From d343941386bfa274cd64f8f384fc51a695f9f626 Mon Sep 17 00:00:00 2001 From: "Rodrigo L. Rosa" Date: Fri, 10 Jun 2011 12:24:27 -0700 Subject: [PATCH] doxy & cleanup --- src/flash/nor/dsp5680xx_flash.c | 92 ++-- src/target/dsp5680xx.c | 768 +++++++++++++++++++------------- src/target/dsp5680xx.h | 79 +++- 3 files changed, 593 insertions(+), 346 deletions(-) diff --git a/src/flash/nor/dsp5680xx_flash.c b/src/flash/nor/dsp5680xx_flash.c index b919f564..4ed72066 100644 --- a/src/flash/nor/dsp5680xx_flash.c +++ b/src/flash/nor/dsp5680xx_flash.c @@ -23,6 +23,19 @@ * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. * ***************************************************************************/ +/** + * @file dsp5680xx_flash.c + * @author Rodrigo L. Rosa + * @date Thu Jun 9 18:21:58 2011 + * + * @brief This file implements the basic functions to run flashing commands + * from the TCL interface. + * It allows the user to flash the Freescale 5680xx DSP. + * + * + */ + + #ifdef HAVE_CONFIG_H #include "config.h" #endif @@ -71,6 +84,15 @@ FLASH_BANK_COMMAND_HANDLER(dsp5680xx_flash_bank_command){ return ERROR_OK; } +/** + * A memory mapped register (PROT) holds information regarding sector protection. + * Protection refers to undesired core access. + * The value in this register is loaded from flash upon reset. + * + * @param bank + * + * @return + */ static int dsp5680xx_flash_protect_check(struct flash_bank *bank){ int retval = ERROR_OK; uint16_t protected = 0; @@ -93,6 +115,18 @@ static int dsp5680xx_flash_protect_check(struct flash_bank *bank){ return retval; } +/** + * Protection funcionality is not implemented. + * The current implementation applies/removes security on the chip. + * The chip is effectively secured/unsecured after the first reset following the execution of this function. + * + * @param bank + * @param set Apply or remove security on the chip. + * @param first This parameter is ignored. + * @param last This parameter is ignored. + * + * @return + */ static int dsp5680xx_flash_protect(struct flash_bank *bank, int set, int first, int last){ // This applies security to flash module after next reset, it does not actually apply protection (protection refers to undesired access from the core) int retval; @@ -103,24 +137,16 @@ static int dsp5680xx_flash_protect(struct flash_bank *bank, int set, int first, return retval; } -/* -static int dsp5680xx_write_block(struct flash_bank *bank, uint8_t *buffer, uint32_t offset, uint32_t count){ - LOG_USER("%s not implemented",__FUNCTION__); - return ERROR_OK; -} - -static int dsp5680xx_write_single(struct flash_bank *bank, uint8_t *buffer, uint32_t offset, uint32_t count){ - LOG_USER("%s not implemented",__FUNCTION__); - return ERROR_OK; -} -*/ - -//-- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -//-- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -// Flash stuff test -//-- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -//-- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- - +/** + * The dsp5680xx use word addressing. The "/2" that appear in the following code are a workaround for the fact that OpenOCD uses byte addressing. + * + * @param bank + * @param buffer Data to write to flash. + * @param offset + * @param count In bytes (2 bytes per address). + * + * @return + */ static int dsp5680xx_flash_write(struct flash_bank *bank, uint8_t *buffer, uint32_t offset, uint32_t count){ int retval; if((offset + count/2)>bank->size){ @@ -151,19 +177,17 @@ static int dsp5680xx_flash_info(struct flash_bank *bank, char *buf, int buf_size snprintf(buf, buf_size, "\ndsp5680xx flash driver info:\n - Currently only full erase/lock/unlock are implemented. \n - Call with bank==0 and sector 0 to 0.\n - Protect requires arp_init-reset to complete. \n - Before removing protection the master tap must be selected, and arp_init-reset is required to complete unlocking."); return ERROR_OK; } -/* -static int dsp5680xx_set_write_enable(struct target *target, int enable){ - LOG_USER("%s not implemented",__FUNCTION__); - return ERROR_OK; -} - - -static int dsp5680xx_check_flash_completion(struct target* target, unsigned int timeout_ms){ - LOG_USER("%s not implemented",__FUNCTION__); - return ERROR_OK; -} -*/ +/** + * The flash module (FM) on the dsp5680xx supports both individual sector and mass erase of the flash memory. + * If this function is called with @first == @last == 0 or if @first is the first sector (#0) and @last is the last sector then the mass erase command is executed (much faster than erasing each sector individually). + * + * @param bank + * @param first + * @param last + * + * @return + */ static int dsp5680xx_flash_erase(struct flash_bank * bank, int first, int last){ int retval; retval = dsp5680xx_f_erase(bank->target, (uint32_t) first, (uint32_t) last); @@ -177,6 +201,14 @@ static int dsp5680xx_flash_erase(struct flash_bank * bank, int first, int last){ return retval; } +/** + * The flash module (FM) on the dsp5680xx support a blank check function. + * This function executes the FM's blank check functionality on each and every sector. + * + * @param bank + * + * @return + */ static int dsp5680xx_flash_erase_check(struct flash_bank * bank){ int retval = ERROR_OK; uint8_t erased = 0; diff --git a/src/target/dsp5680xx.c b/src/target/dsp5680xx.c index f3f25a17..9afda424 100644 --- a/src/target/dsp5680xx.c +++ b/src/target/dsp5680xx.c @@ -31,18 +31,6 @@ #define err_check(retval,err_msg) if(retval != ERROR_OK){LOG_ERROR("%s: %d %s.",__FUNCTION__,__LINE__,err_msg);return retval;} #define err_check_propagate(retval) if(retval!=ERROR_OK){return retval;} -// Forward declarations, could try to optimize this. -static int eonce_instruction_exec(struct target * target, uint8_t instr, uint8_t rw, uint8_t go, uint8_t ex, uint8_t * eonce_status); -static int eonce_load_TX_RX_to_r0(struct target * target); -static int eonce_enter_debug_mode(struct target * target, uint16_t * eonce_status); -static int eonce_read_status_reg(struct target * target, uint16_t * data); -static int eonce_pc_store(struct target * target); -static int eonce_move_value_to_pc(struct target * target, uint32_t value); -static int dsp5680xx_jtag_status(struct target *target, uint8_t * status); -static int dsp5680xx_resume(struct target *target, int current, uint32_t address,int handle_breakpoints, int debug_execution); -static int dsp5680xx_halt(struct target *target); -static int dsp5680xx_write(struct target *target, uint32_t address, uint32_t size, uint32_t count, const uint8_t * buffer); - int dsp5680xx_execute_queue(void){ int retval; retval = jtag_execute_queue(); @@ -50,14 +38,6 @@ int dsp5680xx_execute_queue(void){ return retval; } -static int eonce_exit_debug_mode(struct target * target,uint8_t * eonce_status){ - int retval; - retval = eonce_instruction_exec(target,0x1F,0,0,1,eonce_status); - err_check_propagate(retval); - return retval; -} - - static int dsp5680xx_drscan(struct target * target, uint8_t * data_to_shift_into_dr, uint8_t * data_shifted_out_of_dr, int len){ // -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- // @@ -115,116 +95,12 @@ static int dsp5680xx_irscan(struct target * target, uint32_t * data_to_shift_int //is the casting necessary? jtag_add_plain_ir_scan(ir_len,(uint8_t *)data_to_shift_into_ir,(uint8_t *)data_shifted_out_of_ir, TAP_IDLE); if(context.flush){ - retval = dsp5680xx_execute_queue(); - err_check_propagate(retval); + retval = dsp5680xx_execute_queue(); + err_check_propagate(retval); } return retval; } -static int dsp5680xx_read_core_reg(struct target * target, uint8_t reg_addr, uint16_t * data_read) -{ - //TODO implement a general version of this which matches what openocd uses. - int retval; - uint32_t dummy_data_to_shift_into_dr; - retval = eonce_instruction_exec(target,reg_addr,1,0,0,NULL); - err_check_propagate(retval); - retval = dsp5680xx_drscan(target,(uint8_t *)& dummy_data_to_shift_into_dr,(uint8_t *) data_read, 8); - err_check_propagate(retval); - LOG_DEBUG("Reg. data: 0x%02X.",*data_read); - return retval; -} - -static int dsp5680xx_target_create(struct target *target, Jim_Interp * interp){ - struct dsp5680xx_common *dsp5680xx = calloc(1, sizeof(struct dsp5680xx_common)); - target->arch_info = dsp5680xx; - return ERROR_OK; -} - -static int dsp5680xx_init_target(struct command_context *cmd_ctx, struct target *target){ - context.stored_pc = 0; - context.flush = 1; - LOG_DEBUG("target initiated!"); - //TODO core tap must be enabled before running these commands, currently this is done in the .cfg tcl script. - return ERROR_OK; -} - -static int dsp5680xx_arch_state(struct target *target){ - LOG_USER("%s not implemented yet.",__FUNCTION__); - return ERROR_OK; -} - -int dsp5680xx_target_status(struct target * target, uint8_t * jtag_st, uint16_t * eonce_st){ - return target->state; -} - -static int dsp5680xx_assert_reset(struct target *target){ - target->state = TARGET_RESET; - return ERROR_OK; -} - -static int dsp5680xx_deassert_reset(struct target *target){ - target->state = TARGET_RUNNING; - return ERROR_OK; -} - -static int dsp5680xx_poll(struct target *target){ - int retval; - uint8_t jtag_status; - uint8_t eonce_status; - uint16_t read_tmp; - retval = dsp5680xx_jtag_status(target,&jtag_status); - err_check_propagate(retval); - if (jtag_status == JTAG_STATUS_DEBUG) - if (target->state != TARGET_HALTED){ - retval = eonce_enter_debug_mode(target,&read_tmp); - err_check_propagate(retval); - eonce_status = (uint8_t) read_tmp; - if((eonce_status&EONCE_STAT_MASK) != DSP5680XX_ONCE_OSCR_DEBUG_M){ - LOG_WARNING("%s: Failed to put EOnCE in debug mode. Is flash locked?...",__FUNCTION__); - return ERROR_TARGET_FAILURE; - }else{ - target->state = TARGET_HALTED; - return ERROR_OK; - } - } - if (jtag_status == JTAG_STATUS_NORMAL){ - if(target->state == TARGET_RESET){ - retval = dsp5680xx_halt(target); - err_check_propagate(retval); - retval = eonce_exit_debug_mode(target,&eonce_status); - err_check_propagate(retval); - if((eonce_status&EONCE_STAT_MASK) != DSP5680XX_ONCE_OSCR_NORMAL_M){ - LOG_WARNING("%s: JTAG running, but cannot make EOnCE run. Try resetting...",__FUNCTION__); - return ERROR_TARGET_FAILURE; - }else{ - target->state = TARGET_RUNNING; - return ERROR_OK; - } - } - if(target->state != TARGET_RUNNING){ - retval = eonce_read_status_reg(target,&read_tmp); - err_check_propagate(retval); - eonce_status = (uint8_t) read_tmp; - if((eonce_status&EONCE_STAT_MASK) != DSP5680XX_ONCE_OSCR_NORMAL_M){ - LOG_WARNING("Inconsistent target status. Restart!"); - return ERROR_TARGET_FAILURE; - } - } - target->state = TARGET_RUNNING; - return ERROR_OK; - } - if(jtag_status == JTAG_STATUS_DEAD){ - LOG_ERROR("%s: Cannot communicate with JTAG. Check connection...",__FUNCTION__); - target->state = TARGET_UNKNOWN; - return ERROR_TARGET_FAILURE; - }; - if (target->state == TARGET_UNKNOWN){ - LOG_ERROR("%s: Target status invalid - communication failure",__FUNCTION__); - return ERROR_TARGET_FAILURE; - }; - return ERROR_OK; -} - static int dsp5680xx_jtag_status(struct target *target, uint8_t * status){ uint32_t read_from_ir; uint32_t instr; @@ -237,57 +113,6 @@ static int dsp5680xx_jtag_status(struct target *target, uint8_t * status){ return ERROR_OK; } -static int eonce_read_status_reg(struct target * target, uint16_t * data){ - int retval; - retval = dsp5680xx_read_core_reg(target,DSP5680XX_ONCE_OSR,data); - err_check_propagate(retval); - return retval; -} - -static int dsp5680xx_halt(struct target *target){ - int retval; - uint16_t eonce_status; - if(target->state == TARGET_HALTED){ - LOG_USER("Target already halted."); - return ERROR_OK; - } - retval = eonce_enter_debug_mode(target,&eonce_status); - err_check_propagate(retval); - retval = eonce_pc_store(target); - err_check_propagate(retval); - //TODO is it useful to store the pc? - return retval; -} - -static int dsp5680xx_resume(struct target *target, int current, uint32_t address,int handle_breakpoints, int debug_execution){ - if(target->state == TARGET_RUNNING){ - LOG_USER("Target already running."); - return ERROR_OK; - } - int retval; - uint8_t eonce_status; - if(!current){ - retval = eonce_move_value_to_pc(target,address); - err_check_propagate(retval); - } - - int retry = 20; - while(retry-- > 1){ - retval = eonce_exit_debug_mode(target,&eonce_status ); - err_check_propagate(retval); - if(eonce_status == DSP5680XX_ONCE_OSCR_NORMAL_M) - break; - } - if(retry == 0){ - retval = ERROR_TARGET_FAILURE; - err_check(retval,"Failed to resume..."); - }else{ - target->state = TARGET_RUNNING; - } - LOG_DEBUG("EOnCE status: 0x%02X.",eonce_status); - return ERROR_OK; -} - static int jtag_data_read(struct target * target, uint32_t * data_read, int num_bits){ uint32_t bogus_instr; int retval = dsp5680xx_drscan(target,(uint8_t *) & bogus_instr,(uint8_t *) data_read,num_bits); @@ -314,37 +139,18 @@ static int jtag_data_write(struct target * target, uint32_t instr,int num_bits, #define jtag_data_write24(target,instr,data_read) jtag_data_write(target,instr,24,data_read) #define jtag_data_write32(target,instr,data_read) jtag_data_write(target,instr,32,data_read) -static int eonce_enter_debug_mode(struct target * target, uint16_t * eonce_status){ - int retval; - uint32_t instr = JTAG_INSTR_DEBUG_REQUEST; - uint32_t ir_out;//not used, just to make jtag happy. - // Debug request #1 - retval = dsp5680xx_irscan(target,& instr,& ir_out,DSP5680XX_JTAG_CORE_TAP_IRLEN); - err_check_propagate(retval); - - // Enable EOnCE module - instr = JTAG_INSTR_ENABLE_ONCE; - //Two rounds of jtag 0x6 (enable eonce) to enable EOnCE. - retval = dsp5680xx_irscan(target, & instr, & ir_out,DSP5680XX_JTAG_CORE_TAP_IRLEN); - err_check_propagate(retval); - retval = dsp5680xx_irscan(target, & instr, & ir_out,DSP5680XX_JTAG_CORE_TAP_IRLEN); - err_check_propagate(retval); - // Verify that debug mode is enabled - uint16_t data_read_from_dr; - retval = eonce_read_status_reg(target,&data_read_from_dr); - err_check_propagate(retval); - if((data_read_from_dr&0x30) == 0x30){ - LOG_DEBUG("EOnCE successfully entered debug mode."); - target->state = TARGET_HALTED; - return ERROR_OK; - }else{ - retval = ERROR_TARGET_FAILURE; - err_check(retval,"Failed to set EOnCE module to debug mode."); - } - if(eonce_status!=NULL) - *eonce_status = data_read_from_dr; - return ERROR_OK; -} +/** + * Executes DSP instruction. + * + * @param target + * @param instr Instruction to execute. + * @param rw + * @param go + * @param ex + * @param eonce_status Value read from the EOnCE status register. + * + * @return + */ static int eonce_instruction_exec(struct target * target, uint8_t instr, uint8_t rw, uint8_t go, uint8_t ex,uint8_t * eonce_status){ int retval; @@ -357,15 +163,14 @@ static int eonce_instruction_exec(struct target * target, uint8_t instr, uint8_t return retval; } -/* Executes DSP instruction */ -/* wrappers for parameter conversion between eonce_execute_instruction and eonce_execute_instructionX */ +///wrappers for parameter conversion between eonce_execute_instruction and eonce_execute_instructionX + #define eonce_execute_instruction_1(target,opcode1,opcode2,opcode3) eonce_execute_instruction1(target,opcode1) #define eonce_execute_instruction_2(target,opcode1,opcode2,opcode3) eonce_execute_instruction2(target,opcode1,opcode2) #define eonce_execute_instruction_3(target,opcode1,opcode2,opcode3) eonce_execute_instruction3(target,opcode1,opcode2,opcode3) -/* the macro itself */ #define eonce_execute_instruction(target,words,opcode1,opcode2,opcode3) eonce_execute_instruction_##words(target,opcode1,opcode2,opcode3) -/* Executes one word DSP instruction */ +/// Executes one word DSP instruction static int eonce_execute_instruction1(struct target * target, uint16_t opcode){ int retval; retval = eonce_instruction_exec(target,0x04,0,1,0,NULL); @@ -375,7 +180,7 @@ static int eonce_execute_instruction1(struct target * target, uint16_t opcode){ return retval; } -/* Executes two word DSP instruction */ +/// Executes two word DSP instruction static int eonce_execute_instruction2(struct target * target,uint16_t opcode1, uint16_t opcode2){ int retval; retval = eonce_instruction_exec(target,0x04,0,0,0,NULL); @@ -389,7 +194,7 @@ static int eonce_execute_instruction2(struct target * target,uint16_t opcode1, u return retval; } -/* Executes three word DSP instruction */ +/// Executes three word DSP instruction static int eonce_execute_instruction3(struct target * target, uint16_t opcode1,uint16_t opcode2,uint16_t opcode3){ int retval; retval = eonce_instruction_exec(target,0x04,0,0,0,NULL); @@ -407,15 +212,16 @@ static int eonce_execute_instruction3(struct target * target, uint16_t opcode1,u return retval; } -/* --------------- Real-time data exchange --------------- */ -/* - The EOnCE Transmit (OTX) and Receive (ORX) registers are data memory mapped, each with an upper and lower 16 bit word. - Transmit and receive directions are defined from the core’s perspective. - The core writes to the Transmit register and reads the Receive register, and the host through JTAG writes to the Receive register and reads the Transmit register. - Both registers have a combined data memory mapped OTXRXSR which provides indication when each may be accessed. -ref: eonce_rev.1.0_0208081.pdf@36 +/** + * --------------- Real-time data exchange --------------- + * The EOnCE Transmit (OTX) and Receive (ORX) registers are data memory mapped, each with an upper and lower 16 bit word. + * Transmit and receive directions are defined from the core’s perspective. + * The core writes to the Transmit register and reads the Receive register, and the host through JTAG writes to the Receive register and reads the Transmit register. + * Both registers have a combined data memory mapped OTXRXSR which provides indication when each may be accessed. + *ref: eonce_rev.1.0_0208081.pdf@36 */ +/// writes data into upper ORx register of the target static int eonce_tx_upper_data(struct target * target, uint16_t data, uint32_t * eonce_status_low){ int retval; retval = eonce_instruction_exec(target,DSP5680XX_ONCE_ORX1,0,0,0,NULL); @@ -425,7 +231,7 @@ static int eonce_tx_upper_data(struct target * target, uint16_t data, uint32_t * return retval; } -/* writes data into lower ORx register of the target */ +/// writes data into lower ORx register of the target #define eonce_tx_lower_data(target,data) eonce_instruction_exec(target,DSP5680XX_ONCE_ORX,0,0,0,NULL);\ jtag_data_write16(target,data) @@ -461,119 +267,124 @@ static int eonce_rx_lower_data(struct target * target,uint16_t * data_read) return retval; } -/* -- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- -*/ -/* -- -- -- -- --- -- -- -Core Instructions- -- -- -- --- -- -- -- --- -- -*/ -/* -- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- -*/ -/* move.l #value,r0 */ +/** + * -- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- + * -- -- -- -- --- -- -- -Core Instructions- -- -- -- --- -- -- -- --- -- + * -- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- -- -- --- -- + */ + +/// move.l #value,r0 #define eonce_move_long_to_r0(target,value) eonce_execute_instruction(target,3,0xe418,value&0xffff,value>>16) -/* move.l #value,n */ +/// move.l #value,n #define eonce_move_long_to_n(target,value) eonce_execute_instruction(target,3,0xe41e,value&0xffff,value>>16) -/* move x:(r0),y0 */ +/// move x:(r0),y0 #define eonce_move_at_r0_to_y0(target) eonce_execute_instruction(target,1,0xF514,0,0) -/* move x:(r0),y1 */ +/// move x:(r0),y1 #define eonce_move_at_r0_to_y1(target) eonce_execute_instruction(target,1,0xF714,0,0) -/* move.l x:(r0),y */ +/// move.l x:(r0),y #define eonce_move_long_at_r0_y(target) eonce_execute_instruction(target,1,0xF734,0,0) -/* move y0,x:(r0) */ +/// move y0,x:(r0) #define eonce_move_y0_at_r0(target) eonce_execute_instruction(target,1,0xd514,0,0) -/* bfclr #value,x:(r0) */ +/// bfclr #value,x:(r0) #define eonce_bfclr_at_r0(target,value) eonce_execute_instruction(target,2,0x8040,value,0) -/* move #value,y0 */ +/// move #value,y0 #define eonce_move_value_to_y0(target,value) eonce_execute_instruction(target,2,0x8745,value,0) -/* move.w y0,x:(r0)+ */ +/// move.w y0,x:(r0)+ #define eonce_move_y0_at_r0_inc(target) eonce_execute_instruction(target,1,0xd500,0,0) -/* move.w y0,p:(r0)+ */ +/// move.w y0,p:(r0)+ #define eonce_move_y0_at_pr0_inc(target) eonce_execute_instruction(target,1,0x8560,0,0) -/* move.w p:(r0)+,y0 */ +/// move.w p:(r0)+,y0 #define eonce_move_at_pr0_inc_to_y0(target) eonce_execute_instruction(target,1,0x8568,0,0) -/* move.w p:(r0)+,y1 */ +/// move.w p:(r0)+,y1 #define eonce_move_at_pr0_inc_to_y1(target) eonce_execute_instruction(target,1,0x8768,0,0) -/* move.l #value,r2 */ +/// move.l #value,r2 #define eonce_move_long_to_r2(target,value) eonce_execute_instruction(target,3,0xe41A,value&0xffff,value>>16) -/* move y0,x:(r2) */ +/// move y0,x:(r2) #define eonce_move_y0_at_r2(target) eonce_execute_instruction(target,1,0xd516,0,0) -/* move.w #,x:(r2) */ +/// move.w #,x:(r2) #define eonce_move_value_at_r2(target,value) eonce_execute_instruction(target,2,0x8642,value,0) -/* move.w #,x:(r0) */ +/// move.w #,x:(r0) #define eonce_move_value_at_r0(target,value) eonce_execute_instruction(target,2,0x8640,value,0) -/* move.w #,x:(R2+) */ +/// move.w #,x:(R2+) #define eonce_move_value_at_r2_disp(target,value,disp) eonce_execute_instruction(target,3,0x8646,value,disp) -/* move.w x:(r2),Y0 */ +/// move.w x:(r2),Y0 #define eonce_move_at_r2_to_y0(target) eonce_execute_instruction(target,1,0xF516,0,0) -/* move.w p:(r2)+,y0 */ +/// move.w p:(r2)+,y0 #define eonce_move_at_pr2_inc_to_y0(target) eonce_execute_instruction(target,1,0x856A,0,0) -/* move.l #value,r3 */ +/// move.l #value,r3 #define eonce_move_long_to_r1(target,value) eonce_execute_instruction(target,3,0xE419,value&0xffff,value>>16) -/* move.l #value,r3 */ +/// move.l #value,r3 #define eonce_move_long_to_r3(target,value) eonce_execute_instruction(target,3,0xE41B,value&0xffff,value>>16) -/* move.w y0,p:(r3)+ */ +/// move.w y0,p:(r3)+ #define eonce_move_y0_at_pr3_inc(target) eonce_execute_instruction(target,1,0x8563,0,0) -/* move.w y0,x:(r3) */ +/// move.w y0,x:(r3) #define eonce_move_y0_at_r3(target) eonce_execute_instruction(target,1,0xD503,0,0) -/* move pc,r4 */ +/// move.l #value,r4 +#define eonce_move_long_to_r4(target,value) eonce_execute_instruction(target,3,0xE41C,value&0xffff,value>>16) + +/// move pc,r4 #define eonce_move_pc_to_r4(target) eonce_execute_instruction(target,1,0xE716,0,0) -/* move.l r4,y */ +/// move.l r4,y #define eonce_move_r4_to_y(target) eonce_execute_instruction(target,1,0xe764,0,0) -/* move.w p:(r0)+,y0 */ +/// move.w p:(r0)+,y0 #define eonce_move_at_pr0_inc_to_y0(target) eonce_execute_instruction(target,1,0x8568,0,0) -/* move.w x:(r0)+,y0 */ +/// move.w x:(r0)+,y0 #define eonce_move_at_r0_inc_to_y0(target) eonce_execute_instruction(target,1,0xf500,0,0) -/* move x:(r0),y0 */ +/// move x:(r0),y0 #define eonce_move_at_r0_y0(target) eonce_execute_instruction(target,1,0xF514,0,0) -/* nop */ +/// nop #define eonce_nop(target) eonce_execute_instruction(target,1,0xe700,0,0) -/* move.w x:(R2+),Y0 */ +/// move.w x:(R2+),Y0 #define eonce_move_at_r2_disp_to_y0(target,disp) eonce_execute_instruction(target,2,0xF542,disp,0) -/* move.w y1,x:(r2) */ +/// move.w y1,x:(r2) #define eonce_move_y1_at_r2(target) eonce_execute_instruction(target,1,0xd716,0,0) -/* move.w y1,x:(r0) */ +/// move.w y1,x:(r0) #define eonce_move_y1_at_r0(target) eonce_execute_instruction(target,1,0xd714,0,0) -/* move.bp y0,x:(r0)+ */ +/// move.bp y0,x:(r0)+ #define eonce_move_byte_y0_at_r0(target) eonce_execute_instruction(target,1,0xd5a0,0,0) -/* move.w y1,p:(r0)+ */ +/// move.w y1,p:(r0)+ #define eonce_move_y1_at_pr0_inc(target) eonce_execute_instruction(target,1,0x8760,0,0) -/* move.w y1,x:(r0)+ */ +/// move.w y1,x:(r0)+ #define eonce_move_y1_at_r0_inc(target) eonce_execute_instruction(target,1,0xD700,0,0) -/* move.l #value,y */ +/// move.l #value,y #define eonce_move_long_to_y(target,value) eonce_execute_instruction(target,3,0xe417,value&0xffff,value>>16) -static int eonce_move_value_to_pc(struct target * target, uint32_t value) -{ +static int eonce_move_value_to_pc(struct target * target, uint32_t value){ if (!(target->state == TARGET_HALTED)){ LOG_ERROR("Target must be halted to move PC. Target state = %d.",target->state); return ERROR_TARGET_NOT_HALTED; @@ -598,6 +409,88 @@ static int eonce_load_TX_RX_high_to_r0(struct target * target) return retval; } +static int dsp5680xx_read_core_reg(struct target * target, uint8_t reg_addr, uint16_t * data_read) +{ + //TODO implement a general version of this which matches what openocd uses. + int retval; + uint32_t dummy_data_to_shift_into_dr; + retval = eonce_instruction_exec(target,reg_addr,1,0,0,NULL); + err_check_propagate(retval); + retval = dsp5680xx_drscan(target,(uint8_t *)& dummy_data_to_shift_into_dr,(uint8_t *) data_read, 8); + err_check_propagate(retval); + LOG_DEBUG("Reg. data: 0x%02X.",*data_read); + return retval; +} + +static int eonce_read_status_reg(struct target * target, uint16_t * data){ + int retval; + retval = dsp5680xx_read_core_reg(target,DSP5680XX_ONCE_OSR,data); + err_check_propagate(retval); + return retval; +} + +/** + * Takes the core out of debug mode. + * + * @param target + * @param eonce_status Data read from the EOnCE status register. + * + * @return + */ +static int eonce_exit_debug_mode(struct target * target,uint8_t * eonce_status){ + int retval; + retval = eonce_instruction_exec(target,0x1F,0,0,1,eonce_status); + err_check_propagate(retval); + return retval; +} + +/** + * Puts the core into debug mode, enabling the EOnCE module. + * + * @param target + * @param eonce_status Data read from the EOnCE status register. + * + * @return + */ +static int eonce_enter_debug_mode(struct target * target, uint16_t * eonce_status){ + int retval; + uint32_t instr = JTAG_INSTR_DEBUG_REQUEST; + uint32_t ir_out;//not used, just to make jtag happy. + // Debug request #1 + retval = dsp5680xx_irscan(target,& instr,& ir_out,DSP5680XX_JTAG_CORE_TAP_IRLEN); + err_check_propagate(retval); + + // Enable EOnCE module + instr = JTAG_INSTR_ENABLE_ONCE; + //Two rounds of jtag 0x6 (enable eonce) to enable EOnCE. + retval = dsp5680xx_irscan(target, & instr, & ir_out,DSP5680XX_JTAG_CORE_TAP_IRLEN); + err_check_propagate(retval); + retval = dsp5680xx_irscan(target, & instr, & ir_out,DSP5680XX_JTAG_CORE_TAP_IRLEN); + err_check_propagate(retval); + // Verify that debug mode is enabled + uint16_t data_read_from_dr; + retval = eonce_read_status_reg(target,&data_read_from_dr); + err_check_propagate(retval); + if((data_read_from_dr&0x30) == 0x30){ + LOG_DEBUG("EOnCE successfully entered debug mode."); + target->state = TARGET_HALTED; + return ERROR_OK; + }else{ + retval = ERROR_TARGET_FAILURE; + err_check(retval,"Failed to set EOnCE module to debug mode."); + } + if(eonce_status!=NULL) + *eonce_status = data_read_from_dr; + return ERROR_OK; +} + +/** + * Reads the current value of the program counter and stores it. + * + * @param target + * + * @return + */ static int eonce_pc_store(struct target * target){ uint32_t tmp = 0; int retval; @@ -616,6 +509,155 @@ static int eonce_pc_store(struct target * target){ return ERROR_OK; } +static int dsp5680xx_target_create(struct target *target, Jim_Interp * interp){ + struct dsp5680xx_common *dsp5680xx = calloc(1, sizeof(struct dsp5680xx_common)); + target->arch_info = dsp5680xx; + return ERROR_OK; +} + +static int dsp5680xx_init_target(struct command_context *cmd_ctx, struct target *target){ + context.stored_pc = 0; + context.flush = 1; + LOG_DEBUG("target initiated!"); + //TODO core tap must be enabled before running these commands, currently this is done in the .cfg tcl script. + return ERROR_OK; +} + +static int dsp5680xx_arch_state(struct target *target){ + LOG_USER("%s not implemented yet.",__FUNCTION__); + return ERROR_OK; +} + +int dsp5680xx_target_status(struct target * target, uint8_t * jtag_st, uint16_t * eonce_st){ + return target->state; +} + +static int dsp5680xx_assert_reset(struct target *target){ + target->state = TARGET_RESET; + return ERROR_OK; +} + +static int dsp5680xx_deassert_reset(struct target *target){ + target->state = TARGET_RUNNING; + return ERROR_OK; +} + +static int dsp5680xx_halt(struct target *target){ + int retval; + uint16_t eonce_status; + if(target->state == TARGET_HALTED){ + LOG_USER("Target already halted."); + return ERROR_OK; + } + retval = eonce_enter_debug_mode(target,&eonce_status); + err_check_propagate(retval); + retval = eonce_pc_store(target); + err_check_propagate(retval); + //TODO is it useful to store the pc? + return retval; +} + +static int dsp5680xx_poll(struct target *target){ + int retval; + uint8_t jtag_status; + uint8_t eonce_status; + uint16_t read_tmp; + retval = dsp5680xx_jtag_status(target,&jtag_status); + err_check_propagate(retval); + if (jtag_status == JTAG_STATUS_DEBUG) + if (target->state != TARGET_HALTED){ + retval = eonce_enter_debug_mode(target,&read_tmp); + err_check_propagate(retval); + eonce_status = (uint8_t) read_tmp; + if((eonce_status&EONCE_STAT_MASK) != DSP5680XX_ONCE_OSCR_DEBUG_M){ + LOG_WARNING("%s: Failed to put EOnCE in debug mode. Is flash locked?...",__FUNCTION__); + return ERROR_TARGET_FAILURE; + }else{ + target->state = TARGET_HALTED; + return ERROR_OK; + } + } + if (jtag_status == JTAG_STATUS_NORMAL){ + if(target->state == TARGET_RESET){ + retval = dsp5680xx_halt(target); + err_check_propagate(retval); + retval = eonce_exit_debug_mode(target,&eonce_status); + err_check_propagate(retval); + if((eonce_status&EONCE_STAT_MASK) != DSP5680XX_ONCE_OSCR_NORMAL_M){ + LOG_WARNING("%s: JTAG running, but cannot make EOnCE run. Try resetting...",__FUNCTION__); + return ERROR_TARGET_FAILURE; + }else{ + target->state = TARGET_RUNNING; + return ERROR_OK; + } + } + if(target->state != TARGET_RUNNING){ + retval = eonce_read_status_reg(target,&read_tmp); + err_check_propagate(retval); + eonce_status = (uint8_t) read_tmp; + if((eonce_status&EONCE_STAT_MASK) != DSP5680XX_ONCE_OSCR_NORMAL_M){ + LOG_WARNING("Inconsistent target status. Restart!"); + return ERROR_TARGET_FAILURE; + } + } + target->state = TARGET_RUNNING; + return ERROR_OK; + } + if(jtag_status == JTAG_STATUS_DEAD){ + LOG_ERROR("%s: Cannot communicate with JTAG. Check connection...",__FUNCTION__); + target->state = TARGET_UNKNOWN; + return ERROR_TARGET_FAILURE; + }; + if (target->state == TARGET_UNKNOWN){ + LOG_ERROR("%s: Target status invalid - communication failure",__FUNCTION__); + return ERROR_TARGET_FAILURE; + }; + return ERROR_OK; +} + +static int dsp5680xx_resume(struct target *target, int current, uint32_t address,int handle_breakpoints, int debug_execution){ + if(target->state == TARGET_RUNNING){ + LOG_USER("Target already running."); + return ERROR_OK; + } + int retval; + uint8_t eonce_status; + if(!current){ + retval = eonce_move_value_to_pc(target,address); + err_check_propagate(retval); + } + + int retry = 20; + while(retry-- > 1){ + retval = eonce_exit_debug_mode(target,&eonce_status ); + err_check_propagate(retval); + if(eonce_status == DSP5680XX_ONCE_OSCR_NORMAL_M) + break; + } + if(retry == 0){ + retval = ERROR_TARGET_FAILURE; + err_check(retval,"Failed to resume..."); + }else{ + target->state = TARGET_RUNNING; + } + LOG_DEBUG("EOnCE status: 0x%02X.",eonce_status); + return ERROR_OK; +} + + + + + + +/** + * The value of @address determines if it corresponds to P: (program) or X: (data) memory. If the address is over 0x200000 then it is considered X: memory, and @pmem = 0. + * The special case of 0xFFXXXX is not modified, since it allows to read out the memory mapped EOnCE registers. + * + * @param address + * @param pmem + * + * @return + */ static int dsp5680xx_convert_address(uint32_t * address, int * pmem){ // Distinguish data memory (x:) from program memory (p:) by the address. // Addresses over S_FILE_DATA_OFFSET are considered (x:) memory. @@ -679,7 +721,7 @@ static int dsp5680xx_read_32_single(struct target * target, uint32_t address, ui uint16_t tmp; retval = eonce_rx_upper_data(target,&tmp); err_check_propagate(retval); - *data_read = ((tmp<<16) | (*data_read));//This enables opencd crc to succeed, even though it's very slow. + *data_read = ((tmp<<16) | (*data_read));//This enables OpenOCD crc to succeed (when it should) return retval; } @@ -734,7 +776,6 @@ static int dsp5680xx_read(struct target * target, uint32_t address, unsigned siz return retval; } -//TODO doxy static int dsp5680xx_write_16_single(struct target *target, uint32_t address, uint16_t data, uint8_t w_pmem){ int retval = 0; retval = eonce_move_long_to_r0(target,address); @@ -751,7 +792,6 @@ static int dsp5680xx_write_16_single(struct target *target, uint32_t address, ui return retval; } -//TODO doxy static int dsp5680xx_write_32_single(struct target *target, uint32_t address, uint32_t data, int w_pmem){ int retval = 0; retval = eonce_move_long_to_r0(target,address); @@ -864,7 +904,18 @@ static int dsp5680xx_write_32(struct target * target, uint32_t address, uint32_t return retval; } -//TODO doxy +/** + * Writes @buffer to memory. + * The parameter @address determines whether @buffer should be written to P: (program) memory or X: (data) memory. + * + * @param target + * @param address + * @param size Bytes (1), Half words (2), Words (4). + * @param count In bytes. + * @param buffer + * + * @return + */ static int dsp5680xx_write(struct target *target, uint32_t address, uint32_t size, uint32_t count, const uint8_t * buffer){ //TODO Cannot write 32bit to odd address, will write 0x12345678 as 0x5678 0x0012 if(target->state != TARGET_HALTED){ @@ -888,7 +939,7 @@ static int dsp5680xx_write(struct target *target, uint32_t address, uint32_t siz break; default: retval = ERROR_TARGET_DATA_ABORT; - err_check(retval,"Invalid data size.") + err_check(retval,"Invalid data size."); break; } return retval; @@ -907,21 +958,49 @@ static int dsp5680xx_write_buffer(struct target * target, uint32_t address, uint return dsp5680xx_write(target, address, 1, size, buffer); } +/** + * This function is called by verify_image, it is used to read data from memory. + * + * @param target + * @param address Word addressing. + * @param size In bytes. + * @param buffer + * + * @return + */ static int dsp5680xx_read_buffer(struct target * target, uint32_t address, uint32_t size, uint8_t * buffer){ if(target->state != TARGET_HALTED){ LOG_USER("Target must be halted."); return ERROR_OK; } - // read_buffer is called when the verify_image command is executed. // The "/2" solves the byte/word addressing issue. return dsp5680xx_read(target,address,2,size/2,buffer); } +/** + * This function is not implemented. + * It returns an error in order to get OpenOCD to do read out the data and calculate the CRC, or try a binary comparison. + * + * @param target + * @param address Start address of the image. + * @param size In bytes. + * @param checksum + * + * @return + */ static int dsp5680xx_checksum_memory(struct target * target, uint32_t address, uint32_t size, uint32_t * checksum){ - return ERROR_FAIL;// This will make OpenOCD do the read out the data and verify it. + return ERROR_FAIL; } -// Data signature algorithm used by the core FM (flash module) +/** + * Calculates a signature over @word_count words in the data from @buff16. The algorithm used is the same the FM uses, so the @return may be used to compare with the one generated by the FM module, and check if flashing was successful. + * This algorithm is based on the perl script available from the Freescale website at FAQ 25630. + * + * @param buff16 + * @param word_count + * + * @return + */ static int perl_crc(uint16_t * buff16,uint32_t word_count){ uint16_t checksum = 0xffff; uint16_t data,fbmisr; @@ -940,6 +1019,13 @@ static int perl_crc(uint16_t * buff16,uint32_t word_count){ return checksum; } +/** + * Resets the SIM. (System Integration Module). + * + * @param target + * + * @return + */ int dsp5680xx_f_SIM_reset(struct target * target){ int retval = ERROR_OK; uint16_t sim_cmd = SIM_CMD_RESET; @@ -952,7 +1038,13 @@ int dsp5680xx_f_SIM_reset(struct target * target){ return retval; } -//TODO doxy +/** + * Halts the core and resets the SIM. (System Integration Module). + * + * @param target + * + * @return + */ static int dsp5680xx_soft_reset_halt(struct target *target){ //TODO is this what this function is expected to do...? int retval; @@ -979,6 +1071,18 @@ int dsp5680xx_f_protect_check(struct target * target, uint16_t * protected) { return retval; } +/** + * Executes a command on the FM module. Some commands use the parameters @address and @data, others ignore them. + * + * @param target + * @param command Command to execute. + * @param address Command parameter. + * @param data Command parameter. + * @param hfm_ustat FM status register. + * @param pmem Address is P: (program) memory (@pmem==1) or X: (data) memory (@pmem==0) + * + * @return + */ static int dsp5680xx_f_execute_command(struct target * target, uint16_t command, uint32_t address, uint32_t data, uint16_t * hfm_ustat, int pmem){ int retval; retval = eonce_load_TX_RX_high_to_r0(target); @@ -1055,6 +1159,13 @@ static int dsp5680xx_f_execute_command(struct target * target, uint16_t command, return ERROR_OK; } +/** + * Prior to the execution of any Flash module command, the Flash module Clock Divider (CLKDIV) register must be initialized. The values of this register determine the speed of the internal Flash Clock (FCLK). FCLK must be in the range of 150kHz ≤ FCLK ≤ 200kHz for proper operation of the Flash module. (Running FCLK too slowly wears out the module, while running it too fast under programs Flash leading to bit errors.) + * + * @param target + * + * @return + */ static int eonce_set_hfmdiv(struct target * target){ uint16_t i; int retval; @@ -1093,6 +1204,16 @@ static int eonce_set_hfmdiv(struct target * target){ return ERROR_OK; } +/** + * Executes the FM calculate signature command. The FM will calculate over the data from @address to @address + @words -1. The result is written to a register, then read out by this function and returned in @signature. The value @signature may be compared to the the one returned by perl_crc to verify the flash was written correctly. + * + * @param target + * @param address Start of flash array where the signature should be calculated. + * @param words Number of words over which the signature should be calculated. + * @param signature Value calculated by the FM. + * + * @return + */ static int dsp5680xx_f_signature(struct target * target, uint32_t address, uint32_t words, uint16_t * signature){ int retval; uint16_t hfm_ustat; @@ -1121,6 +1242,15 @@ int dsp5680xx_f_erase_check(struct target * target, uint8_t * erased,uint32_t se return retval; } +/** + * Executes the FM page erase command. + * + * @param target + * @param sector Page to erase. + * @param hfm_ustat FM module status register. + * + * @return + */ static int erase_sector(struct target * target, int sector, uint16_t * hfm_ustat){ int retval; retval = dsp5680xx_f_execute_command(target,HFM_PAGE_ERASE,HFM_FLASH_BASE_ADDR+sector*HFM_SECTOR_SIZE/2,0,hfm_ustat,1); @@ -1128,6 +1258,14 @@ static int erase_sector(struct target * target, int sector, uint16_t * hfm_ustat return retval; } +/** + * Executes the FM mass erase command. Erases the flash array completely. + * + * @param target + * @param hfm_ustat FM module status register. + * + * @return + */ static int mass_erase(struct target * target, uint16_t * hfm_ustat){ int retval; retval = dsp5680xx_f_execute_command(target,HFM_MASS_ERASE,0,0,hfm_ustat,1); @@ -1161,49 +1299,51 @@ int dsp5680xx_f_erase(struct target * target, int first, int last){ }else{ for(int i = first;i<=last;i++){ retval = erase_sector(target,i,&hfm_ustat); - err_check_propagate(retval); - } + err_check_propagate(retval); + } } return ERROR_OK; } -// Algorithm for programming normal p: flash -// Follow state machine from "56F801x Peripheral Reference Manual"@163. -// Registers to set up before calling: -// r0: TX/RX high address. -// r2: FM module base address. -// r3: Destination address in flash. -// -// hfm_wait: // wait for command to finish -// brclr #0x40,x:(r2+0x13),hfm_wait -// rx_check: // wait for input buffer full -// brclr #0x01,x:(r0-2),rx_check -// move.w x:(r0),y0 // read from Rx buffer -// move.w y0,p:(r3)+ -// move.w #0x20,x:(r2+0x14) // write PGM command -// move.w #0x80,x:(r2+0x13) // start the command -// brclr #0x20,X:(R2+0x13),accerr_check // protection violation check -// bfset #0x20,X:(R2+0x13) // clear pviol -// bra hfm_wait -// accerr_check: -// brclr #0x10,X:(R2+0x13),hfm_wait // access error check -// bfset #0x10,X:(R2+0x13) // clear accerr -// bra hfm_wait // loop -//0x00000073 0x8A460013407D brclr #0x40,X:(R2+0x13),*+0 -//0x00000076 0xE700 nop -//0x00000077 0xE700 nop -//0x00000078 0x8A44FFFE017B brclr #1,X:(R0-2),*-2 -//0x0000007B 0xE700 nop -//0x0000007C 0xF514 move.w X:(R0),Y0 -//0x0000007D 0x8563 move.w Y0,P:(R3)+ -//0x0000007E 0x864600200014 move.w #0x20,X:(R2+0x14) -//0x00000081 0x864600800013 move.w #0x80,X:(R2+0x13) -//0x00000084 0x8A4600132004 brclr #0x20,X:(R2+0x13),*+7 -//0x00000087 0x824600130020 bfset #0x20,X:(R2+0x13) -//0x0000008A 0xA968 bra *-23 -//0x0000008B 0x8A4600131065 brclr #0x10,X:(R2+0x13),*-24 -//0x0000008E 0x824600130010 bfset #0x10,X:(R2+0x13) -//0x00000091 0xA961 bra *-30 +/** + * Algorithm for programming normal p: flash + * Follow state machine from "56F801x Peripheral Reference Manual"@163. + * Registers to set up before calling: +* r0: TX/RX high address. +* r2: FM module base address. +* r3: Destination address in flash. +* +* hfm_wait: // wait for command to finish +* brclr #0x40,x:(r2+0x13),hfm_wait +* rx_check: // wait for input buffer full +* brclr #0x01,x:(r0-2),rx_check +* move.w x:(r0),y0 // read from Rx buffer +* move.w y0,p:(r3)+ +* move.w #0x20,x:(r2+0x14) // write PGM command +* move.w #0x80,x:(r2+0x13) // start the command +* brclr #0x20,X:(R2+0x13),accerr_check // protection violation check +* bfset #0x20,X:(R2+0x13) // clear pviol +* bra hfm_wait +* accerr_check: +* brclr #0x10,X:(R2+0x13),hfm_wait // access error check +* bfset #0x10,X:(R2+0x13) // clear accerr +* bra hfm_wait // loop +*0x00000073 0x8A460013407D brclr #0x40,X:(R2+0x13),*+0 +*0x00000076 0xE700 nop +*0x00000077 0xE700 nop +*0x00000078 0x8A44FFFE017B brclr #1,X:(R0-2),*-2 +*0x0000007B 0xE700 nop +*0x0000007C 0xF514 move.w X:(R0),Y0 +*0x0000007D 0x8563 move.w Y0,P:(R3)+ +*0x0000007E 0x864600200014 move.w #0x20,X:(R2+0x14) +*0x00000081 0x864600800013 move.w #0x80,X:(R2+0x13) +*0x00000084 0x8A4600132004 brclr #0x20,X:(R2+0x13),*+7 +*0x00000087 0x824600130020 bfset #0x20,X:(R2+0x13) +*0x0000008A 0xA968 bra *-23 +*0x0000008B 0x8A4600131065 brclr #0x10,X:(R2+0x13),*-24 +*0x0000008E 0x824600130010 bfset #0x10,X:(R2+0x13) +*0x00000091 0xA961 bra *-30 +*/ const uint16_t pgm_write_pflash[] = {0x8A46,0x0013,0x407D,0xE700,0xE700,0x8A44,0xFFFE,0x017B,0xE700,0xF514,0x8563,0x8646,0x0020,0x0014,0x8646,0x0080,0x0013,0x8A46,0x0013,0x2004,0x8246,0x0013,0x0020,0xA968,0x8A46,0x0013,0x1065,0x8246,0x0013,0x0010,0xA961}; const uint32_t pgm_write_pflash_length = 31; @@ -1211,8 +1351,8 @@ int dsp5680xx_f_wr(struct target * target, uint8_t *buffer, uint32_t address, ui int retval = ERROR_OK; uint16_t* buff16 = (uint16_t *) buffer; if (dsp5680xx_target_status(target,NULL,NULL) != TARGET_HALTED){ - retval = dsp5680xx_halt(target); - err_check_propagate(retval); + retval = eonce_enter_debug_mode(target,NULL); + err_check_propagate(retval); } // -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- // Download the pgm that flashes. @@ -1302,8 +1442,6 @@ int dsp5680xx_f_wr(struct target * target, uint8_t *buffer, uint32_t address, ui return retval; } - - int dsp5680xx_f_unlock(struct target * target){ int retval; if(target->tap->enabled){ diff --git a/src/target/dsp5680xx.h b/src/target/dsp5680xx.h index 50ab9907..a5747240 100644 --- a/src/target/dsp5680xx.h +++ b/src/target/dsp5680xx.h @@ -25,6 +25,19 @@ #include +/** + * @file dsp5680xx.h + * @author Rodrigo Rosa + * @date Thu Jun 9 18:54:38 2011 + * + * @brief Basic support for the 5680xx DSP from Freescale. + * The chip has two taps in the JTAG chain, the Master tap and the Core tap. + * In this code the Master tap is only used to unlock the flash memory by executing a JTAG instruction. + * + * + */ + + #define S_FILE_DATA_OFFSET 0x200000 //---------------------------------------------------------------- @@ -160,6 +173,11 @@ #define HFM_USTAT_MASK_BLANK 0x4 #define HFM_USTAT_MASK_PVIOL_ACCER 0x30 +/** + * The value used on for the FM clock is important to prevent flashing errors and to prevent deterioration of the FM. + * This value was calculated using a spreadsheet tool available on the Freescale website under FAQ 25464. + * + */ #define HFM_CLK_DEFAULT 0x40 #define HFM_FLASH_BASE_ADDR 0x0 #define HFM_SIZE_BYTES 0x4000 // bytes @@ -168,10 +186,12 @@ #define HFM_SECTOR_COUNT 0x20 // A 16K block in pages of 256 words. +/** + * Writing HFM_LOCK_FLASH to HFM_LOCK_ADDR_L and HFM_LOCK_ADDR_H will enable security on flash after the next reset. + */ #define HFM_LOCK_FLASH 0xE70A #define HFM_LOCK_ADDR_L 0x1FF7 #define HFM_LOCK_ADDR_H 0x1FF8 -// Writing HFM_LOCK_FLASH to HFM_LOCK_ADDR_L and HFM_LOCK_ADDR_H will enable security on flash after the next reset. //---------------------------------------------------------------- //---------------------------------------------------------------- @@ -203,12 +223,69 @@ static inline struct dsp5680xx_common *target_to_dsp5680xx(struct target *target return target->arch_info; } +/** + * Writes to flash memory. + * Does not check if flash is erased, it's up to the user to erase the flash before running this function. + * + * @param target + * @param buffer + * @param address + * @param count In bytes. + * + * @return + */ int dsp5680xx_f_wr(struct target * target, uint8_t *buffer, uint32_t address, uint32_t count); +/** + * The FM has the funcionality of checking if the flash array is erased. This function executes it. It does not support individual sector analysis. + * + * @param target + * @param erased + * @param sector This parameter is ignored because the FM does not support checking if individual sectors are erased. + * + * @return + */ int dsp5680xx_f_erase_check(struct target * target,uint8_t * erased, uint32_t sector); + +/** + * Erases either a sector or the complete flash array. If either the range first-last covers the complete array or if @first == 0 and @last == 0 then a mass erase command is executed on the FM. If not, then individual sectors are erased. + * + * @param target + * @param first + * @param last + * + * @return + */ int dsp5680xx_f_erase(struct target * target, int first, int last); + +/** + * Reads the memory mapped protection register. + * + * @param target + * @param protected Data read from the protection register. + * + * @return + */ int dsp5680xx_f_protect_check(struct target * target, uint16_t * protected); + +/** + * Writes the flash security words with a specific value. The chip's security will be enabled after the first reset following the execution of this function. + * + * @param target + * + * @return + */ int dsp5680xx_f_lock(struct target * target); + +/** + * Executes a mass erase command. The must be done from the Master tap. + * It is up to the user to select the master tap (jtag tapenable dsp5680xx.chp) before running this function. + * The flash array will be unsecured (and erased) after the first reset following the execution of this function. + * + * @param target + * + * @return + */ int dsp5680xx_f_unlock(struct target * target); #endif // dsp5680xx.h -- 2.39.5