_write_memory(struct target *target, uint32_t address, uint32_t count, uint8_t *buffer) { return cortex_a8_write_memory(target, address, 4, count, buffer); } static int cortex_a8_dcc_read(struct swjdp_common *swjdp, uint8_t *value, uint8_t *ctrl) { #if 0 u16 dcrdr; mem_ap_read_buf_u16(swjdp, (uint8_t*)&dcrdr, 1, DCB_DCRDR); *ctrl = (uint8_t)dcrdr; *value = (uint8_t)(dcrdr >> 8); LOG_DEBUG("data 0x%x ctrl 0x%x", *value, *ctrl); /* write ack back to software dcc register * signify we have read data */ if (dcrdr & (1 << 0)) { dcrdr = 0; mem_ap_write_buf_u16(swjdp, (uint8_t*)&dcrdr, 1, DCB_DCRDR); } #endif return ERROR_OK; } static int cortex_a8_handle_target_request(void *priv) { struct target *target = priv; struct armv7a_common *armv7a = target_to_armv7a(target); struct swjdp_common *swjdp = &armv7a->swjdp_info; if (!target_was_examined(target)) return ERROR_OK; if (!target->dbg_msg_enabled) return ERROR_OK; if (target->state == TARGET_RUNNING) { uint8_t data = 0; uint8_t ctrl = 0; cortex_a8_dcc_read(swjdp, &data, &ctrl); /* check if we have data */ if (ctrl & (1 << 0)) { uint32_t request; /* we assume target is quick enough */ request = data; cortex_a8_dcc_read(swjdp, &data, &ctrl); request |= (data << 8); cortex_a8_dcc_read(swjdp, &data, &ctrl); request |= (data << 16); cortex_a8_dcc_read(swjdp, &data, &ctrl); request |= (data << 24); target_request(target, request); } } return ERROR_OK; } /* * Cortex-A8 target information and configuration */ static int cortex_a8_examine_first(struct target *target) { struct cortex_a8_common *cortex_a8 = target_to_cortex_a8(target); struct armv7a_common *armv7a = &cortex_a8->armv7a_common; struct swjdp_common *swjdp = &armv7a->swjdp_info; int i; int retval = ERROR_OK; uint32_t didr, ctypr, ttypr, cpuid; LOG_DEBUG("TODO"); /* Here we shall insert a proper ROM Table scan */ armv7a->debug_base = OMAP3530_DEBUG_BASE; /* We do one extra read to ensure DAP is configured, * we call ahbap_debugport_init(swjdp) instead */ ahbap_debugport_init(swjdp); mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_CPUID, &cpuid); if ((retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_CPUID, &cpuid)) != ERROR_OK) { LOG_DEBUG("Examine failed"); return retval; } if ((retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_CTYPR, &ctypr)) != ERROR_OK) { LOG_DEBUG("Examine failed"); return retval; } if ((retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_TTYPR, &ttypr)) != ERROR_OK) { LOG_DEBUG("Examine failed"); return retval; } if ((retval = mem_ap_read_atomic_u32(swjdp, armv7a->debug_base + CPUDBG_DIDR, &didr)) != ERROR_OK) { LOG_DEBUG("Examine failed"); return retval; } LOG_DEBUG("cpuid = 0x%08" PRIx32, cpuid); LOG_DEBUG("ctypr = 0x%08" PRIx32, ctypr); LOG_DEBUG("ttypr = 0x%08" PRIx32, ttypr); LOG_DEBUG("didr = 0x%08" PRIx32, didr); cortex_a8_dpm_setup(cortex_a8, didr); /* Setup Breakpoint Register Pairs */ cortex_a8->brp_num = ((didr >> 24) & 0x0F) + 1; cortex_a8->brp_num_context = ((didr >> 20) & 0x0F) + 1; cortex_a8->brp_num_available = cortex_a8->brp_num; cortex_a8->brp_list = calloc(cortex_a8->brp_num, sizeof(struct cortex_a8_brp)); // cortex_a8->brb_enabled = ????; for (i = 0; i < cortex_a8->brp_num; i++) { cortex_a8->brp_list[i].used = 0; if (i < (cortex_a8->brp_num-cortex_a8->brp_num_context)) cortex_a8->brp_list[i].type = BRP_NORMAL; else cortex_a8->brp_list[i].type = BRP_CONTEXT; cortex_a8->brp_list[i].value = 0; cortex_a8->brp_list[i].control = 0; cortex_a8->brp_list[i].BRPn = i; } /* Setup Watchpoint Register Pairs */ cortex_a8->wrp_num = ((didr >> 28) & 0x0F) + 1; cortex_a8->wrp_num_available = cortex_a8->wrp_num; cortex_a8->wrp_list = calloc(cortex_a8->wrp_num, sizeof(struct cortex_a8_wrp)); for (i = 0; i < cortex_a8->wrp_num; i++) { cortex_a8->wrp_list[i].used = 0; cortex_a8->wrp_list[i].type = 0; cortex_a8->wrp_list[i].value = 0; cortex_a8->wrp_list[i].control = 0; cortex_a8->wrp_list[i].WRPn = i; } LOG_DEBUG("Configured %i hw breakpoint pairs and %i hw watchpoint pairs", cortex_a8->brp_num , cortex_a8->wrp_num); target_set_examined(target); return ERROR_OK; } static int cortex_a8_examine(struct target *target) { int retval = ERROR_OK; /* don't re-probe hardware after each reset */ if (!target_was_examined(target)) retval = cortex_a8_examine_first(target); /* Configure core debug access */ if (retval == ERROR_OK) retval = cortex_a8_init_debug_access(target); return retval; } /* * Cortex-A8 target creation and initialization */ static int cortex_a8_init_target(struct command_context *cmd_ctx, struct target *target) { /* examine_first() does a bunch of this */ return ERROR_OK; } static int cortex_a8_init_arch_info(struct target *target, struct cortex_a8_common *cortex_a8, struct jtag_tap *tap) { struct armv7a_common *armv7a = &cortex_a8->armv7a_common; struct arm *armv4_5 = &armv7a->armv4_5_common; struct swjdp_common *swjdp = &armv7a->swjdp_info; /* Setup struct cortex_a8_common */ cortex_a8->common_magic = CORTEX_A8_COMMON_MAGIC; armv4_5->arch_info = armv7a; /* prepare JTAG information for the new target */ cortex_a8->jtag_info.tap = tap; cortex_a8->jtag_info.scann_size = 4; swjdp->dp_select_value = -1; swjdp->ap_csw_value = -1; swjdp->ap_tar_value = -1; swjdp->jtag_info = &cortex_a8->jtag_info; swjdp->memaccess_tck = 80; /* Number of bits for tar autoincrement, impl. dep. at least 10 */ swjdp->tar_autoincr_block = (1 << 10); cortex_a8->fast_reg_read = 0; /* register arch-specific functions */ armv7a->examine_debug_reason = NULL; armv7a->post_debug_entry = cortex_a8_post_debug_entry; armv7a->pre_restore_context = NULL; armv7a->post_restore_context = NULL; armv7a->armv4_5_mmu.armv4_5_cache.ctype = -1; // armv7a->armv4_5_mmu.get_ttb = armv7a_get_ttb; armv7a->armv4_5_mmu.read_memory = cortex_a8_read_memory; armv7a->armv4_5_mmu.write_memory = cortex_a8_write_memory; // armv7a->armv4_5_mmu.disable_mmu_caches = armv7a_disable_mmu_caches; // armv7a->armv4_5_mmu.enable_mmu_caches = armv7a_enable_mmu_caches; armv7a->armv4_5_mmu.has_tiny_pages = 1; armv7a->armv4_5_mmu.mmu_enabled = 0; armv7a->read_cp15 = cortex_a8_read_cp15; armv7a->write_cp15 = cortex_a8_write_cp15; // arm7_9->handle_target_request = cortex_a8_handle_target_request; /* REVISIT v7a setup should be in a v7a-specific routine */ armv4_5_init_arch_info(target, armv4_5); armv7a->common_magic = ARMV7_COMMON_MAGIC; target_register_timer_callback(cortex_a8_handle_target_request, 1, 1, target); return ERROR_OK; } static int cortex_a8_target_create(struct target *target, Jim_Interp *interp) { struct cortex_a8_common *cortex_a8 = calloc(1, sizeof(struct cortex_a8_common)); cortex_a8_init_arch_info(target, cortex_a8, target->tap); return ERROR_OK; } COMMAND_HANDLER(cortex_a8_handle_cache_info_command) { struct target *target = get_current_target(CMD_CTX); struct armv7a_common *armv7a = target_to_armv7a(target); return armv4_5_handle_cache_info_command(CMD_CTX, &armv7a->armv4_5_mmu.armv4_5_cache); } COMMAND_HANDLER(cortex_a8_handle_dbginit_command) { struct target *target = get_current_target(CMD_CTX); cortex_a8_init_debug_access(target); return ERROR_OK; } static int cortex_a8_register_commands(struct command_context *cmd_ctx) { struct command *cortex_a8_cmd; int retval = ERROR_OK; armv4_5_register_commands(cmd_ctx); armv7a_register_commands(cmd_ctx); cortex_a8_cmd = COMMAND_REGISTER(cmd_ctx, NULL, "cortex_a8", NULL, COMMAND_ANY, "cortex_a8 specific commands"); COMMAND_REGISTER(cmd_ctx, cortex_a8_cmd, "cache_info", cortex_a8_handle_cache_info_command, COMMAND_EXEC, "display information about target caches"); COMMAND_REGISTER(cmd_ctx, cortex_a8_cmd, "dbginit", cortex_a8_handle_dbginit_command, COMMAND_EXEC, "Initialize core debug"); return retval; } struct target_type cortexa8_target = { .name = "cortex_a8", .poll = cortex_a8_poll, .arch_state = armv7a_arch_state, .target_request_data = NULL, .halt = cortex_a8_halt, .resume = cortex_a8_resume, .step = cortex_a8_step, .assert_reset = cortex_a8_assert_reset, .deassert_reset = cortex_a8_deassert_reset, .soft_reset_halt = NULL, .get_gdb_reg_list = armv4_5_get_gdb_reg_list, .read_memory = cortex_a8_read_memory, .write_memory = cortex_a8_write_memory, .bulk_write_memory = cortex_a8_bulk_write_memory, .checksum_memory = arm_checksum_memory, .blank_check_memory = arm_blank_check_memory, .run_algorithm = armv4_5_run_algorithm, .add_breakpoint = cortex_a8_add_breakpoint, .remove_breakpoint = cortex_a8_remove_breakpoint, .add_watchpoint = NULL, .remove_watchpoint = NULL, .register_commands = cortex_a8_register_commands, .target_create = cortex_a8_target_create, .init_target = cortex_a8_init_target, .examine = cortex_a8_examine, .mrc = cortex_a8_mrc, .mcr = cortex_a8_mcr, };