* *
* Copyright (C) 2009 by David N. Claffey <dnclaffey@gmail.com> *
* *
+ * Copyright (C) 2011 by Drasko DRASKOVIC *
+ * drasko.draskovic@gmail.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 *
#include "config.h"
#endif
+#include <helper/time_support.h>
+
#include "mips32.h"
#include "mips32_pracc.h"
static int mips32_pracc_write_u32(struct mips_ejtag *ejtag_info,
uint32_t addr, uint32_t *buf);
+static int mips32_pracc_sync_cache(struct mips_ejtag *ejtag_info,
+ uint32_t start_addr, uint32_t end_addr);
+static int mips32_pracc_clean_invalidate_cache(struct mips_ejtag *ejtag_info,
+ uint32_t start_addr, uint32_t end_addr);
+
static int wait_for_pracc_rw(struct mips_ejtag *ejtag_info, uint32_t *ctrl)
{
uint32_t ejtag_ctrl;
+ long long then = timeval_ms();
+ int timeout;
+ int retval;
+
+ /* wait for the PrAcc to become "1" */
+ mips_ejtag_set_instr(ejtag_info, EJTAG_INST_CONTROL);
+ ejtag_ctrl = ejtag_info->ejtag_ctrl;
while (1)
{
- mips_ejtag_set_instr(ejtag_info, EJTAG_INST_CONTROL);
- ejtag_ctrl = ejtag_info->ejtag_ctrl;
- mips_ejtag_drscan_32(ejtag_info, &ejtag_ctrl);
+ retval = mips_ejtag_drscan_32(ejtag_info, &ejtag_ctrl);
+ if (retval != ERROR_OK)
+ return retval;
+
if (ejtag_ctrl & EJTAG_CTRL_PRACC)
break;
- LOG_DEBUG("DEBUGMODULE: No memory access in progress!");
- return ERROR_JTAG_DEVICE_ERROR;
+
+ if ( (timeout = timeval_ms()-then) > 1000 )
+ {
+ LOG_DEBUG("DEBUGMODULE: No memory access in progress!");
+ return ERROR_JTAG_DEVICE_ERROR;
+ }
}
*ctrl = ejtag_ctrl;
/* Send the data out */
mips_ejtag_set_instr(ctx->ejtag_info, EJTAG_INST_DATA);
- mips_ejtag_drscan_32(ctx->ejtag_info, &data);
+ mips_ejtag_drscan_32_out(ctx->ejtag_info, data);
/* Clear the access pending bit (let the processor eat!) */
ejtag_ctrl = ejtag_info->ejtag_ctrl & ~EJTAG_CTRL_PRACC;
mips_ejtag_set_instr(ctx->ejtag_info, EJTAG_INST_CONTROL);
- mips_ejtag_drscan_32(ctx->ejtag_info, &ejtag_ctrl);
+ mips_ejtag_drscan_32_out(ctx->ejtag_info, ejtag_ctrl);
- jtag_add_clocks(5);
return jtag_execute_queue();
}
uint32_t ejtag_ctrl,data;
int offset;
struct mips_ejtag *ejtag_info = ctx->ejtag_info;
+ int retval;
mips_ejtag_set_instr(ctx->ejtag_info, EJTAG_INST_DATA);
- mips_ejtag_drscan_32(ctx->ejtag_info, &data);
+ retval = mips_ejtag_drscan_32(ctx->ejtag_info, &data);
+ if (retval != ERROR_OK)
+ return retval;
/* Clear access pending bit */
ejtag_ctrl = ejtag_info->ejtag_ctrl & ~EJTAG_CTRL_PRACC;
mips_ejtag_set_instr(ctx->ejtag_info, EJTAG_INST_CONTROL);
- mips_ejtag_drscan_32(ctx->ejtag_info, &ejtag_ctrl);
+ mips_ejtag_drscan_32_out(ctx->ejtag_info, ejtag_ctrl);
- jtag_add_clocks(5);
- return jtag_execute_queue();
+ retval = jtag_execute_queue();
+ if (retval != ERROR_OK)
+ return retval;
if ((address >= MIPS32_PRACC_PARAM_IN)
&& (address <= MIPS32_PRACC_PARAM_IN + ctx->num_iparam * 4))
address = data = 0;
mips_ejtag_set_instr(ejtag_info, EJTAG_INST_ADDRESS);
- mips_ejtag_drscan_32(ejtag_info, &address);
+ retval = mips_ejtag_drscan_32(ejtag_info, &address);
+ if (retval != ERROR_OK)
+ return retval;
/* Check for read or write */
if (ejtag_ctrl & EJTAG_CTRL_PRNW)
uint32_t *param_out = malloc(count * sizeof(uint32_t));
int i;
-// int retval;
+ int retval = ERROR_OK;
int blocksize;
- int bytesread;
uint32_t param_in[2];
- bytesread = 0;
-
//while (count > 0)
{
blocksize = count;
param_in[0] = addr;
param_in[1] = blocksize;
- mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
ARRAY_SIZE(param_in), param_in, count, param_out, 1);
// count -= blocksize;
// addr += blocksize;
-// bytesread += blocksize;
}
for (i = 0; i < count; i++)
free(param_out);
- return ERROR_OK;
+ return retval;
}
static int mips32_pracc_read_mem8(struct mips_ejtag *ejtag_info, uint32_t addr, int count, uint8_t *buf)
uint32_t *param_out = malloc(count * sizeof(uint32_t));
int i;
-// int retval;
+ int retval = ERROR_OK;
int blocksize;
- int bytesread;
uint32_t param_in[2];
- bytesread = 0;
-
// while (count > 0)
{
blocksize = count;
param_in[0] = addr;
param_in[1] = blocksize;
- mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
ARRAY_SIZE(param_in), param_in, count, param_out, 1);
// count -= blocksize;
// addr += blocksize;
-// bytesread += blocksize;
}
for (i = 0; i < count; i++)
free(param_out);
- return ERROR_OK;
+ return retval;
+}
+
+int mips32_cp0_read(struct mips_ejtag *ejtag_info, uint32_t *val, uint32_t cp0_reg, uint32_t cp0_sel)
+{
+ /**
+ * Do not make this code static, but regenerate it every time,
+ * as 5th element has to be changed to add parameters
+ */
+ uint32_t code[] = {
+ /* start: */
+ MIPS32_MTC0(15,31,0), /* move $15 to COP0 DeSave */
+ MIPS32_LUI(15,UPPER16(MIPS32_PRACC_STACK)), /* $15 = MIPS32_PRACC_STACK */
+ MIPS32_ORI(15,15,LOWER16(MIPS32_PRACC_STACK)),
+ MIPS32_SW(8,0,15), /* sw $8,($15) */
+ MIPS32_SW(9,0,15), /* sw $9,($15) */
+
+ /* 5 */ MIPS32_MFC0(8,0,0), /* move COP0 [cp0_reg select] to $8 */
+
+ MIPS32_LUI(9,UPPER16(MIPS32_PRACC_PARAM_OUT)), /* $11 = MIPS32_PRACC_PARAM_OUT */
+ MIPS32_ORI(9,9,LOWER16(MIPS32_PRACC_PARAM_OUT)),
+ MIPS32_SW(8,0,9), /* sw $8,0($9) */
+
+ MIPS32_LW(9,0,15), /* lw $9,($15) */
+ MIPS32_LW(8,0,15), /* lw $8,($15) */
+ MIPS32_B(NEG16(12)), /* b start */
+ MIPS32_MFC0(15,31,0), /* move COP0 DeSave to $15 */
+ };
+
+ /**
+ * Note that our input parametes cp0_reg and cp0_sel
+ * are numbers (not gprs) which make part of mfc0 instruction opcode.
+ *
+ * These are not fix, but can be different for each mips32_cp0_read() function call,
+ * and that is why we must insert them directly into opcode,
+ * i.e. we can not pass it on EJTAG microprogram stack (via param_in),
+ * and put them into the gprs later from MIPS32_PRACC_STACK
+ * because mfc0 do not use gpr as a parameter for the cp0_reg and select part,
+ * but plain (immediate) number.
+ *
+ * MIPS32_MTC0 is implemented via MIPS32_R_INST macro.
+ * In order to insert our parameters, we must change rd and funct fields.
+ */
+ code[5] |= (cp0_reg << 11) | cp0_sel; /* change rd and funct of MIPS32_R_INST macro */
+
+ /* TODO remove array */
+ uint32_t *param_out = val;
+ int retval;
+
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, 0, NULL, 1, param_out, 1);
+
+ return retval;
+}
+
+int mips32_cp0_write(struct mips_ejtag *ejtag_info,
+ uint32_t val, uint32_t cp0_reg, uint32_t cp0_sel)
+{
+ uint32_t code[] = {
+ /* start: */
+ MIPS32_MTC0(15,31,0), /* move $15 to COP0 DeSave */
+ MIPS32_LUI(15,UPPER16(MIPS32_PRACC_STACK)), /* $15 = MIPS32_PRACC_STACK */
+ MIPS32_ORI(15,15,LOWER16(MIPS32_PRACC_STACK)),
+ MIPS32_SW(8,0,15), /* sw $8,($15) */
+ MIPS32_SW(9,0,15), /* sw $9,($15) */
+
+ MIPS32_LUI(8,UPPER16(MIPS32_PRACC_PARAM_IN)), /* $8 = MIPS32_PRACC_PARAM_IN */
+ MIPS32_ORI(8,8,LOWER16(MIPS32_PRACC_PARAM_IN)),
+ MIPS32_LW(9,0,8), /* Load write val to $9 */
+
+ /* 8 */ MIPS32_MTC0(9,0,0), /* move $9 to COP0 [cp0_reg select] */
+
+ MIPS32_LW(9,0,15), /* lw $9,($15) */
+ MIPS32_LW(8,0,15), /* lw $8,($15) */
+ MIPS32_B(NEG16(12)), /* b start */
+ MIPS32_MFC0(15,31,0), /* move COP0 DeSave to $15 */
+ };
+
+ /**
+ * Note that MIPS32_MTC0 macro is implemented via MIPS32_R_INST macro.
+ * In order to insert our parameters, we must change rd and funct fields.
+ */
+ code[8] |= (cp0_reg << 11) | cp0_sel; /* change rd and funct fields of MIPS32_R_INST macro */
+
+ /* TODO remove array */
+ uint32_t *param_in = malloc(1 * sizeof(uint32_t));
+ int retval;
+ param_in[0] = val;
+
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, 1, param_in, 0, NULL, 1);
+
+ free(param_in);
+
+ return retval;
}
+/**
+ * \b mips32_pracc_sync_cache
+ *
+ * Synchronize Caches to Make Instruction Writes Effective
+ * (ref. doc. MIPS32 Architecture For Programmers Volume II: The MIPS32 Instruction Set,
+ * Document Number: MD00086, Revision 2.00, June 9, 2003)
+ *
+ * When the instruction stream is written, the SYNCI instruction should be used
+ * in conjunction with other instructions to make the newly-written instructions effective.
+ *
+ * Explanation :
+ * A program that loads another program into memory is actually writing the D- side cache.
+ * The instructions it has loaded can't be executed until they reach the I-cache.
+ *
+ * After the instructions have been written, the loader should arrange
+ * to write back any containing D-cache line and invalidate any locations
+ * already in the I-cache.
+ *
+ * You can do that with cache instructions, but those instructions are only available in kernel mode,
+ * and a loader writing instructions for the use of its own process need not be privileged software.
+ *
+ * In the latest MIPS32/64 CPUs, MIPS provides the synci instruction,
+ * which does the whole job for a cache-line-sized chunk of the memory you just loaded:
+ * That is, it arranges a D-cache write-back and an I-cache invalidate.
+ *
+ * To employ synci at user level, you need to know the size of a cache line,
+ * and that can be obtained with a rdhwr SYNCI_Step
+ * from one of the standard “hardware registers”.
+ */
+static int mips32_pracc_sync_cache(struct mips_ejtag *ejtag_info,
+ uint32_t start_addr, uint32_t end_addr)
+{
+ static const uint32_t code[] = {
+ /* start: */
+ MIPS32_MTC0(15,31,0), /* move $15 to COP0 DeSave */
+ MIPS32_LUI(15,UPPER16(MIPS32_PRACC_STACK)), /* $15 = MIPS32_PRACC_STACK */
+ MIPS32_ORI(15,15,LOWER16(MIPS32_PRACC_STACK)),
+ MIPS32_SW(8,0,15), /* sw $8,($15) */
+ MIPS32_SW(9,0,15), /* sw $9,($15) */
+ MIPS32_SW(10,0,15), /* sw $10,($15) */
+ MIPS32_SW(11,0,15), /* sw $11,($15) */
+
+ MIPS32_LUI(8,UPPER16(MIPS32_PRACC_PARAM_IN)), /* $8 = MIPS32_PRACC_PARAM_IN */
+ MIPS32_ORI(8,8,LOWER16(MIPS32_PRACC_PARAM_IN)),
+ MIPS32_LW(9,0,8), /* Load write start_addr to $9 */
+ MIPS32_LW(10,4,8), /* Load write end_addr to $10 */
+
+ MIPS32_RDHWR(11, MIPS32_SYNCI_STEP), /* $11 = MIPS32_SYNCI_STEP */
+ MIPS32_BEQ(11,0,6), /* beq $11, $0, end */
+ MIPS32_NOP,
+ /* synci_loop : */
+ MIPS32_SYNCI(0,9), /* synci 0($9) */
+ MIPS32_SLTU(8,10,9), /* sltu $8, $10, $9 # $8 = $10 < $9 ? 1 : 0 */
+ MIPS32_BNE(8,0,NEG16(3)), /* bne $8, $0, synci_loop */
+ MIPS32_ADDU(9, 9, 11), /* $9 += MIPS32_SYNCI_STEP */
+ MIPS32_SYNC,
+ /* end: */
+ MIPS32_LW(11,0,15), /* lw $11,($15) */
+ MIPS32_LW(10,0,15), /* lw $10,($15) */
+ MIPS32_LW(9,0,15), /* lw $9,($15) */
+ MIPS32_LW(8,0,15), /* lw $8,($15) */
+ MIPS32_B(NEG16(24)), /* b start */
+ MIPS32_MFC0(15,31,0), /* move COP0 DeSave to $15 */
+ };
+
+ /* TODO remove array */
+ uint32_t *param_in = malloc(2 * sizeof(uint32_t));
+ int retval;
+ param_in[0] = start_addr;
+ param_in[1] = end_addr;
+
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, 2, param_in, 0, NULL, 1);
+
+ free(param_in);
+
+ return retval;
+}
+
+/**
+ * \b mips32_pracc_clean_invalidate_cache
+ *
+ * Writeback D$ and Invalidate I$
+ * so that the instructions written can be visible to CPU
+ */
+static int mips32_pracc_clean_invalidate_cache(struct mips_ejtag *ejtag_info,
+ uint32_t start_addr, uint32_t end_addr)
+{
+ static const uint32_t code[] = {
+ /* start: */
+ MIPS32_MTC0(15,31,0), /* move $15 to COP0 DeSave */
+ MIPS32_LUI(15,UPPER16(MIPS32_PRACC_STACK)), /* $15 = MIPS32_PRACC_STACK */
+ MIPS32_ORI(15,15,LOWER16(MIPS32_PRACC_STACK)),
+ MIPS32_SW(8,0,15), /* sw $8,($15) */
+ MIPS32_SW(9,0,15), /* sw $9,($15) */
+ MIPS32_SW(10,0,15), /* sw $10,($15) */
+ MIPS32_SW(11,0,15), /* sw $11,($15) */
+
+ MIPS32_LUI(8,UPPER16(MIPS32_PRACC_PARAM_IN)), /* $8 = MIPS32_PRACC_PARAM_IN */
+ MIPS32_ORI(8,8,LOWER16(MIPS32_PRACC_PARAM_IN)),
+ MIPS32_LW(9,0,8), /* Load write start_addr to $9 */
+ MIPS32_LW(10,4,8), /* Load write end_addr to $10 */
+ MIPS32_LW(11,8,8), /* Load write clsiz to $11 */
+
+ /* cache_loop: */
+ MIPS32_SLTU(8,10,9), /* sltu $8, $10, $9 : $8 <- $10 < $9 ? */
+ MIPS32_BGTZ(8,6), /* bgtz $8, end */
+ MIPS32_NOP,
+
+ MIPS32_CACHE(MIPS32_CACHE_D_HIT_WRITEBACK,0,9), /* cache Hit_Writeback_D, 0($9) */
+ MIPS32_CACHE(MIPS32_CACHE_I_HIT_INVALIDATE,0,9), /* cache Hit_Invalidate_I, 0($9) */
+
+ MIPS32_ADDU(9,9,11), /* $9 += $11 */
+
+ MIPS32_B(NEG16(7)), /* b cache_loop */
+ MIPS32_NOP,
+ /* end: */
+ MIPS32_LW(11,0,15), /* lw $11,($15) */
+ MIPS32_LW(10,0,15), /* lw $10,($15) */
+ MIPS32_LW(9,0,15), /* lw $9,($15) */
+ MIPS32_LW(8,0,15), /* lw $8,($15) */
+ MIPS32_B(NEG16(25)), /* b start */
+ MIPS32_MFC0(15,31,0), /* move COP0 DeSave to $15 */
+ };
+
+ /**
+ * Find cache line size in bytes
+ */
+ uint32_t conf;
+ uint32_t dl, clsiz;
+
+ mips32_cp0_read(ejtag_info, &conf, 16, 1);
+ dl = (conf & MIPS32_CONFIG1_DL_MASK) >> MIPS32_CONFIG1_DL_SHIFT;
+
+ /* dl encoding : dl=1 => 4 bytes, dl=2 => 8 bytes, etc... */
+ clsiz = 0x2 << dl;
+
+ /* TODO remove array */
+ uint32_t *param_in = malloc(3 * sizeof(uint32_t));
+ int retval;
+ param_in[0] = start_addr;
+ param_in[1] = end_addr;
+ param_in[2] = clsiz;
+
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, 3, param_in, 0, NULL, 1);
+
+ free(param_in);
+
+ return retval;
+}
+
+
int mips32_pracc_write_mem(struct mips_ejtag *ejtag_info, uint32_t addr, int size, int count, void *buf)
{
+ int retval;
+
switch (size)
{
case 1:
- return mips32_pracc_write_mem8(ejtag_info, addr, count, (uint8_t*)buf);
+ retval = mips32_pracc_write_mem8(ejtag_info, addr, count, (uint8_t*)buf);
+ break;
case 2:
- return mips32_pracc_write_mem16(ejtag_info, addr, count,(uint16_t*)buf);
+ retval = mips32_pracc_write_mem16(ejtag_info, addr, count,(uint16_t*)buf);
+ break;
case 4:
if (count == 1)
- return mips32_pracc_write_u32(ejtag_info, addr, (uint32_t*)buf);
+ {
+ retval = mips32_pracc_write_u32(ejtag_info, addr, (uint32_t*)buf);
+ }
else
- return mips32_pracc_write_mem32(ejtag_info, addr, count, (uint32_t*)buf);
+ {
+ retval = mips32_pracc_write_mem32(ejtag_info, addr, count, (uint32_t*)buf);
+ }
+ break;
+ default:
+ retval = ERROR_FAIL;
}
- return ERROR_OK;
+ /**
+ * If we are in the cachable regoion and cache is activated,
+ * we must clean D$ + invalidate I$ after we did the write,
+ * so that changes do not continue to live only in D$, but to be
+ * replicated in I$ also (maybe we wrote the istructions)
+ */
+ uint32_t conf = 0;
+ int cached = 0;
+
+ mips32_cp0_read(ejtag_info, &conf, 16, 0);
+
+ switch (KSEGX(addr))
+ {
+ case KUSEG:
+ cached = (conf & MIPS32_CONFIG0_KU_MASK) >> MIPS32_CONFIG0_KU_SHIFT;
+ break;
+ case KSEG0 :
+ cached = (conf & MIPS32_CONFIG0_K0_MASK) >> MIPS32_CONFIG0_K0_SHIFT;
+ break;
+ case KSEG1:
+ /* uncachable segment - nothing to do */
+ break;
+ case KSEG2:
+ case KSEG3:
+ cached = (conf & MIPS32_CONFIG0_K23_MASK) >> MIPS32_CONFIG0_K23_SHIFT;
+ break;
+ default:
+ /* what ? */
+ break;
+ }
+
+ /**
+ * Check cachablitiy bits coherency algorithm -
+ * is the region cacheable or uncached.
+ * If cacheable we have to synchronize the cache
+ */
+ if (cached == 0x3)
+ {
+ uint32_t start_addr, end_addr;
+ uint32_t rel;
+
+ start_addr = addr;
+ end_addr = addr + count * size;
+
+ /** select cache synchronisation mechanism based on Architecture Release */
+ rel = (conf & MIPS32_CONFIG0_AR_MASK) >> MIPS32_CONFIG0_AR_SHIFT;
+ switch (rel)
+ {
+ case MIPS32_ARCH_REL1 :
+ /* MIPS32/64 Release 1 - we must use cache instruction */
+ mips32_pracc_clean_invalidate_cache(ejtag_info, start_addr, end_addr);
+ break;
+ case MIPS32_ARCH_REL2 :
+ /* MIPS32/64 Release 2 - we can use synci instruction */
+ mips32_pracc_sync_cache(ejtag_info, start_addr, end_addr);
+ break;
+ default :
+ /* what ? */
+ break;
+ }
+ }
+
+ return retval;
}
static int mips32_pracc_write_mem32(struct mips_ejtag *ejtag_info, uint32_t addr, int count, uint32_t *buf)
memcpy(¶m_in[2], buf, count * sizeof(uint32_t));
- mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ int retval;
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
count + 2, param_in, 0, NULL, 1);
free(param_in);
- return ERROR_OK;
+ return retval;
}
static int mips32_pracc_write_u32(struct mips_ejtag *ejtag_info, uint32_t addr, uint32_t *buf)
param_in[0] = addr;
param_in[1] = *buf;
- mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ return mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
ARRAY_SIZE(param_in), param_in, 0, NULL, 1);
-
- return ERROR_OK;
}
static int mips32_pracc_write_mem16(struct mips_ejtag *ejtag_info, uint32_t addr, int count, uint16_t *buf)
param_in[i + 2] = buf[i];
}
- mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ int retval;
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
count + 2, param_in, 0, NULL, 1);
free(param_in);
- return ERROR_OK;
+ return retval;
}
static int mips32_pracc_write_mem8(struct mips_ejtag *ejtag_info, uint32_t addr, int count, uint8_t *buf)
param_in[i + 2] = buf[i];
}
- retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
count + 2, param_in, 0, NULL, 1);
free(param_in);
int retval;
- retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
MIPS32NUMCOREREGS, regs, 0, NULL, 1);
return retval;
int retval;
- retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code, \
+ retval = mips32_pracc_exec(ejtag_info, ARRAY_SIZE(code), code,
0, NULL, MIPS32NUMCOREREGS, regs, 1);
return retval;
return retval;
mips_ejtag_set_instr(ejtag_info, EJTAG_INST_DATA);
- mips_ejtag_drscan_32(ejtag_info, &jmp_code[i]);
+ mips_ejtag_drscan_32_out(ejtag_info, jmp_code[i]);
/* Clear the access pending bit (let the processor eat!) */
ejtag_ctrl = ejtag_info->ejtag_ctrl & ~EJTAG_CTRL_PRACC;
mips_ejtag_set_instr(ejtag_info, EJTAG_INST_CONTROL);
- mips_ejtag_drscan_32(ejtag_info, &ejtag_ctrl);
+ mips_ejtag_drscan_32_out(ejtag_info, ejtag_ctrl);
}
if ((retval = wait_for_pracc_rw(ejtag_info, &ejtag_ctrl)) != ERROR_OK)
/* next fetch to dmseg should be in FASTDATA_AREA, check */
address = 0;
mips_ejtag_set_instr(ejtag_info, EJTAG_INST_ADDRESS);
- mips_ejtag_drscan_32(ejtag_info, &address);
+ retval = mips_ejtag_drscan_32(ejtag_info, &address);
+ if (retval != ERROR_OK)
+ return retval;
if (address != MIPS32_PRACC_FASTDATA_AREA)
return ERROR_FAIL;
+ /* wait PrAcc pending bit for FASTDATA write */
+ if ((retval = wait_for_pracc_rw(ejtag_info, &ejtag_ctrl)) != ERROR_OK)
+ return retval;
+
/* Send the load start address */
val = addr;
mips_ejtag_set_instr(ejtag_info, EJTAG_INST_FASTDATA);
/* Send the load end address */
val = addr + (count - 1) * 4;
- mips_ejtag_set_instr(ejtag_info, EJTAG_INST_FASTDATA);
mips_ejtag_fastdata_scan(ejtag_info, 1, &val);
for (i = 0; i < count; i++)
{
- /* Send the data out using fastdata (clears the access pending bit) */
if ((retval = mips_ejtag_fastdata_scan(ejtag_info, write_t, buf++)) != ERROR_OK)
return retval;
}
address = 0;
mips_ejtag_set_instr(ejtag_info, EJTAG_INST_ADDRESS);
- mips_ejtag_drscan_32(ejtag_info, &address);
+ retval = mips_ejtag_drscan_32(ejtag_info, &address);
+ if (retval != ERROR_OK)
+ return retval;
if (address != MIPS32_PRACC_TEXT)
LOG_ERROR("mini program did not return to start");