Add support for 64-bit memory reads/writes (#419)

* 64-bit progbuf memory reads work. Change-Id: Ia3dbc0ee39a31ed0e5c38bbb3d9e089b2533f399 * 64-bit writes work. Change-Id: Iae78711d715b6682817bb7cce366b0094bda8b23 * Let targets indicate number of supported data bits. This is used by the default memory read/write functions when creating an aligned block. I'm adding this mainly to ensure I get coverage of the 64-bit progbuf memory read/write code. Change-Id: Ie5909fe537c9ec3360a8d2837f84be00a63de77b * Make mingw32 happy. Change-Id: Iade8c1fdfc72ccafc82f2f34923577032b668916
2019-11-04 11:04:30 -08:00 · 2019-11-04 11:04:30 -08:00 · f93ede5401
parent 20804cb4d2
commit f93ede5401
8 changed files with 142 additions and 56 deletions
--- a/src/target/riscv/program.c
+++ b/src/target/riscv/program.c
@ -79,6 +79,11 @@ int riscv_program_exec(struct riscv_program *p, struct target *t)
 	return ERROR_OK;
 }
 int riscv_program_sdr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
 {
 	return riscv_program_insert(p, sd(d, b, offset));
 }
 int riscv_program_swr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
 {
 	return riscv_program_insert(p, sw(d, b, offset));
@ -94,6 +99,11 @@ int riscv_program_sbr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno
 	return riscv_program_insert(p, sb(d, b, offset));
 }
 int riscv_program_ldr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
 {
 	return riscv_program_insert(p, ld(d, b, offset));
 }
 int riscv_program_lwr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
 {
 	return riscv_program_insert(p, lw(d, b, offset));
--- a/src/target/riscv/program.h
+++ b/src/target/riscv/program.h
@ -55,10 +55,12 @@ int riscv_program_save_to_dscratch(struct riscv_program *p, enum gdb_regno to_sa
 /* Helpers to assemble various instructions.  Return 0 on success.  These might
 * assemble into a multi-instruction sequence that overwrites some other
 * register, but those will be properly saved and restored. */
 int riscv_program_ldr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno a, int o);
 int riscv_program_lwr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno a, int o);
 int riscv_program_lhr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno a, int o);
 int riscv_program_lbr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno a, int o);
 int riscv_program_sdr(struct riscv_program *p, enum gdb_regno s, enum gdb_regno a, int o);
 int riscv_program_swr(struct riscv_program *p, enum gdb_regno s, enum gdb_regno a, int o);
 int riscv_program_shr(struct riscv_program *p, enum gdb_regno s, enum gdb_regno a, int o);
 int riscv_program_sbr(struct riscv_program *p, enum gdb_regno s, enum gdb_regno a, int o);
--- a/src/target/riscv/riscv-013.c
+++ b/src/target/riscv/riscv-013.c
@ -1261,8 +1261,8 @@ static int register_write_direct(struct target *target, unsigned number,
 	RISCV013_INFO(info);
 	RISCV_INFO(r);
-	LOG_DEBUG("{%d} reg[0x%x] <- 0x%" PRIx64, riscv_current_hartid(target),
+	LOG_DEBUG("{%d} %s <- 0x%" PRIx64, riscv_current_hartid(target),
-			number, value);
+			gdb_regno_name(number), value);
 	int result = register_write_abstract(target, number, value,
 			register_size(target, number));
@ -1449,8 +1449,8 @@ static int register_read_direct(struct target *target, uint64_t *value, uint32_t
 	}
 	if (result == ERROR_OK) {
-		LOG_DEBUG("{%d} reg[0x%x] = 0x%" PRIx64, riscv_current_hartid(target),
+		LOG_DEBUG("{%d} %s = 0x%" PRIx64, riscv_current_hartid(target),
-				number, *value);
+				gdb_regno_name(number), *value);
 	}
 	return result;
@ -1949,25 +1949,32 @@ static int deassert_reset(struct target *target)
 /**
 * @par size in bytes
 */
-static void read_from_buf(uint64_t *value, const uint8_t *buffer, unsigned size)
+static uint64_t read_from_buf(const uint8_t *buffer, unsigned size)
 {
 	switch (size) {
 		case 1:
-			*value = buffer[0];
+			return buffer[0];
 			break;
 		case 2:
-			*value = buffer[0]
+			return buffer[0]
 				| ((uint64_t) buffer[1] << 8);
 			break;
 		case 4:
-			*value = buffer[0]
+			return buffer[0]
 				| ((uint64_t) buffer[1] << 8)
 				| ((uint64_t) buffer[2] << 16)
 				| ((uint64_t) buffer[3] << 24);
-			break;
+		case 8:
 			return buffer[0]
 				| ((uint64_t) buffer[1] << 8)
 				| ((uint64_t) buffer[2] << 16)
 				| ((uint64_t) buffer[3] << 24)
 				| ((uint64_t) buffer[4] << 32)
 				| ((uint64_t) buffer[5] << 40)
 				| ((uint64_t) buffer[6] << 48)
 				| ((uint64_t) buffer[7] << 56);
 		default:
 			assert(false);
 	}
 	return -1;
 }
 /**
@ -2042,7 +2049,21 @@ static void log_memory_access(target_addr_t address, uint64_t value,
 	char fmt[80];
 	sprintf(fmt, "M[0x%" TARGET_PRIxADDR "] %ss 0x%%0%d" PRIx64,
 			address, read ? "read" : "write", size_bytes * 2);
-	value &= (((uint64_t) 0x1) << (size_bytes * 8)) - 1;
+	switch (size_bytes) {
 		case 1:
 			value &= 0xff;
 			break;
 		case 2:
 			value &= 0xffff;
 			break;
 		case 4:
 			value &= 0xffffffff;
 			break;
 		case 8:
 			break;
 		default:
 			assert(false);
 	}
 	LOG_DEBUG(fmt, value);
 }
@ -2446,8 +2467,7 @@ static int write_memory_abstract(struct target *target, target_addr_t address,
 	bool updateaddr = true;
 	for (uint32_t c = 0; c < count; c++) {
 		/* Move data to arg0 */
-		riscv_reg_t value = 0;
+		riscv_reg_t value = read_from_buf(p, size);
 		read_from_buf(&value, p, size);
 		result = write_abstract_arg(target, 0, value, riscv_xlen(target));
 		if (result != ERROR_OK) {
 			LOG_ERROR("Failed to write arg0 during write_memory_abstract().");
@ -2542,6 +2562,8 @@ static int read_memory_progbuf_inner(struct target *target, target_addr_t addres
 		size_t reads = 0;
 		for (riscv_addr_t addr = read_addr; addr < fin_addr; addr += size) {
 			if (size > 4)
 				riscv_batch_add_dmi_read(batch, DMI_DATA1);
 			riscv_batch_add_dmi_read(batch, DMI_DATA0);
 			reads++;
@ -2577,7 +2599,7 @@ static int read_memory_progbuf_inner(struct target *target, target_addr_t addres
 				dmi_write(target, DMI_ABSTRACTAUTO, 0);
-				uint32_t dmi_data0;
+				uint32_t dmi_data0, dmi_data1 = 0;
 				/* This is definitely a good version of the value that we
 				 * attempted to read when we discovered that the target was
 				 * busy. */
@ -2585,6 +2607,10 @@ static int read_memory_progbuf_inner(struct target *target, target_addr_t addres
 					riscv_batch_free(batch);
 					goto error;
 				}
 				if (size > 4 && dmi_read(target, &dmi_data1, DMI_DATA1) != ERROR_OK) {
 					riscv_batch_free(batch);
 					goto error;
 				}
 				/* See how far we got, clobbering dmi_data0. */
 				result = register_read_direct(target, &next_read_addr,
@ -2593,8 +2619,9 @@ static int read_memory_progbuf_inner(struct target *target, target_addr_t addres
 					riscv_batch_free(batch);
 					goto error;
 				}
-				write_to_buf(buffer + next_read_addr - 2 * size - address, dmi_data0, size);
+				uint64_t value64 = (((uint64_t) dmi_data1) << 32) | dmi_data0;
-				log_memory_access(next_read_addr - 2 * size, dmi_data0, size, true);
+				write_to_buf(buffer + next_read_addr - 2 * size - address, value64, size);
 				log_memory_access(next_read_addr - 2 * size, value64, size, true);
 				/* Restore the command, and execute it.
 				 * Now DMI_DATA0 contains the next value just as it would if no
@ -2618,15 +2645,16 @@ static int read_memory_progbuf_inner(struct target *target, target_addr_t addres
 		/* Now read whatever we got out of the batch. */
 		dmi_status_t status = DMI_STATUS_SUCCESS;
 		riscv_addr_t receive_addr = read_addr - size * 2;
 		unsigned read = 0;
 		for (size_t i = 0; i < reads; i++) {
 			riscv_addr_t receive_addr = read_addr + (i-2) * size;
 			assert(receive_addr < address + size * count);
 			if (receive_addr < address)
 				continue;
 			if (receive_addr > next_read_addr - (3 + ignore_last) * size)
 				break;
-			uint64_t dmi_out = riscv_batch_get_dmi_read(batch, i);
+			uint64_t dmi_out = riscv_batch_get_dmi_read(batch, read++);
 			status = get_field(dmi_out, DTM_DMI_OP);
 			if (status != DMI_STATUS_SUCCESS) {
 				/* If we're here because of busy count, dmi_busy_delay will
@ -2643,7 +2671,20 @@ static int read_memory_progbuf_inner(struct target *target, target_addr_t addres
 				result = ERROR_FAIL;
 				goto error;
 			}
-			uint32_t value = get_field(dmi_out, DTM_DMI_DATA);
+			uint64_t value = get_field(dmi_out, DTM_DMI_DATA);
 			if (size > 4) {
 				dmi_out = riscv_batch_get_dmi_read(batch, read++);
 				status = get_field(dmi_out, DTM_DMI_OP);
 				if (status != DMI_STATUS_SUCCESS) {
 					LOG_WARNING("Batch memory read encountered DMI error %d. "
 							"Falling back on slower reads.", status);
 					riscv_batch_free(batch);
 					result = ERROR_FAIL;
 					goto error;
 				}
 				value <<= 32;
 				value |= get_field(dmi_out, DTM_DMI_DATA);
 			}
 			riscv_addr_t offset = receive_addr - address;
 			write_to_buf(buffer + offset, value, size);
 			log_memory_access(receive_addr, value, size, true);
@ -2660,11 +2701,14 @@ static int read_memory_progbuf_inner(struct target *target, target_addr_t addres
 	if (count > 1) {
 		/* Read the penultimate word. */
-		uint32_t value;
+		uint32_t dmi_data0, dmi_data1 = 0;
-		if (dmi_read(target, &value, DMI_DATA0) != ERROR_OK)
+		if (dmi_read(target, &dmi_data0, DMI_DATA0) != ERROR_OK)
 			return ERROR_FAIL;
-		write_to_buf(buffer + size * (count-2), value, size);
+		if (size > 4 && dmi_read(target, &dmi_data1, DMI_DATA1) != ERROR_OK)
-		log_memory_access(address + size * (count-2), value, size, true);
+			return ERROR_FAIL;
 		uint64_t value64 = (((uint64_t) dmi_data1) << 32) | dmi_data0;
 		write_to_buf(buffer + size * (count-2), value64, size);
 		log_memory_access(address + size * (count-2), value64, size, true);
 	}
 	/* Read the last word. */
@ -2715,6 +2759,9 @@ static int read_memory_progbuf_one(struct target *target, target_addr_t address,
 		case 4:
 			riscv_program_lwr(&program, GDB_REGNO_S0, GDB_REGNO_S0, 0);
 			break;
 		case 8:
 			riscv_program_ldr(&program, GDB_REGNO_S0, GDB_REGNO_S0, 0);
 			break;
 		default:
 			LOG_ERROR("Unsupported size: %d", size);
 			return ERROR_FAIL;
@ -2740,6 +2787,7 @@ static int read_memory_progbuf_one(struct target *target, target_addr_t address,
 	if (register_read(target, &value, GDB_REGNO_S0) != ERROR_OK)
 		return ERROR_FAIL;
 	write_to_buf(buffer, value, size);
 	log_memory_access(address, value, size, true);
 	if (riscv_set_register(target, GDB_REGNO_S0, s0) != ERROR_OK)
 		return ERROR_FAIL;
@ -2760,6 +2808,12 @@ static int read_memory_progbuf(struct target *target, target_addr_t address,
 {
 	RISCV013_INFO(info);
 	if (riscv_xlen(target) < size * 8) {
 		LOG_ERROR("XLEN (%d) is too short for %d-bit memory read.",
 				riscv_xlen(target), size * 8);
 		return ERROR_FAIL;
 	}
 	int result = ERROR_OK;
 	LOG_DEBUG("reading %d words of %d bytes from 0x%" TARGET_PRIxADDR, count,
@ -2805,10 +2859,14 @@ static int read_memory_progbuf(struct target *target, target_addr_t address,
 		case 4:
 			riscv_program_lwr(&program, GDB_REGNO_S1, GDB_REGNO_S0, 0);
 			break;
 		case 8:
 			riscv_program_ldr(&program, GDB_REGNO_S1, GDB_REGNO_S0, 0);
 			break;
 		default:
 			LOG_ERROR("Unsupported size: %d", size);
 			return ERROR_FAIL;
 	}
 	if (riscv_enable_virtual && info->progbufsize >= 4 && get_field(mstatus, MSTATUS_MPRV))
 		riscv_program_csrrci(&program, GDB_REGNO_ZERO,  CSR_DCSR_MPRVEN, GDB_REGNO_DCSR);
 	riscv_program_addi(&program, GDB_REGNO_S0, GDB_REGNO_S0, size);
@ -3088,6 +3146,12 @@ static int write_memory_progbuf(struct target *target, target_addr_t address,
 {
 	RISCV013_INFO(info);
 	if (riscv_xlen(target) < size * 8) {
 		LOG_ERROR("XLEN (%d) is too short for %d-bit memory write.",
 				riscv_xlen(target), size * 8);
 		return ERROR_FAIL;
 	}
 	LOG_DEBUG("writing %d words of %d bytes to 0x%08lx", count, size, (long)address);
 	select_dmi(target);
@ -3124,8 +3188,11 @@ static int write_memory_progbuf(struct target *target, target_addr_t address,
 		case 4:
 			riscv_program_swr(&program, GDB_REGNO_S1, GDB_REGNO_S0, 0);
 			break;
 		case 8:
 			riscv_program_sdr(&program, GDB_REGNO_S1, GDB_REGNO_S0, 0);
 			break;
 		default:
-			LOG_ERROR("Unsupported size: %d", size);
+			LOG_ERROR("write_memory_progbuf(): Unsupported size: %d", size);
 			result = ERROR_FAIL;
 			goto error;
 	}
@ -3158,28 +3225,7 @@ static int write_memory_progbuf(struct target *target, target_addr_t address,
 			unsigned offset = size*i;
 			const uint8_t *t_buffer = buffer + offset;
-			/* TODO: Test with read_from_buf(&value, t_buffer, size)*/
+			uint64_t value = read_from_buf(t_buffer, size);
 			uint32_t value;
 			switch (size) {
 				case 1:
 					value = t_buffer[0];
 					break;
 				case 2:
 					value = t_buffer[0]
 						| ((uint32_t) t_buffer[1] << 8);
 					break;
 				case 4:
 					value = t_buffer[0]
 						| ((uint32_t) t_buffer[1] << 8)
 						| ((uint32_t) t_buffer[2] << 16)
 						| ((uint32_t) t_buffer[3] << 24);
 					break;
 				default:
 					LOG_ERROR("unsupported access size: %d", size);
 					riscv_batch_free(batch);
 					result = ERROR_FAIL;
 					goto error;
 			}
 			log_memory_access(address + offset, value, size, false);
 			cur_addr += size;
@ -3193,12 +3239,14 @@ static int write_memory_progbuf(struct target *target, target_addr_t address,
 				}
 				/* Write value. */
 				if (size > 4)
 					dmi_write(target, DMI_DATA1, value >> 32);
 				dmi_write(target, DMI_DATA0, value);
 				/* Write and execute command that moves value into S1 and
 				 * executes program buffer. */
 				uint32_t command = access_register_command(target,
-						GDB_REGNO_S1, 32,
+						GDB_REGNO_S1, size > 4 ? 64 : 32,
 						AC_ACCESS_REGISTER_POSTEXEC |
 						AC_ACCESS_REGISTER_TRANSFER |
 						AC_ACCESS_REGISTER_WRITE);
@ -3214,6 +3262,8 @@ static int write_memory_progbuf(struct target *target, target_addr_t address,
 				setup_needed = false;
 			} else {
 				if (size > 4)
 					riscv_batch_add_dmi_write(batch, DMI_DATA1, value >> 32);
 				riscv_batch_add_dmi_write(batch, DMI_DATA0, value);
 				if (riscv_batch_full(batch))
 					break;
--- a/src/target/riscv/riscv.c
+++ b/src/target/riscv/riscv.c
@ -2457,7 +2457,7 @@ const struct command_registration riscv_command_handlers[] = {
 	COMMAND_REGISTRATION_DONE
 };
-unsigned riscv_address_bits(struct target *target)
+static unsigned riscv_xlen_nonconst(struct target *target)
 {
 	return riscv_xlen(target);
 }
@ -2500,7 +2500,8 @@ struct target_type riscv_target = {
 	.commands = riscv_command_handlers,
-	.address_bits = riscv_address_bits
+	.address_bits = riscv_xlen_nonconst,
 	.data_bits = riscv_xlen_nonconst
 };
 /*** RISC-V Interface ***/
@ -2609,7 +2610,7 @@ bool riscv_supports_extension(struct target *target, int hartid, char letter)
 	return r->misa[hartid] & (1 << num);
 }
-int riscv_xlen(const struct target *target)
+unsigned riscv_xlen(const struct target *target)
 {
 	return riscv_xlen_of_hart(target, riscv_current_hartid(target));
 }
--- a/src/target/riscv/riscv.h
+++ b/src/target/riscv/riscv.h
@ -218,7 +218,7 @@ int riscv_step_rtos_hart(struct target *target);
 bool riscv_supports_extension(struct target *target, int hartid, char letter);
 /* Returns XLEN for the given (or current) hart. */
-int riscv_xlen(const struct target *target);
+unsigned riscv_xlen(const struct target *target);
 int riscv_xlen_of_hart(const struct target *target, int hartid);
 bool riscv_rtos_enabled(const struct target *target);
--- a/src/target/target.c
+++ b/src/target/target.c
@ -1284,6 +1284,13 @@ unsigned target_address_bits(struct target *target)
 	return 32;
 }
 unsigned target_data_bits(struct target *target)
 {
 	if (target->type->data_bits)
 		return target->type->data_bits(target);
 	return 32;
 }
 int target_profiling(struct target *target, uint32_t *samples,
 			uint32_t max_num_samples, uint32_t *num_samples, uint32_t seconds)
 {
@ -2189,9 +2196,11 @@ static int target_write_buffer_default(struct target *target,
 {
 	uint32_t size;
-	/* Align up to maximum 4 bytes. The loop condition makes sure the next pass
+	/* Align up to maximum bytes. The loop condition makes sure the next pass
 	 * will have something to do with the size we leave to it. */
-	for (size = 1; size < 4 && count >= size * 2 + (address & size); size *= 2) {
+	for (size = 1;
 			size < target_data_bits(target) / 8 && count >= size * 2 + (address & size);
 			size *= 2) {
 		if (address & size) {
 			int retval = target_write_memory(target, address, size, 1, buffer);
 			if (retval != ERROR_OK)
@ -2250,9 +2259,11 @@ static int target_read_buffer_default(struct target *target, target_addr_t addre
 {
 	uint32_t size;
-	/* Align up to maximum 4 bytes. The loop condition makes sure the next pass
+	/* Align up to maximum bytes. The loop condition makes sure the next pass
 	 * will have something to do with the size we leave to it. */
-	for (size = 1; size < 4 && count >= size * 2 + (address & size); size *= 2) {
+	for (size = 1;
 			size < target_data_bits(target) / 8 && count >= size * 2 + (address & size);
 			size *= 2) {
 		if (address & size) {
 			int retval = target_read_memory(target, address, size, 1, buffer);
 			if (retval != ERROR_OK)
--- a/src/target/target.h
+++ b/src/target/target.h
@ -664,6 +664,13 @@ target_addr_t target_address_max(struct target *target);
 */
 unsigned target_address_bits(struct target *target);
 /**
 * Return the number of data bits this target supports.
 *
 * This routine is a wrapper for target->type->data_bits.
 */
 unsigned target_data_bits(struct target *target);
 /** Return the *name* of this targets current state */
 const char *target_state_name(struct target *target);
--- a/src/target/target_type.h
+++ b/src/target/target_type.h
@ -296,6 +296,11 @@ struct target_type {
 	 * typically be 32 for 32-bit targets, and 64 for 64-bit targets. If not
 	 * implemented, it's assumed to be 32. */
 	unsigned (*address_bits)(struct target *target);
 	/* Return the number of data bits this target supports. This will
 	 * typically be 32 for 32-bit targets, and 64 for 64-bit targets. If not
 	 * implemented, it's assumed to be 32. */
 	unsigned (*data_bits)(struct target *target);
 };
 #endif /* OPENOCD_TARGET_TARGET_TYPE_H */