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authorTim Newsome <tim@sifive.com>2017-12-11 12:52:31 -0800
committerGitHub <noreply@github.com>2017-12-11 12:52:31 -0800
commite50ee46a6ff414b1af4f51290a92607295f693ff (patch)
tree7c5a74d4952437dfd8368f9bd7dbe29aff20687a /src
parent7a6704c5c6fe2570967bce7f0437db8c3a21179f (diff)
parent52cdf286cae5bf31b1d55730c5020b8920f79db2 (diff)
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Merge pull request #131 from riscv/small_progbuf
Support program buffers that are just 2 instructions large
Diffstat (limited to 'src')
-rw-r--r--src/target/riscv/batch.c3
-rw-r--r--src/target/riscv/debug_defines.h127
-rw-r--r--src/target/riscv/program.c401
-rw-r--r--src/target/riscv/program.h75
-rw-r--r--src/target/riscv/riscv-013.c1105
-rw-r--r--src/target/riscv/riscv.c72
-rw-r--r--src/target/riscv/riscv.h15
7 files changed, 780 insertions, 1018 deletions
diff --git a/src/target/riscv/batch.c b/src/target/riscv/batch.c
index 1e6a4be..1e6db42 100644
--- a/src/target/riscv/batch.c
+++ b/src/target/riscv/batch.c
@@ -49,13 +49,12 @@ void riscv_batch_run(struct riscv_batch *batch)
return;
}
- keep_alive();
+ keep_alive();
LOG_DEBUG("running a batch of %ld scans", (long)batch->used_scans);
riscv_batch_add_nop(batch);
for (size_t i = 0; i < batch->used_scans; ++i) {
- dump_field(batch->fields + i);
jtag_add_dr_scan(batch->target->tap, 1, batch->fields + i, TAP_IDLE);
if (batch->idle_count > 0)
jtag_add_runtest(batch->idle_count, TAP_IDLE);
diff --git a/src/target/riscv/debug_defines.h b/src/target/riscv/debug_defines.h
index 6e88a55..6067dbe 100644
--- a/src/target/riscv/debug_defines.h
+++ b/src/target/riscv/debug_defines.h
@@ -173,12 +173,6 @@
#define CSR_DCSR_EBREAKM_LENGTH 1
#define CSR_DCSR_EBREAKM (0x1U << CSR_DCSR_EBREAKM_OFFSET)
/*
-* When 1, {\tt ebreak} instructions in Hypervisor Mode enter Debug Mode.
- */
-#define CSR_DCSR_EBREAKH_OFFSET 14
-#define CSR_DCSR_EBREAKH_LENGTH 1
-#define CSR_DCSR_EBREAKH (0x1U << CSR_DCSR_EBREAKH_OFFSET)
-/*
* When 1, {\tt ebreak} instructions in Supervisor Mode enter Debug Mode.
*/
#define CSR_DCSR_EBREAKS_OFFSET 13
@@ -207,9 +201,10 @@
/*
* 0: Increment counters as usual.
*
-* 1: Don't increment any counters while in Debug Mode. This includes
-* the {\tt cycle} and {\tt instret} CSRs. This is preferred for most
-* debugging scenarios.
+* 1: Don't increment any counters while in Debug Mode or on {\tt
+* ebreak} instructions that cause entry into Debug Mode. These
+* counters include the {\tt cycle} and {\tt instret} CSRs. This is
+* preferred for most debugging scenarios.
*
* An implementation may choose not to support writing to this bit.
* The debugger must read back the value it writes to check whether
@@ -312,9 +307,9 @@
*
* This bit is only writable from Debug Mode.
*/
-#define CSR_TDATA1_HMODE_OFFSET XLEN-5
-#define CSR_TDATA1_HMODE_LENGTH 1
-#define CSR_TDATA1_HMODE (0x1ULL << CSR_TDATA1_HMODE_OFFSET)
+#define CSR_TDATA1_DMODE_OFFSET XLEN-5
+#define CSR_TDATA1_DMODE_LENGTH 1
+#define CSR_TDATA1_DMODE (0x1ULL << CSR_TDATA1_DMODE_OFFSET)
/*
* Trigger-specific data.
*/
@@ -390,7 +385,7 @@
* 0: Raise a breakpoint exception. (Used when software wants to use
* the trigger module without an external debugger attached.)
*
-* 1: Enter Debug Mode. (Only supported when \Fhmode is 1.)
+* 1: Enter Debug Mode. (Only supported when \Fdmode is 1.)
*
* 2: Start tracing.
*
@@ -532,7 +527,7 @@
* 0: Raise a breakpoint exception. (Used when software wants to use the
* trigger module without an external debugger attached.)
*
-* 1: Enter Debug Mode. (Only supported when \Fhmode is 1.)
+* 1: Enter Debug Mode. (Only supported when \Fdmode is 1.)
*
* 2: Start tracing.
*
@@ -549,6 +544,30 @@
#define CSR_ICOUNT_ACTION (0x3fULL << CSR_ICOUNT_ACTION_OFFSET)
#define DMI_DMSTATUS 0x11
/*
+* If 1, then there is an implicit {\tt ebreak} instruction at the
+* non-existent word immediately after the Program Buffer. This saves
+* the debugger from having to write the {\tt ebreak} itself, and
+* allows the Program Buffer to be one word smaller.
+*
+* This must be 1 when \Fprogbufsize is 1.
+ */
+#define DMI_DMSTATUS_IMPEBREAK_OFFSET 22
+#define DMI_DMSTATUS_IMPEBREAK_LENGTH 1
+#define DMI_DMSTATUS_IMPEBREAK (0x1U << DMI_DMSTATUS_IMPEBREAK_OFFSET)
+/*
+* Gets set if the Debug Module was accessed incorrectly.
+*
+* 0 (none): No error.
+*
+* 1 (badaddr): There was an access to an unimplemented Debug Module
+* address.
+*
+* 7 (other): An access failed for another reason.
+ */
+#define DMI_DMSTATUS_DMERR_OFFSET 18
+#define DMI_DMSTATUS_DMERR_LENGTH 3
+#define DMI_DMSTATUS_DMERR (0x7U << DMI_DMSTATUS_DMERR_OFFSET)
+/*
* This field is 1 when all currently selected harts have acknowledged the previous \Fresumereq.
*/
#define DMI_DMSTATUS_ALLRESUMEACK_OFFSET 17
@@ -629,6 +648,13 @@
#define DMI_DMSTATUS_AUTHBUSY_OFFSET 6
#define DMI_DMSTATUS_AUTHBUSY_LENGTH 1
#define DMI_DMSTATUS_AUTHBUSY (0x1U << DMI_DMSTATUS_AUTHBUSY_OFFSET)
+/*
+* 0: \Rdevtreeaddrzero--\Rdevtreeaddrthree hold information which
+* is not relevant to the Device Tree.
+*
+* 1: \Rdevtreeaddrzero--\Rdevtreeaddrthree registers hold the address of the
+* Device Tree.
+ */
#define DMI_DMSTATUS_DEVTREEVALID_OFFSET 4
#define DMI_DMSTATUS_DEVTREEVALID_LENGTH 1
#define DMI_DMSTATUS_DEVTREEVALID (0x1U << DMI_DMSTATUS_DEVTREEVALID_OFFSET)
@@ -654,7 +680,6 @@
*
* Writing 1 or 0 has no effect on a hart which is already halted, but
* the bit should be cleared to 0 before the hart is resumed.
-* Setting both \Fhaltreq and \Fresumereq leads to undefined behavior.
*
* Writes apply to the new value of \Fhartsel and \Fhasel.
*/
@@ -664,7 +689,8 @@
/*
* Resume request signal for all currently selected harts. When set to 1,
* each selected hart will resume if it is currently halted.
-* Setting both \Fhaltreq and \Fresumereq leads to undefined behavior.
+*
+* This bit is ignored while \Fhaltreq is set.
*
* Writes apply to the new value of \Fhartsel and \Fhasel.
*/
@@ -710,11 +736,12 @@
#define DMI_DMCONTROL_HARTSEL (0x3ffU << DMI_DMCONTROL_HARTSEL_OFFSET)
/*
* This bit controls the reset signal from the DM to the rest of the
-* system. To perform a system reset the debugger writes 1,
+* system. The signal should reset every part of the system, including
+* every hart, except for the DM and any logic required to access the
+* DM.
+* To perform a system reset the debugger writes 1,
* and then writes 0
-* to deassert the reset. This bit must not reset the Debug Module
-* registers. What it does reset is platform-specific (it may
-* reset nothing).
+* to deassert the reset.
*/
#define DMI_DMCONTROL_NDMRESET_OFFSET 1
#define DMI_DMCONTROL_NDMRESET_LENGTH 1
@@ -778,7 +805,7 @@
* shadowing the {\tt data} registers.
*
* If \Fdataaccess is 1: Signed address of RAM where the {\tt data}
-* registers are shadowed.
+* registers are shadowed, to be used to access relative to \Rzero.
*/
#define DMI_HARTINFO_DATAADDR_OFFSET 0
#define DMI_HARTINFO_DATAADDR_LENGTH 12
@@ -891,13 +918,10 @@
#define DMI_ABSTRACTCS 0x16
/*
* Size of the Program Buffer, in 32-bit words. Valid sizes are 0 - 16.
-*
-* TODO: Explain what can be done with each size of the buffer, to suggest
-* why you would want more or less words.
*/
-#define DMI_ABSTRACTCS_PROGSIZE_OFFSET 24
-#define DMI_ABSTRACTCS_PROGSIZE_LENGTH 5
-#define DMI_ABSTRACTCS_PROGSIZE (0x1fU << DMI_ABSTRACTCS_PROGSIZE_OFFSET)
+#define DMI_ABSTRACTCS_PROGBUFSIZE_OFFSET 24
+#define DMI_ABSTRACTCS_PROGBUFSIZE_LENGTH 5
+#define DMI_ABSTRACTCS_PROGBUFSIZE (0x1fU << DMI_ABSTRACTCS_PROGBUFSIZE_OFFSET)
/*
* 1: An abstract command is currently being executed.
*
@@ -1013,24 +1037,22 @@
*
* 4: 128-bit
*
-* If an unsupported system bus access size is written here,
-* the DM may not perform the access, or may perform the access
-* with any access size.
+* If an unsupported system bus access size is written here, the DM
+* does not perform the access and sberror is set to 3.
*/
#define DMI_SBCS_SBACCESS_OFFSET 17
#define DMI_SBCS_SBACCESS_LENGTH 3
#define DMI_SBCS_SBACCESS (0x7U << DMI_SBCS_SBACCESS_OFFSET)
/*
-* When 1, the internal address value (used by the system bus master)
-* is incremented by the access size (in bytes) selected in \Fsbaccess
-* after every system bus access.
+* When 1, {\tt sbaddress} is incremented by the access size (in
+* bytes) selected in \Fsbaccess after every system bus access.
*/
#define DMI_SBCS_SBAUTOINCREMENT_OFFSET 16
#define DMI_SBCS_SBAUTOINCREMENT_LENGTH 1
#define DMI_SBCS_SBAUTOINCREMENT (0x1U << DMI_SBCS_SBAUTOINCREMENT_OFFSET)
/*
-* When 1, every read from \Rsbdatazero automatically triggers a system
-* bus read at the new address.
+* When 1, every read from \Rsbdatazero automatically triggers a
+* system bus read at the (possibly auto-incremented) address.
*/
#define DMI_SBCS_SBAUTOREAD_OFFSET 15
#define DMI_SBCS_SBAUTOREAD_LENGTH 1
@@ -1052,8 +1074,7 @@
*
* 4: The system bus master was busy when one of the
* {\tt sbaddress} or {\tt sbdata} registers was written,
-* or the {\tt sbdata} register was read when it had
-* stale data.
+* or \Rsbdatazero was read when it had stale data.
*/
#define DMI_SBCS_SBERROR_OFFSET 12
#define DMI_SBCS_SBERROR_LENGTH 3
@@ -1097,54 +1118,54 @@
#define DMI_SBCS_SBACCESS8 (0x1U << DMI_SBCS_SBACCESS8_OFFSET)
#define DMI_SBADDRESS0 0x39
/*
-* Accesses bits 31:0 of the internal address.
+* Accesses bits 31:0 of the physical address in {\tt sbaddress}.
*/
#define DMI_SBADDRESS0_ADDRESS_OFFSET 0
#define DMI_SBADDRESS0_ADDRESS_LENGTH 32
#define DMI_SBADDRESS0_ADDRESS (0xffffffffU << DMI_SBADDRESS0_ADDRESS_OFFSET)
#define DMI_SBADDRESS1 0x3a
/*
-* Accesses bits 63:32 of the internal address (if the system address
-* bus is that wide).
+* Accesses bits 63:32 of the physical address in {\tt sbaddress} (if
+* the system address bus is that wide).
*/
#define DMI_SBADDRESS1_ADDRESS_OFFSET 0
#define DMI_SBADDRESS1_ADDRESS_LENGTH 32
#define DMI_SBADDRESS1_ADDRESS (0xffffffffU << DMI_SBADDRESS1_ADDRESS_OFFSET)
#define DMI_SBADDRESS2 0x3b
/*
-* Accesses bits 95:64 of the internal address (if the system address
-* bus is that wide).
+* Accesses bits 95:64 of the physical address in {\tt sbaddress} (if
+* the system address bus is that wide).
*/
#define DMI_SBADDRESS2_ADDRESS_OFFSET 0
#define DMI_SBADDRESS2_ADDRESS_LENGTH 32
#define DMI_SBADDRESS2_ADDRESS (0xffffffffU << DMI_SBADDRESS2_ADDRESS_OFFSET)
#define DMI_SBDATA0 0x3c
/*
-* Accesses bits 31:0 of the internal data.
+* Accesses bits 31:0 of {\tt sbdata}.
*/
#define DMI_SBDATA0_DATA_OFFSET 0
#define DMI_SBDATA0_DATA_LENGTH 32
#define DMI_SBDATA0_DATA (0xffffffffU << DMI_SBDATA0_DATA_OFFSET)
#define DMI_SBDATA1 0x3d
/*
-* Accesses bits 63:32 of the internal data (if the system bus is
-* that wide).
+* Accesses bits 63:32 of {\tt sbdata} (if the system bus is that
+* wide).
*/
#define DMI_SBDATA1_DATA_OFFSET 0
#define DMI_SBDATA1_DATA_LENGTH 32
#define DMI_SBDATA1_DATA (0xffffffffU << DMI_SBDATA1_DATA_OFFSET)
#define DMI_SBDATA2 0x3e
/*
-* Accesses bits 95:64 of the internal data (if the system bus is
-* that wide).
+* Accesses bits 95:64 of {\tt sbdata} (if the system bus is that
+* wide).
*/
#define DMI_SBDATA2_DATA_OFFSET 0
#define DMI_SBDATA2_DATA_LENGTH 32
#define DMI_SBDATA2_DATA (0xffffffffU << DMI_SBDATA2_DATA_OFFSET)
#define DMI_SBDATA3 0x3f
/*
-* Accesses bits 127:96 of the internal data (if the system bus is
-* that wide).
+* Accesses bits 127:96 of {\tt sbdata} (if the system bus is that
+* wide).
*/
#define DMI_SBDATA3_DATA_OFFSET 0
#define DMI_SBDATA3_DATA_LENGTH 32
@@ -1188,6 +1209,9 @@
* 0: Don't do the operation specified by \Fwrite.
*
* 1: Do the operation specified by \Fwrite.
+*
+* This bit can be used to just execute the Program Buffer without
+* having to worry about placing valid values into \Fsize or \Fregno.
*/
#define AC_ACCESS_REGISTER_TRANSFER_OFFSET 17
#define AC_ACCESS_REGISTER_TRANSFER_LENGTH 1
@@ -1223,8 +1247,9 @@
/*
* Contains the privilege level the hart was operating in when Debug
* Mode was entered. The encoding is described in Table
-* \ref{tab:privlevel}. A user can write this value to change the
-* hart's privilege level when exiting Debug Mode.
+* \ref{tab:privlevel}, and matches the privilege level encoding from
+* the RISC-V Privileged ISA Specification. A user can write this
+* value to change the hart's privilege level when exiting Debug Mode.
*/
#define VIRT_PRIV_PRV_OFFSET 0
#define VIRT_PRIV_PRV_LENGTH 2
diff --git a/src/target/riscv/program.c b/src/target/riscv/program.c
index d052574..e7238dd 100644
--- a/src/target/riscv/program.c
+++ b/src/target/riscv/program.c
@@ -11,44 +11,39 @@
#include "asm.h"
#include "encoding.h"
-riscv_addr_t riscv_program_gal(struct riscv_program *p, riscv_addr_t addr);
-int riscv_program_lah(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-int riscv_program_lal(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-
/* Program interface. */
int riscv_program_init(struct riscv_program *p, struct target *target)
{
memset(p, 0, sizeof(*p));
p->target = target;
p->instruction_count = 0;
- p->data_count = 0;
- p->writes_memory = 0;
p->target_xlen = riscv_xlen(target);
for (size_t i = 0; i < RISCV_REGISTER_COUNT; ++i) {
p->writes_xreg[i] = 0;
- p->in_use[i] = 0;
}
for(size_t i = 0; i < RISCV_MAX_DEBUG_BUFFER_SIZE; ++i)
p->debug_buffer[i] = -1;
- if (riscv_debug_buffer_enter(target, p) != ERROR_OK) {
- LOG_ERROR("unable to write progam buffer enter code");
- return ERROR_FAIL;
- }
+ return ERROR_OK;
+}
+int riscv_program_write(struct riscv_program *program)
+{
+ for (unsigned i = 0; i < program->instruction_count; ++i) {
+ LOG_DEBUG("%p: debug_buffer[%02x] = DASM(0x%08x)", program, i, program->debug_buffer[i]);
+ if (riscv_write_debug_buffer(program->target, i,
+ program->debug_buffer[i]) != ERROR_OK)
+ return ERROR_FAIL;
+ }
return ERROR_OK;
}
+/** Add ebreak and execute the program. */
int riscv_program_exec(struct riscv_program *p, struct target *t)
{
keep_alive();
- if (riscv_debug_buffer_leave(t, p) != ERROR_OK) {
- LOG_ERROR("unable to write program buffer exit code");
- return ERROR_FAIL;
- }
-
riscv_reg_t saved_registers[GDB_REGNO_XPR31 + 1];
for (size_t i = GDB_REGNO_XPR0 + 1; i <= GDB_REGNO_XPR31; ++i) {
if (p->writes_xreg[i]) {
@@ -57,14 +52,6 @@ int riscv_program_exec(struct riscv_program *p, struct target *t)
}
}
- if (p->writes_memory && (riscv_program_fence(p) != ERROR_OK)) {
- LOG_ERROR("Unable to write fence");
- for(size_t i = 0; i < riscv_debug_buffer_size(p->target); ++i)
- LOG_ERROR("ram[%02x]: DASM(0x%08lx) [0x%08lx]", (int)i, (long)p->debug_buffer[i], (long)p->debug_buffer[i]);
- abort();
- return ERROR_FAIL;
- }
-
if (riscv_program_ebreak(p) != ERROR_OK) {
LOG_ERROR("Unable to write ebreak");
for(size_t i = 0; i < riscv_debug_buffer_size(p->target); ++i)
@@ -73,16 +60,8 @@ int riscv_program_exec(struct riscv_program *p, struct target *t)
return ERROR_FAIL;
}
- for (unsigned i = 0; i < riscv_debug_buffer_size(p->target); ++i) {
- if (i < p->instruction_count) {
- LOG_DEBUG("%p: debug_buffer[%02x] = DASM(0x%08x)", p, i, p->debug_buffer[i]);
- riscv_write_debug_buffer(t, i, p->debug_buffer[i]);
- }
- if (i >= riscv_debug_buffer_size(p->target) - p->data_count) {
- LOG_DEBUG("%p: debug_buffer[%02x] = 0x%08x", p, i, p->debug_buffer[i]);
- riscv_write_debug_buffer(t, i, p->debug_buffer[i]);
- }
- }
+ if (riscv_program_write(p) != ERROR_OK)
+ return ERROR_FAIL;
if (riscv_execute_debug_buffer(t) != ERROR_OK) {
LOG_ERROR("Unable to execute program %p", p);
@@ -90,7 +69,7 @@ int riscv_program_exec(struct riscv_program *p, struct target *t)
}
for (size_t i = 0; i < riscv_debug_buffer_size(p->target); ++i)
- if (i >= riscv_debug_buffer_size(p->target) - p->data_count)
+ if (i >= riscv_debug_buffer_size(p->target))
p->debug_buffer[i] = riscv_read_debug_buffer(t, i);
for (size_t i = GDB_REGNO_XPR0; i <= GDB_REGNO_XPR31; ++i)
@@ -100,236 +79,39 @@ int riscv_program_exec(struct riscv_program *p, struct target *t)
return ERROR_OK;
}
-riscv_addr_t riscv_program_alloc_data(struct riscv_program *p, size_t bytes)
-{
- riscv_addr_t addr =
- riscv_debug_buffer_addr(p->target)
- + riscv_debug_buffer_size(p->target) * sizeof(p->debug_buffer[0])
- - p->data_count * sizeof(p->debug_buffer[0])
- - bytes;
- while (addr % bytes != 0) addr--;
-
- riscv_addr_t ptop =
- riscv_debug_buffer_addr(p->target)
- + p->instruction_count * sizeof(p->debug_buffer[0]);
-
- if (addr <= ptop) {
- LOG_ERROR("unable to allocate %d bytes", (int)bytes);
- return RISCV_PROGRAM_ALLOC_FAIL;
- }
-
- p->data_count =
- + riscv_debug_buffer_size(p->target)
- - (addr - riscv_debug_buffer_addr(p->target)) / sizeof(p->debug_buffer[0]);
- return addr;
-}
-
-riscv_addr_t riscv_program_alloc_x(struct riscv_program *p)
-{
- return riscv_program_alloc_data(p, p->target_xlen / 8);
-}
-
-riscv_addr_t riscv_program_alloc_d(struct riscv_program *p)
-{
- return riscv_program_alloc_data(p, 8);
-}
-
-riscv_addr_t riscv_program_alloc_w(struct riscv_program *p)
-{
- return riscv_program_alloc_data(p, 4);
-}
-
-riscv_addr_t riscv_program_alloc_h(struct riscv_program *p)
-{
- return riscv_program_alloc_data(p, 2);
-}
-
-riscv_addr_t riscv_program_alloc_b(struct riscv_program *p)
-{
- return riscv_program_alloc_data(p, 1);
-}
-
-riscv_insn_t riscv_program_read_ram(struct riscv_program *p, riscv_addr_t addr)
-{
- if (addr < riscv_debug_buffer_addr(p->target))
- return -1;
- if ((size_t)addr > riscv_debug_buffer_addr(p->target) + (riscv_debug_buffer_size(p->target) * sizeof(p->debug_buffer[0])))
- return -1;
-
- int off = (addr - riscv_debug_buffer_addr(p->target)) / sizeof(p->debug_buffer[0]);
- return p->debug_buffer[off];
-}
-
-void riscv_program_write_ram(struct riscv_program *p, riscv_addr_t addr, uint64_t d)
-{
- if (addr < riscv_debug_buffer_addr(p->target))
- return;
- if ((size_t)addr > riscv_debug_buffer_addr(p->target) + (riscv_debug_buffer_size(p->target) * sizeof(p->debug_buffer[0])))
- return;
-
- int off = (addr - riscv_debug_buffer_addr(p->target)) / sizeof(p->debug_buffer[0]);
- p->debug_buffer[off] = d;
-}
-
int riscv_program_swr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
{
- p->writes_memory = 1;
return riscv_program_insert(p, sw(d, b, offset));
}
int riscv_program_shr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
{
- p->writes_memory = 1;
return riscv_program_insert(p, sh(d, b, offset));
}
int riscv_program_sbr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
{
- p->writes_memory = 1;
return riscv_program_insert(p, sb(d, b, offset));
}
int riscv_program_lwr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
{
- p->writes_memory = 1;
return riscv_program_insert(p, lw(d, b, offset));
}
int riscv_program_lhr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
{
- p->writes_memory = 1;
return riscv_program_insert(p, lh(d, b, offset));
}
int riscv_program_lbr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno b, int offset)
{
- p->writes_memory = 1;
return riscv_program_insert(p, lb(d, b, offset));
}
-int riscv_program_lx(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- switch (p->target_xlen) {
- case 64: return riscv_program_ld(p, d, addr);
- case 32: return riscv_program_lw(p, d, addr);
- }
-
- LOG_ERROR("unknown xlen %d", p->target_xlen);
- abort();
- return -1;
-}
-
-int riscv_program_ld(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0 ? GDB_REGNO_X0 : d;
- if (riscv_program_lah(p, d, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, ld(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- return ERROR_OK;
-}
-
-int riscv_program_lw(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0 ? GDB_REGNO_X0 : d;
- if (riscv_program_lah(p, d, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, lw(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- return ERROR_OK;
-}
-
-int riscv_program_lh(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0 ? GDB_REGNO_X0 : d;
- if (riscv_program_lah(p, d, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, lh(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- return ERROR_OK;
-}
-
-int riscv_program_lb(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0 ? GDB_REGNO_X0 : d;
- if (riscv_program_lah(p, t, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, lb(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- return ERROR_OK;
-}
-
-int riscv_program_sx(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- switch (p->target_xlen) {
- case 64: return riscv_program_sd(p, d, addr);
- case 32: return riscv_program_sw(p, d, addr);
- }
-
- LOG_ERROR("unknown xlen %d", p->target_xlen);
- abort();
- return -1;
-}
-
-int riscv_program_sd(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0
- ? GDB_REGNO_X0
- : riscv_program_gettemp(p);
- if (riscv_program_lah(p, t, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, sd(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- riscv_program_puttemp(p, t);
- p->writes_memory = true;
- return ERROR_OK;
-}
-
-int riscv_program_sw(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0
- ? GDB_REGNO_X0
- : riscv_program_gettemp(p);
- if (riscv_program_lah(p, t, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, sw(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- riscv_program_puttemp(p, t);
- p->writes_memory = true;
- return ERROR_OK;
-}
-
-int riscv_program_sh(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0
- ? GDB_REGNO_X0
- : riscv_program_gettemp(p);
- if (riscv_program_lah(p, t, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, sh(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- riscv_program_puttemp(p, t);
- p->writes_memory = true;
- return ERROR_OK;
-}
-
-int riscv_program_sb(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- enum gdb_regno t = riscv_program_gah(p, addr) == 0
- ? GDB_REGNO_X0
- : riscv_program_gettemp(p);
- if (riscv_program_lah(p, t, addr) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_insert(p, sb(d, t, riscv_program_gal(p, addr))) != ERROR_OK)
- return ERROR_FAIL;
- riscv_program_puttemp(p, t);
- p->writes_memory = true;
- return ERROR_OK;
-}
-
int riscv_program_csrr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno csr)
{
- assert(csr >= GDB_REGNO_CSR0);
+ assert(csr >= GDB_REGNO_CSR0 && csr <= GDB_REGNO_CSR4095);
return riscv_program_insert(p, csrrs(d, GDB_REGNO_X0, csr - GDB_REGNO_CSR0));
}
@@ -339,12 +121,6 @@ int riscv_program_csrw(struct riscv_program *p, enum gdb_regno s, enum gdb_regno
return riscv_program_insert(p, csrrw(GDB_REGNO_X0, s, csr - GDB_REGNO_CSR0));
}
-int riscv_program_csrrw(struct riscv_program *p, enum gdb_regno d, enum gdb_regno s, enum gdb_regno csr)
-{
- assert(csr >= GDB_REGNO_CSR0);
- return riscv_program_insert(p, csrrw(d, s, csr - GDB_REGNO_CSR0));
-}
-
int riscv_program_fence_i(struct riscv_program *p)
{
return riscv_program_insert(p, fence_i());
@@ -357,158 +133,27 @@ int riscv_program_fence(struct riscv_program *p)
int riscv_program_ebreak(struct riscv_program *p)
{
+ struct target *target = p->target;
+ RISCV_INFO(r);
+ if (p->instruction_count == riscv_debug_buffer_size(p->target) &&
+ r->impebreak) {
+ return ERROR_OK;
+ }
return riscv_program_insert(p, ebreak());
}
-int riscv_program_lui(struct riscv_program *p, enum gdb_regno d, int32_t u)
-{
- return riscv_program_insert(p, lui(d, u));
-}
-
int riscv_program_addi(struct riscv_program *p, enum gdb_regno d, enum gdb_regno s, int16_t u)
{
return riscv_program_insert(p, addi(d, s, u));
}
-int riscv_program_fsx(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- assert(d >= GDB_REGNO_FPR0);
- assert(d <= GDB_REGNO_FPR31);
- enum gdb_regno t = riscv_program_gah(p, addr) == 0
- ? GDB_REGNO_X0
- : riscv_program_gettemp(p);
- if (riscv_program_lah(p, t, addr) != ERROR_OK)
- return ERROR_FAIL;
- uint32_t instruction;
- switch (p->target->reg_cache->reg_list[GDB_REGNO_FPR0].size) {
- case 64:
- instruction = fsd(d - GDB_REGNO_FPR0, t, riscv_program_gal(p, addr));
- break;
- case 32:
- instruction = fsw(d - GDB_REGNO_FPR0, t, riscv_program_gal(p, addr));
- break;
- default:
- return ERROR_FAIL;
- }
- if (riscv_program_insert(p, instruction) != ERROR_OK)
- return ERROR_FAIL;
- riscv_program_puttemp(p, t);
- p->writes_memory = true;
- return ERROR_OK;
-}
-
-int riscv_program_flx(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- assert(d >= GDB_REGNO_FPR0);
- assert(d <= GDB_REGNO_FPR31);
- enum gdb_regno t = riscv_program_gah(p, addr) == 0 ? GDB_REGNO_X0 : d;
- if (riscv_program_lah(p, t, addr) != ERROR_OK)
- return ERROR_FAIL;
- uint32_t instruction;
- switch (p->target->reg_cache->reg_list[GDB_REGNO_FPR0].size) {
- case 64:
- instruction = fld(d - GDB_REGNO_FPR0, t, riscv_program_gal(p, addr));
- break;
- case 32:
- instruction = flw(d - GDB_REGNO_FPR0, t, riscv_program_gal(p, addr));
- break;
- default:
- return ERROR_FAIL;
- }
- if (riscv_program_insert(p, instruction) != ERROR_OK)
- return ERROR_FAIL;
- return ERROR_OK;
-}
-
-int riscv_program_li(struct riscv_program *p, enum gdb_regno d, riscv_reg_t c)
-{
- if (riscv_program_lui(p, d, c >> 12) != ERROR_OK)
- return ERROR_FAIL;
- if (riscv_program_addi(p, d, d, c & 0xFFF) != ERROR_OK)
- return ERROR_FAIL;
- return ERROR_OK;
-}
-
-int riscv_program_dont_restore_register(struct riscv_program *p, enum gdb_regno r)
-{
- assert(r < RISCV_REGISTER_COUNT);
- p->writes_xreg[r] = 0;
- return ERROR_OK;
-}
-
-int riscv_program_do_restore_register(struct riscv_program *p, enum gdb_regno r)
-{
- assert(r < RISCV_REGISTER_COUNT);
- p->writes_xreg[r] = 1;
- return ERROR_OK;
-}
-
-void riscv_program_reserve_register(struct riscv_program *p, enum gdb_regno r)
-{
- assert(r < RISCV_REGISTER_COUNT);
- assert(p->in_use[r] == 0);
- p->in_use[r] = 1;
-}
-
-enum gdb_regno riscv_program_gettemp(struct riscv_program *p)
-{
- for (size_t i = GDB_REGNO_S0; i <= GDB_REGNO_XPR31; ++i) {
- if (p->in_use[i]) continue;
-
- riscv_program_do_restore_register(p, i);
- p->in_use[i] = 1;
- return i;
- }
-
- LOG_ERROR("You've run out of temporary registers. This is impossible.");
- abort();
-}
-
-void riscv_program_puttemp(struct riscv_program *p, enum gdb_regno r)
-{
- assert(r < RISCV_REGISTER_COUNT);
- p->in_use[r] = 0;
-}
-
-/* Helper functions. */
-riscv_addr_t riscv_program_gah(struct riscv_program *p, riscv_addr_t addr)
-{
- return addr >> 12;
-}
-
-riscv_addr_t riscv_program_gal(struct riscv_program *p, riscv_addr_t addr)
-{
- if (addr > 0) {
- return (addr & 0x7FF);
- } else {
- return 0;
- }
-}
-
-int riscv_program_lah(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- riscv_addr_t ah = riscv_program_gah(p, addr);
- if (ah == 0)
- return ERROR_OK;
- return riscv_program_lui(p, d, ah);
-}
-
-int riscv_program_lal(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr)
-{
- riscv_addr_t al = riscv_program_gal(p, addr);
- if (al == 0)
- return ERROR_OK;
- return riscv_program_addi(p, d, d, al);
-}
-
int riscv_program_insert(struct riscv_program *p, riscv_insn_t i)
{
- if (p->instruction_count + p->data_count + 1 > riscv_debug_buffer_size(p->target)) {
+ if (p->instruction_count >= riscv_debug_buffer_size(p->target)) {
LOG_ERROR("Unable to insert instruction:");
LOG_ERROR(" instruction_count=%d", (int)p->instruction_count);
- LOG_ERROR(" data_count =%d", (int)p->data_count);
LOG_ERROR(" buffer size =%d", (int)riscv_debug_buffer_size(p->target));
- return ERROR_FAIL;
+ abort();
}
p->debug_buffer[p->instruction_count] = i;
diff --git a/src/target/riscv/program.h b/src/target/riscv/program.h
index ac1127e..d641be1 100644
--- a/src/target/riscv/program.h
+++ b/src/target/riscv/program.h
@@ -15,23 +15,12 @@ struct riscv_program {
uint32_t debug_buffer[RISCV_MAX_DEBUG_BUFFER_SIZE];
- /* The debug buffer is allocated in two directions: instructions go at
- * the start, while data goes at the end. When they meet in the middle
- * this blows up. */
+ /* Number of 32-bit instructions in the program. */
size_t instruction_count;
- size_t data_count;
/* Side effects of executing this program. These must be accounted for
* in order to maintain correct executing of the target system. */
bool writes_xreg[RISCV_REGISTER_COUNT];
- bool writes_memory;
-
- /* When a register is used it will be set in this array. */
- bool in_use[RISCV_REGISTER_COUNT];
-
- /* Remembers the registers that have been saved into dscratch
- * registers. These are restored */
- enum gdb_regno dscratch_saved[RISCV_DSCRATCH_COUNT];
/* XLEN on the target. */
int target_xlen;
@@ -40,6 +29,9 @@ struct riscv_program {
/* Initializes a program with the header. */
int riscv_program_init(struct riscv_program *p, struct target *t);
+/* Write the program to the program buffer. */
+int riscv_program_write(struct riscv_program *program);
+
/* Executes a program, returning 0 if the program successfully executed. Note
* that this may cause registers to be saved or restored, which could result to
* calls to things like riscv_save_register which itself could require a
@@ -60,83 +52,24 @@ int riscv_program_insert(struct riscv_program *p, riscv_insn_t i);
* memory. */
int riscv_program_save_to_dscratch(struct riscv_program *p, enum gdb_regno to_save);
-/* Allocates data of various sizes. Either returns the absolute physical
- * address or RISCV_PROGRAM_ALLOC_FAIL on failure. */
-riscv_addr_t riscv_program_alloc_data(struct riscv_program *p, size_t bytes);
-riscv_addr_t riscv_program_alloc_x(struct riscv_program *p);
-riscv_addr_t riscv_program_alloc_d(struct riscv_program *p);
-riscv_addr_t riscv_program_alloc_w(struct riscv_program *p);
-riscv_addr_t riscv_program_alloc_h(struct riscv_program *p);
-riscv_addr_t riscv_program_alloc_b(struct riscv_program *p);
-#define RISCV_PROGRAM_ALLOC_FAIL ((riscv_addr_t)(-1))
-
-/* Reads a word of memory from this program's internal view of the debug RAM.
- * This is what you want to use to get data back from the program after it
- * executes. */
-riscv_insn_t riscv_program_read_ram(struct riscv_program *p, riscv_addr_t addr);
-void riscv_program_write_ram(struct riscv_program *p, riscv_addr_t a, uint64_t d);
-
/* Helpers to assembly various instructions. Return 0 on success. These might
* assembly into a multi-instruction sequence that overwrites some other
* register, but those will be properly saved and restored. */
-int riscv_program_lx(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-int riscv_program_ld(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-int riscv_program_lw(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-int riscv_program_lh(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-int riscv_program_lb(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-
-int riscv_program_sx(struct riscv_program *p, enum gdb_regno s, riscv_addr_t addr);
-int riscv_program_sd(struct riscv_program *p, enum gdb_regno s, riscv_addr_t addr);
-int riscv_program_sw(struct riscv_program *p, enum gdb_regno s, riscv_addr_t addr);
-int riscv_program_sh(struct riscv_program *p, enum gdb_regno s, riscv_addr_t addr);
-int riscv_program_sb(struct riscv_program *p, enum gdb_regno s, riscv_addr_t addr);
-
-int riscv_program_lxr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno a, int o);
-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_sxr(struct riscv_program *p, enum gdb_regno s, 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);
int riscv_program_csrr(struct riscv_program *p, enum gdb_regno d, enum gdb_regno csr);
int riscv_program_csrw(struct riscv_program *p, enum gdb_regno s, enum gdb_regno csr);
-int riscv_program_csrrw(struct riscv_program *p, enum gdb_regno d, enum gdb_regno s, enum gdb_regno csr);
int riscv_program_fence_i(struct riscv_program *p);
int riscv_program_fence(struct riscv_program *p);
int riscv_program_ebreak(struct riscv_program *p);
-int riscv_program_lui(struct riscv_program *p, enum gdb_regno d, int32_t u);
int riscv_program_addi(struct riscv_program *p, enum gdb_regno d, enum gdb_regno s, int16_t i);
-int riscv_program_fsx(struct riscv_program *p, enum gdb_regno s, riscv_addr_t addr);
-int riscv_program_flx(struct riscv_program *p, enum gdb_regno d, riscv_addr_t addr);
-
-/* Assembler macros. */
-int riscv_program_li(struct riscv_program *p, enum gdb_regno d, riscv_reg_t c);
-int riscv_program_la(struct riscv_program *p, enum gdb_regno d, riscv_addr_t a);
-
-/* Register allocation. The user is expected to have obtained temporary
- * registers using these fuctions. Additionally, there is an interface for
- * reserving registers -- it's expected that this has been called as the first
- * thing in the program's execution to reserve registers that can't be touched
- * by the program's execution. */
-void riscv_program_reserve_register(struct riscv_program *p, enum gdb_regno r);
-enum gdb_regno riscv_program_gettemp(struct riscv_program *p);
-void riscv_program_puttemp(struct riscv_program *p, enum gdb_regno r);
-
-/* Executing a program usually causes the registers that get overwritten to be
- * saved and restored. Calling this prevents the given register from actually
- * being restored as a result of all activity in this program. */
-int riscv_program_dont_restore_register(struct riscv_program *p, enum gdb_regno r);
-int riscv_program_do_restore_register(struct riscv_program *p, enum gdb_regno r);
-
-/* Addressing functions. */
-riscv_addr_t riscv_program_gah(struct riscv_program *p, riscv_addr_t addr);
-
#endif
diff --git a/src/target/riscv/riscv-013.c b/src/target/riscv/riscv-013.c
index 4ab9a2e..1768b62 100644
--- a/src/target/riscv/riscv-013.c
+++ b/src/target/riscv/riscv-013.c
@@ -28,16 +28,10 @@
#include "batch.h"
#define DMI_DATA1 (DMI_DATA0 + 1)
+#define DMI_PROGBUF1 (DMI_PROGBUF0 + 1)
static void riscv013_on_step_or_resume(struct target *target, bool step);
static void riscv013_step_or_resume_current_hart(struct target *target, bool step);
-static riscv_addr_t riscv013_progbuf_addr(struct target *target);
-static riscv_addr_t riscv013_progbuf_size(struct target *target);
-static riscv_addr_t riscv013_data_size(struct target *target);
-static riscv_addr_t riscv013_data_addr(struct target *target);
-static void riscv013_set_autoexec(struct target *target, unsigned index,
- bool enabled);
-static int riscv013_debug_buffer_register(struct target *target, riscv_addr_t addr);
static void riscv013_clear_abstract_error(struct target *target);
/* Implementations of the functions in riscv_info_t. */
@@ -52,8 +46,6 @@ static void riscv013_on_step(struct target *target);
static void riscv013_on_resume(struct target *target);
static bool riscv013_is_halted(struct target *target);
static enum riscv_halt_reason riscv013_halt_reason(struct target *target);
-static void riscv013_debug_buffer_enter(struct target *target, struct riscv_program *p);
-static void riscv013_debug_buffer_leave(struct target *target, struct riscv_program *p);
static void riscv013_write_debug_buffer(struct target *target, unsigned index,
riscv_insn_t d);
static riscv_insn_t riscv013_read_debug_buffer(struct target *target, unsigned
@@ -63,6 +55,13 @@ static void riscv013_fill_dmi_write_u64(struct target *target, char *buf, int a,
static void riscv013_fill_dmi_read_u64(struct target *target, char *buf, int a);
static int riscv013_dmi_write_u64_bits(struct target *target);
static void riscv013_fill_dmi_nop_u64(struct target *target, char *buf);
+static int register_read_direct(struct target *target, uint64_t *value, uint32_t number);
+static int register_write_direct(struct target *target, unsigned number,
+ uint64_t value);
+static int read_memory(struct target *target, target_addr_t address,
+ uint32_t size, uint32_t count, uint8_t *buffer);
+static int write_memory(struct target *target, target_addr_t address,
+ uint32_t size, uint32_t count, const uint8_t *buffer);
/**
* Since almost everything can be accomplish by scanning the dbus register, all
@@ -135,18 +134,28 @@ struct memory_cache_line {
bool dirty;
};
+typedef enum {
+ YNM_MAYBE,
+ YNM_YES,
+ YNM_NO
+} yes_no_maybe_t;
+
typedef struct {
/* Number of address bits in the dbus register. */
unsigned abits;
/* Number of abstract command data registers. */
unsigned datacount;
/* Number of words in the Program Buffer. */
- unsigned progsize;
+ unsigned progbufsize;
/* The value that mstatus actually has on the target right now. This is not
* the value we present to the user. That one may be stored in the
* reg_cache. */
uint64_t mstatus_actual;
+ yes_no_maybe_t progbuf_writable;
+ /* We only need the address so that we know the alignment of the buffer. */
+ riscv_addr_t progbuf_address;
+
/* Single buffer that contains all register names, instead of calling
* malloc for each register. Needs to be freed when reg_list is freed. */
char *reg_names;
@@ -171,9 +180,6 @@ typedef struct {
bool need_strict_step;
- // Some memoized values
- int progbuf_size, progbuf_addr, data_addr, data_size;
-
bool abstract_read_csr_supported;
bool abstract_write_csr_supported;
bool abstract_read_fpr_supported;
@@ -182,7 +188,12 @@ typedef struct {
// When a function returns some error due to a failure indicated by the
// target in cmderr, the caller can look here to see what that error was.
// (Compare with errno.)
- unsigned cmderr;
+ uint8_t cmderr;
+
+ // Some fields from hartinfo.
+ uint8_t datasize;
+ uint8_t dataaccess;
+ int16_t dataaddr;
} riscv013_info_t;
static void decode_dmi(char *text, unsigned address, unsigned data)
@@ -200,6 +211,7 @@ static void decode_dmi(char *text, unsigned address, unsigned data)
{ DMI_DMCONTROL, DMI_DMCONTROL_NDMRESET, "ndmreset" },
{ DMI_DMCONTROL, DMI_DMCONTROL_DMACTIVE, "dmactive" },
+ { DMI_DMSTATUS, DMI_DMSTATUS_IMPEBREAK, "impebreak" },
{ DMI_DMSTATUS, DMI_DMSTATUS_ALLRESUMEACK, "allresumeack" },
{ DMI_DMSTATUS, DMI_DMSTATUS_ANYRESUMEACK, "anyresumeack" },
{ DMI_DMSTATUS, DMI_DMSTATUS_ALLNONEXISTENT, "allnonexistent" },
@@ -215,7 +227,7 @@ static void decode_dmi(char *text, unsigned address, unsigned data)
{ DMI_DMSTATUS, DMI_DMSTATUS_DEVTREEVALID, "devtreevalid" },
{ DMI_DMSTATUS, DMI_DMSTATUS_VERSION, "version" },
- { DMI_ABSTRACTCS, DMI_ABSTRACTCS_PROGSIZE, "progsize" },
+ { DMI_ABSTRACTCS, DMI_ABSTRACTCS_PROGBUFSIZE, "progbufsize" },
{ DMI_ABSTRACTCS, DMI_ABSTRACTCS_BUSY, "busy" },
{ DMI_ABSTRACTCS, DMI_ABSTRACTCS_CMDERR, "cmderr" },
{ DMI_ABSTRACTCS, DMI_ABSTRACTCS_DATACOUNT, "datacount" },
@@ -635,11 +647,12 @@ static int write_abstract_arg(struct target *target, unsigned index,
return ERROR_OK;
}
-static int register_read_abstract(struct target *target, uint64_t *value,
- uint32_t number, unsigned size)
+/**
+ * @size in bits
+ */
+static uint32_t access_register_command(uint32_t number, unsigned size,
+ uint32_t flags)
{
- RISCV013_INFO(r);
-
uint32_t command = set_field(0, DMI_COMMAND_CMDTYPE, 0);
switch (size) {
case 32:
@@ -649,45 +662,58 @@ static int register_read_abstract(struct target *target, uint64_t *value,
command = set_field(command, AC_ACCESS_REGISTER_SIZE, 3);
break;
default:
- LOG_ERROR("Unsupported abstract register read size: %d", size);
- return ERROR_FAIL;
+ assert(0);
}
- command = set_field(command, AC_ACCESS_REGISTER_POSTEXEC, 0);
- command = set_field(command, AC_ACCESS_REGISTER_TRANSFER, 1);
- command = set_field(command, AC_ACCESS_REGISTER_WRITE, 0);
if (number <= GDB_REGNO_XPR31) {
command = set_field(command, AC_ACCESS_REGISTER_REGNO,
0x1000 + number - GDB_REGNO_XPR0);
} else if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31) {
- if (!r->abstract_read_fpr_supported)
- return ERROR_FAIL;
command = set_field(command, AC_ACCESS_REGISTER_REGNO,
0x1020 + number - GDB_REGNO_FPR0);
} else if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095) {
- if (!r->abstract_read_csr_supported)
- return ERROR_FAIL;
command = set_field(command, AC_ACCESS_REGISTER_REGNO,
number - GDB_REGNO_CSR0);
} else {
- return ERROR_FAIL;
+ assert(0);
}
+ command |= flags;
+
+ return command;
+}
+
+static int register_read_abstract(struct target *target, uint64_t *value,
+ uint32_t number, unsigned size)
+{
+ RISCV013_INFO(info);
+
+ if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31 &&
+ !info->abstract_read_fpr_supported)
+ return ERROR_FAIL;
+ if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095 &&
+ !info->abstract_read_csr_supported)
+ return ERROR_FAIL;
+
+ uint32_t command = access_register_command(number, size,
+ AC_ACCESS_REGISTER_TRANSFER);
+
int result = execute_abstract_command(target, command);
if (result != ERROR_OK) {
- if (r->cmderr == CMDERR_NOT_SUPPORTED) {
+ if (info->cmderr == CMDERR_NOT_SUPPORTED) {
if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31) {
- r->abstract_read_fpr_supported = false;
+ info->abstract_read_fpr_supported = false;
LOG_INFO("Disabling abstract command reads from FPRs.");
} else if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095) {
- r->abstract_read_csr_supported = false;
+ info->abstract_read_csr_supported = false;
LOG_INFO("Disabling abstract command reads from CSRs.");
}
}
return result;
}
- *value = read_abstract_arg(target, 0);
+ if (value)
+ *value = read_abstract_arg(target, 0);
return ERROR_OK;
}
@@ -697,38 +723,16 @@ static int register_write_abstract(struct target *target, uint32_t number,
{
RISCV013_INFO(info);
- uint32_t command = set_field(0, DMI_COMMAND_CMDTYPE, 0);
- switch (size) {
- case 32:
- command = set_field(command, AC_ACCESS_REGISTER_SIZE, 2);
- break;
- case 64:
- command = set_field(command, AC_ACCESS_REGISTER_SIZE, 3);
- break;
- default:
- LOG_ERROR("Unsupported abstract register read size: %d", size);
- return ERROR_FAIL;
- }
- command = set_field(command, AC_ACCESS_REGISTER_POSTEXEC, 0);
- command = set_field(command, AC_ACCESS_REGISTER_TRANSFER, 1);
- command = set_field(command, AC_ACCESS_REGISTER_WRITE, 1);
-
- if (number <= GDB_REGNO_XPR31) {
- command = set_field(command, AC_ACCESS_REGISTER_REGNO,
- 0x1000 + number - GDB_REGNO_XPR0);
- } else if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31) {
- if (!info->abstract_read_fpr_supported)
- return ERROR_FAIL;
- command = set_field(command, AC_ACCESS_REGISTER_REGNO,
- 0x1020 + number - GDB_REGNO_FPR0);
- } else if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095) {
- if (!info->abstract_read_csr_supported)
- return ERROR_FAIL;
- command = set_field(command, AC_ACCESS_REGISTER_REGNO,
- number - GDB_REGNO_CSR0);
- } else {
+ if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31 &&
+ !info->abstract_write_fpr_supported)
+ return ERROR_FAIL;
+ if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095 &&
+ !info->abstract_write_csr_supported)
return ERROR_FAIL;
- }
+
+ uint32_t command = access_register_command(number, size,
+ AC_ACCESS_REGISTER_TRANSFER |
+ AC_ACCESS_REGISTER_WRITE);
if (write_abstract_arg(target, 0, value) != ERROR_OK) {
return ERROR_FAIL;
@@ -751,6 +755,201 @@ static int register_write_abstract(struct target *target, uint32_t number,
return ERROR_OK;
}
+static int examine_progbuf(struct target *target)
+{
+ riscv013_info_t *info = get_info(target);
+
+ if (info->progbuf_writable != YNM_MAYBE)
+ return ERROR_OK;
+
+ // Figure out if progbuf is writable.
+
+ if (info->progbufsize < 1) {
+ info->progbuf_writable = YNM_NO;
+ LOG_INFO("No program buffer present.");
+ return ERROR_OK;
+ }
+
+ uint64_t s0;
+ if (register_read_direct(target, &s0, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+
+ struct riscv_program program;
+ riscv_program_init(&program, target);
+ riscv_program_insert(&program, auipc(S0));
+ if (riscv_program_exec(&program, target) != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (register_read_direct(target, &info->progbuf_address, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+
+ riscv_program_init(&program, target);
+ riscv_program_insert(&program, sw(S0, S0, 0));
+ int result = riscv_program_exec(&program, target);
+
+ if (register_write_direct(target, GDB_REGNO_S0, s0) != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (result != ERROR_OK) {
+ // This program might have failed if the program buffer is not
+ // writable.
+ info->progbuf_writable = YNM_NO;
+ return ERROR_OK;
+ }
+
+ uint32_t written = dmi_read(target, DMI_PROGBUF0);
+ if (written == (uint32_t) info->progbuf_address) {
+ LOG_INFO("progbuf is writable at 0x%" TARGET_PRIxADDR,
+ info->progbuf_address);
+ info->progbuf_writable = YNM_YES;
+
+ } else {
+ LOG_INFO("progbuf is not writeable at 0x%" TARGET_PRIxADDR,
+ info->progbuf_address);
+ info->progbuf_writable = YNM_NO;
+ }
+
+ return ERROR_OK;
+}
+
+typedef enum {
+ SPACE_DMI_DATA,
+ SPACE_DMI_PROGBUF,
+ SPACE_DMI_RAM
+} memory_space_t;
+
+typedef struct {
+ // How can the debugger access this memory?
+ memory_space_t memory_space;
+ // Memory address to access the scratch memory from the hart.
+ riscv_addr_t hart_address;
+ // Memory address to access the scratch memory from the debugger.
+ riscv_addr_t debug_address;
+} scratch_mem_t;
+
+/**
+ * Find some scratch memory to be used with the given program.
+ */
+static int scratch_find(struct target *target,
+ scratch_mem_t *scratch,
+ struct riscv_program *program,
+ unsigned size_bytes)
+{
+ riscv013_info_t *info = get_info(target);
+
+ riscv_addr_t alignment = 1;
+ while (alignment < size_bytes)
+ alignment *= 2;
+
+ if (info->dataaccess == 1) {
+ // Sign extend dataaddr.
+ scratch->hart_address = info->dataaddr;
+ if (info->dataaddr & (1<<11)) {
+ scratch->hart_address |= 0xfffffffffffff000ULL;
+ }
+ // Align.
+ scratch->hart_address = (scratch->hart_address + alignment - 1) & ~(alignment - 1);
+
+ if ((size_bytes + scratch->hart_address - info->dataaddr + 3) / 4 >=
+ info->datasize) {
+ scratch->memory_space = SPACE_DMI_DATA;
+ scratch->debug_address = (scratch->hart_address - info->dataaddr) / 4;
+ return ERROR_OK;
+ }
+ }
+
+ if (examine_progbuf(target) != ERROR_OK)
+ return ERROR_FAIL;
+
+ // Allow for ebreak at the end of the program.
+ unsigned program_size = (program->instruction_count + 1 ) * 4;
+ scratch->hart_address = (info->progbuf_address + program_size + alignment - 1) &
+ ~(alignment - 1);
+ if ((size_bytes + scratch->hart_address - info->progbuf_address + 3) / 4 >=
+ info->progbufsize) {
+ scratch->memory_space = SPACE_DMI_PROGBUF;
+ scratch->debug_address = (scratch->hart_address - info->progbuf_address) / 4;
+ return ERROR_OK;
+ }
+
+ if (riscv_use_scratch_ram) {
+ scratch->hart_address = (riscv_use_scratch_ram + alignment - 1) &
+ ~(alignment - 1);
+ scratch->memory_space = SPACE_DMI_RAM;
+ scratch->debug_address = scratch->hart_address;
+ return ERROR_OK;
+ }
+
+ LOG_ERROR("Couldn't find %d bytes of scratch RAM to use. Please configure "
+ "an address with 'riscv set_scratch_ram'.", size_bytes);
+ return ERROR_FAIL;
+}
+
+static int scratch_read64(struct target *target, scratch_mem_t *scratch,
+ uint64_t *value)
+{
+ switch (scratch->memory_space) {
+ case SPACE_DMI_DATA:
+ *value = dmi_read(target, DMI_DATA0 + scratch->debug_address);
+ *value |= ((uint64_t) dmi_read(target, DMI_DATA1 +
+ scratch->debug_address)) << 32;
+ break;
+ case SPACE_DMI_PROGBUF:
+ *value = dmi_read(target, DMI_PROGBUF0 + scratch->debug_address);
+ *value |= ((uint64_t) dmi_read(target, DMI_PROGBUF1 +
+ scratch->debug_address)) << 32;
+ break;
+ case SPACE_DMI_RAM:
+ {
+ uint8_t buffer[8];
+ if (read_memory(target, scratch->debug_address, 4, 2, buffer) != ERROR_OK)
+ return ERROR_FAIL;
+ *value = 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);
+ }
+ break;
+ }
+ return ERROR_OK;
+}
+
+static int scratch_write64(struct target *target, scratch_mem_t *scratch,
+ uint64_t value)
+{
+ switch (scratch->memory_space) {
+ case SPACE_DMI_DATA:
+ dmi_write(target, DMI_DATA0 + scratch->debug_address, value);
+ dmi_write(target, DMI_DATA1 + scratch->debug_address, value >> 32);
+ break;
+ case SPACE_DMI_PROGBUF:
+ dmi_write(target, DMI_PROGBUF0 + scratch->debug_address, value);
+ dmi_write(target, DMI_PROGBUF1 + scratch->debug_address, value >> 32);
+ break;
+ case SPACE_DMI_RAM:
+ {
+ uint8_t buffer[8] = {
+ value,
+ value >> 8,
+ value >> 16,
+ value >> 24,
+ value >> 32,
+ value >> 40,
+ value >> 48,
+ value >> 56
+ };
+ if (write_memory(target, scratch->debug_address, 4, 2, buffer) != ERROR_OK)
+ return ERROR_FAIL;
+ }
+ break;
+ }
+ return ERROR_OK;
+}
+
static int register_write_direct(struct target *target, unsigned number,
uint64_t value)
{
@@ -763,34 +962,55 @@ static int register_write_direct(struct target *target, unsigned number,
return ERROR_OK;
struct riscv_program program;
-
riscv_program_init(&program, target);
- riscv_addr_t input = riscv_program_alloc_d(&program);
- riscv_program_write_ram(&program, input + 4, value >> 32);
- riscv_program_write_ram(&program, input, value);
+ uint64_t s0;
+ if (register_read_direct(target, &s0, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31 &&
+ supports_extension(target, 'D') &&
+ riscv_xlen(target) < 64) {
+ /* There are no instructions to move all the bits from a register, so
+ * we need to use some scratch RAM. */
+ riscv_program_insert(&program, fld(number - GDB_REGNO_FPR0, S0, 0));
+
+ scratch_mem_t scratch;
+ if (scratch_find(target, &scratch, &program, 8) != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (register_write_direct(target, GDB_REGNO_S0, scratch.hart_address)
+ != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (scratch_write64(target, &scratch, value) != ERROR_OK)
+ return ERROR_FAIL;
- assert(GDB_REGNO_XPR0 == 0);
- if (number <= GDB_REGNO_XPR31) {
- riscv_program_lx(&program, number, input);
- } else if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31) {
- riscv_program_flx(&program, number, input);
- } else if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095) {
- enum gdb_regno temp = riscv_program_gettemp(&program);
- riscv_program_lx(&program, temp, input);
- riscv_program_csrw(&program, temp, number);
} else {
- LOG_ERROR("Unsupported register (enum gdb_regno)(%d)", number);
- abort();
+ if (register_write_direct(target, GDB_REGNO_S0, value) != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31) {
+ if (supports_extension(target, 'D')) {
+ riscv_program_insert(&program, fmv_d_x(number - GDB_REGNO_FPR0, S0));
+ } else {
+ riscv_program_insert(&program, fmv_s_x(number - GDB_REGNO_FPR0, S0));
+ }
+ } else if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095) {
+ riscv_program_csrw(&program, S0, number);
+ } else {
+ LOG_ERROR("Unsupported register (enum gdb_regno)(%d)", number);
+ abort();
+ }
}
int exec_out = riscv_program_exec(&program, target);
- if (exec_out != ERROR_OK) {
- riscv013_clear_abstract_error(target);
+
+ // Restore S0.
+ if (register_write_direct(target, GDB_REGNO_S0, s0) != ERROR_OK)
return ERROR_FAIL;
- }
- return ERROR_OK;
+ return exec_out;
}
/** Actually read registers from the target right now. */
@@ -800,41 +1020,72 @@ static int register_read_direct(struct target *target, uint64_t *value, uint32_t
riscv_xlen(target));
if (result != ERROR_OK) {
+ assert(number != GDB_REGNO_S0);
+
+ result = ERROR_OK;
+
struct riscv_program program;
riscv_program_init(&program, target);
- riscv_addr_t output = riscv_program_alloc_d(&program);
- riscv_program_write_ram(&program, output + 4, 0);
- riscv_program_write_ram(&program, output, 0);
-
- assert(GDB_REGNO_XPR0 == 0);
- if (number <= GDB_REGNO_XPR31) {
- riscv_program_sx(&program, number, output);
- } else if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31) {
- riscv_program_fsx(&program, number, output);
+
+ scratch_mem_t scratch;
+ bool use_scratch = false;
+
+ uint64_t s0;
+ if (register_read_direct(target, &s0, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+
+ // Write program to move data into s0.
+
+ if (number >= GDB_REGNO_FPR0 && number <= GDB_REGNO_FPR31) {
+ // TODO: Possibly set F in mstatus.
+ if (supports_extension(target, 'D') && riscv_xlen(target) < 64) {
+ /* There are no instructions to move all the bits from a
+ * register, so we need to use some scratch RAM. */
+ riscv_program_insert(&program, fsd(number - GDB_REGNO_FPR0, S0,
+ 0));
+
+ if (scratch_find(target, &scratch, &program, 8) != ERROR_OK)
+ return ERROR_FAIL;
+ use_scratch = true;
+
+ if (register_write_direct(target, GDB_REGNO_S0,
+ scratch.hart_address) != ERROR_OK)
+ return ERROR_FAIL;
+ } else if (supports_extension(target, 'D')) {
+ riscv_program_insert(&program, fmv_x_d(S0, number - GDB_REGNO_FPR0));
+ } else {
+ riscv_program_insert(&program, fmv_x_s(S0, number - GDB_REGNO_FPR0));
+ }
} else if (number >= GDB_REGNO_CSR0 && number <= GDB_REGNO_CSR4095) {
- LOG_DEBUG("reading CSR index=0x%03x", number - GDB_REGNO_CSR0);
- enum gdb_regno temp = riscv_program_gettemp(&program);
- riscv_program_csrr(&program, temp, number);
- riscv_program_sx(&program, temp, output);
+ riscv_program_csrr(&program, S0, number);
} else {
LOG_ERROR("Unsupported register (enum gdb_regno)(%d)", number);
abort();
}
- int exec_out = riscv_program_exec(&program, target);
- if (exec_out != ERROR_OK) {
- riscv013_clear_abstract_error(target);
- return ERROR_FAIL;
+ // Execute program.
+ result = riscv_program_exec(&program, target);
+
+ if (use_scratch) {
+ if (scratch_read64(target, &scratch, value) != ERROR_OK)
+ return ERROR_FAIL;
+ } else {
+ // Read S0
+ if (register_read_direct(target, value, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
}
- *value = 0;
- *value |= ((uint64_t)(riscv_program_read_ram(&program, output + 4))) << 32;
- *value |= riscv_program_read_ram(&program, output);
+ // Restore S0.
+ if (register_write_direct(target, GDB_REGNO_S0, s0) != ERROR_OK)
+ return ERROR_FAIL;
}
- LOG_DEBUG("[%d] reg[0x%x] = 0x%" PRIx64, riscv_current_hartid(target),
- number, *value);
- return ERROR_OK;
+ if (result == ERROR_OK) {
+ LOG_DEBUG("[%d] reg[0x%x] = 0x%" PRIx64, riscv_current_hartid(target),
+ number, *value);
+ }
+
+ return result;
}
/*** OpenOCD target functions. ***/
@@ -890,8 +1141,6 @@ static int init_target(struct command_context *cmd_ctx,
generic_info->on_resume = &riscv013_on_resume;
generic_info->on_step = &riscv013_on_step;
generic_info->halt_reason = &riscv013_halt_reason;
- generic_info->debug_buffer_enter = &riscv013_debug_buffer_enter;
- generic_info->debug_buffer_leave = &riscv013_debug_buffer_leave;
generic_info->read_debug_buffer = &riscv013_read_debug_buffer;
generic_info->write_debug_buffer = &riscv013_write_debug_buffer;
generic_info->execute_debug_buffer = &riscv013_execute_debug_buffer;
@@ -904,10 +1153,7 @@ static int init_target(struct command_context *cmd_ctx,
return ERROR_FAIL;
riscv013_info_t *info = get_info(target);
- info->progbuf_size = -1;
- info->progbuf_addr = -1;
- info->data_size = -1;
- info->data_addr = -1;
+ info->progbufsize = -1;
info->dmi_busy_delay = 0;
info->ac_busy_delay = 0;
@@ -996,7 +1242,6 @@ static int examine(struct target *target)
info->abits = get_field(dtmcontrol, DTM_DTMCS_ABITS);
info->dtmcontrol_idle = get_field(dtmcontrol, DTM_DTMCS_IDLE);
- uint32_t dmcontrol = dmi_read(target, DMI_DMCONTROL);
uint32_t dmstatus = dmi_read(target, DMI_DMSTATUS);
if (get_field(dmstatus, DMI_DMSTATUS_VERSION) != 2) {
LOG_ERROR("OpenOCD only supports Debug Module version 2, not %d "
@@ -1007,10 +1252,17 @@ static int examine(struct target *target)
// Reset the Debug Module.
dmi_write(target, DMI_DMCONTROL, 0);
dmi_write(target, DMI_DMCONTROL, DMI_DMCONTROL_DMACTIVE);
- dmcontrol = dmi_read(target, DMI_DMCONTROL);
+ uint32_t dmcontrol = dmi_read(target, DMI_DMCONTROL);
+
+ uint32_t hartinfo = dmi_read(target, DMI_HARTINFO);
LOG_DEBUG("dmcontrol: 0x%08x", dmcontrol);
LOG_DEBUG("dmstatus: 0x%08x", dmstatus);
+ LOG_DEBUG("hartinfo: 0x%08x", hartinfo);
+
+ info->datasize = get_field(hartinfo, DMI_HARTINFO_DATASIZE);
+ info->dataaccess = get_field(hartinfo, DMI_HARTINFO_DATAACCESS);
+ info->dataaddr = get_field(hartinfo, DMI_HARTINFO_DATAADDR);
if (!get_field(dmcontrol, DMI_DMCONTROL_DMACTIVE)) {
LOG_ERROR("Debug Module did not become active. dmcontrol=0x%x",
@@ -1037,10 +1289,12 @@ static int examine(struct target *target)
// Check that abstract data registers are accessible.
uint32_t abstractcs = dmi_read(target, DMI_ABSTRACTCS);
info->datacount = get_field(abstractcs, DMI_ABSTRACTCS_DATACOUNT);
- info->progsize = get_field(abstractcs, DMI_ABSTRACTCS_PROGSIZE);
+ info->progbufsize = get_field(abstractcs, DMI_ABSTRACTCS_PROGBUFSIZE);
/* Before doing anything else we must first enumerate the harts. */
RISCV_INFO(r);
+ r->impebreak = get_field(dmstatus, DMI_DMSTATUS_IMPEBREAK);
+
int original_coreid = target->coreid;
for (int i = 0; i < RISCV_MAX_HARTS; ++i) {
/* Fake being a non-RTOS targeted to this core so we can see if
@@ -1074,80 +1328,21 @@ static int examine(struct target *target)
/* Without knowing anything else we can at least mess with the
* program buffer. */
- r->debug_buffer_size[i] = riscv013_progbuf_size(target);
-
- /* Guess this is a 32-bit system, we're probing it. */
- r->xlen[i] = 32;
-
- /* First find the low 32 bits of the program buffer. This is
- * used to check for alignment. */
- struct riscv_program program32;
- riscv_program_init(&program32, target);
- riscv_program_csrrw(&program32, GDB_REGNO_S0, GDB_REGNO_S0, GDB_REGNO_DSCRATCH);
- riscv_program_insert(&program32, auipc(GDB_REGNO_S0));
- riscv_program_insert(&program32, sw(GDB_REGNO_S0, GDB_REGNO_S0, -4));
- riscv_program_csrrw(&program32, GDB_REGNO_S0, GDB_REGNO_S0, GDB_REGNO_DSCRATCH);
- riscv_program_fence(&program32);
- riscv_program_exec(&program32, target);
-
- riscv_addr_t progbuf_addr = dmi_read(target, DMI_PROGBUF0) - 4;
- if (get_field(dmi_read(target, DMI_ABSTRACTCS), DMI_ABSTRACTCS_CMDERR) != 0) {
- LOG_ERROR("Unable to find the address of the program buffer on hart %d", i);
- r->xlen[i] = -1;
- continue;
- }
- r->debug_buffer_addr[i] = progbuf_addr;
-
- /* Check to see if the core can execute 64 bit instructions.
- * In order to make this work we first need to */
- int offset = (progbuf_addr % 8 == 0) ? -4 : 0;
-
- /* This program uses a temporary register. If the core can not
- * execute 64 bit instruction, the original value of temporary
- * register (s0) will not be restored due to an exception.
- * So we have to save it and restore manually in that case.
- * If the core can execute 64 bit instruction, the saved value
- * is wrong, because it was read with 32 bit lw instruction,
- * but the value of s0 will be restored by the reverse swap
- * of s0 and dscratch registers. */
- uint64_t s0 = riscv_get_register(target, GDB_REGNO_S0);
-
- struct riscv_program program64;
- riscv_program_init(&program64, target);
- riscv_program_csrrw(&program64, GDB_REGNO_S0, GDB_REGNO_S0, GDB_REGNO_DSCRATCH);
- riscv_program_insert(&program64, auipc(GDB_REGNO_S0));
- riscv_program_insert(&program64, sd(GDB_REGNO_S0, GDB_REGNO_S0, offset));
- riscv_program_csrrw(&program64, GDB_REGNO_S0, GDB_REGNO_S0, GDB_REGNO_DSCRATCH);
- riscv_program_fence(&program64);
- int result = riscv_program_exec(&program64, target);
+ r->debug_buffer_size[i] = info->progbufsize;
+ int result = register_read_abstract(target, NULL, GDB_REGNO_S0, 64);
if (result == ERROR_OK) {
- r->debug_buffer_addr[i] =
- (dmi_read(target, DMI_PROGBUF0 + (8 + offset) / 4) << 32)
- + dmi_read(target, DMI_PROGBUF0 + (4 + offset) / 4)
- - 4;
r->xlen[i] = 64;
} else {
- riscv_set_register(target, GDB_REGNO_S0, s0);
+ r->xlen[i] = 32;
}
+ r->misa = riscv_get_register_on_hart(target, i, GDB_REGNO_MISA);
+
/* Display this as early as possible to help people who are using
* really slow simulators. */
- LOG_DEBUG(" hart %d: XLEN=%d, program buffer at 0x%" PRIx64, i,
- r->xlen[i], r->debug_buffer_addr[i]);
-
- if (riscv_program_gah(&program64, r->debug_buffer_addr[i])) {
- LOG_ERROR("This implementation will not work with hart %d with debug_buffer_addr of 0x%lx", i,
- (long)r->debug_buffer_addr[i]);
- abort();
- }
-
- /* Check to see if we can use the data words as an extended
- * program buffer or not. */
- if (r->debug_buffer_addr[i] + (4 * r->debug_buffer_size[i]) == riscv013_data_addr(target)) {
- r->debug_buffer_size[i] += riscv013_data_size(target);
- LOG_DEBUG("extending the debug buffer using data words, total size %d", r->debug_buffer_size[i]);
- }
+ LOG_DEBUG(" hart %d: XLEN=%d, misa=0x%" PRIx64, i, r->xlen[i],
+ r->misa);
}
/* Then we check the number of triggers availiable to each hart. */
@@ -1169,8 +1364,7 @@ static int examine(struct target *target)
riscv_count_harts(target));
for (int i = 0; i < riscv_count_harts(target); ++i) {
if (riscv_hart_enabled(target, i)) {
- LOG_INFO(" hart %d: XLEN=%d, program buffer at 0x%" PRIx64
- ", %d triggers", i, r->xlen[i], r->debug_buffer_addr[i],
+ LOG_INFO(" hart %d: XLEN=%d, %d triggers", i, r->xlen[i],
r->trigger_count[i]);
} else {
LOG_INFO(" hart %d: currently disabled", i);
@@ -1293,6 +1487,9 @@ static int deassert_reset(struct target *target)
return ERROR_OK;
}
+/**
+ * @size in bytes
+ */
static void write_to_buf(uint8_t *buffer, uint64_t value, unsigned size)
{
switch (size) {
@@ -1314,6 +1511,16 @@ static void write_to_buf(uint8_t *buffer, uint64_t value, unsigned size)
}
}
+static int execute_fence(struct target *target) {
+ struct riscv_program program;
+ riscv_program_init(&program, target);
+ riscv_program_fence(&program);
+ int result = riscv_program_exec(&program, target);
+ if (result != ERROR_OK)
+ LOG_ERROR("Unable to execute fence");
+ return result;
+}
+
/**
* Read the requested memory, taking care to execute every read exactly once,
* even if cmderr=busy is encountered.
@@ -1328,21 +1535,21 @@ static int read_memory(struct target *target, target_addr_t address,
select_dmi(target);
- /* This program uses two temporary registers. A word of data and the
- * associated address are stored at some location in memory. The
- * program loads the word from that address and then increments the
- * address. The debugger is expected to pull the memory word-by-word
- * from the chip with AUTOEXEC set in order to trigger program
- * execution on every word. */
- uint64_t s0 = riscv_get_register(target, GDB_REGNO_S0);
- uint64_t s1 = riscv_get_register(target, GDB_REGNO_S1);
+ /* s0 holds the next address to write to
+ * s1 holds the next data value to write
+ */
+ uint64_t s0, s1;
+ if (register_read_direct(target, &s0, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+ if (register_read_direct(target, &s1, GDB_REGNO_S1) != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (execute_fence(target) != ERROR_OK)
+ return ERROR_FAIL;
+ // Write the program (load, increment)
struct riscv_program program;
riscv_program_init(&program, target);
- riscv_addr_t r_data = riscv_program_alloc_w(&program);
- riscv_addr_t r_addr = riscv_program_alloc_x(&program);
- riscv_program_fence(&program);
- riscv_program_lx(&program, GDB_REGNO_S0, r_addr);
switch (size) {
case 1:
riscv_program_lbr(&program, GDB_REGNO_S1, GDB_REGNO_S0, 0);
@@ -1358,70 +1565,51 @@ static int read_memory(struct target *target, target_addr_t address,
return ERROR_FAIL;
}
riscv_program_addi(&program, GDB_REGNO_S0, GDB_REGNO_S0, size);
- riscv_program_sw(&program, GDB_REGNO_S1, r_data);
- riscv_program_sx(&program, GDB_REGNO_S0, r_addr);
-
- /* The first round through the program's execution we use the regular
- * program execution mechanism. */
- switch (riscv_xlen(target)) {
- case 64:
- riscv_program_write_ram(&program, r_addr + 4, ((riscv_addr_t) address) >> 32);
- case 32:
- riscv_program_write_ram(&program, r_addr, (riscv_addr_t) address);
- break;
- default:
- LOG_ERROR("unknown XLEN %d", riscv_xlen(target));
- return ERROR_FAIL;
- }
- if (riscv_program_exec(&program, target) != ERROR_OK) {
- uint32_t acs = dmi_read(target, DMI_ABSTRACTCS);
- LOG_ERROR("failed to execute program, abstractcs=0x%08x", acs);
- riscv013_clear_abstract_error(target);
- riscv_set_register(target, GDB_REGNO_S0, s0);
- riscv_set_register(target, GDB_REGNO_S1, s1);
- LOG_ERROR(" exiting with ERROR_FAIL");
+ if (riscv_program_ebreak(&program) != ERROR_OK)
return ERROR_FAIL;
- }
+ riscv_program_write(&program);
- // Program has been executed once. d_addr contains address+size, and d_data
- // contains *address.
+ // Write address to S0, and execute buffer.
+ if (register_write_direct(target, GDB_REGNO_S0, address) != ERROR_OK)
+ return ERROR_FAIL;
+ uint32_t command = access_register_command(GDB_REGNO_S1, riscv_xlen(target),
+ AC_ACCESS_REGISTER_TRANSFER |
+ AC_ACCESS_REGISTER_POSTEXEC);
+ if (execute_abstract_command(target, command) != ERROR_OK)
+ return ERROR_FAIL;
- /* The rest of this program is designed to be fast so it reads various
- * DMI registers directly. */
- int d_data = (r_data - riscv_debug_buffer_addr(target)) / 4;
- int d_addr = (r_addr - riscv_debug_buffer_addr(target)) / 4;
+ // First read has just triggered. Result is in s1.
- riscv013_set_autoexec(target, d_data, 1);
+ dmi_write(target, DMI_ABSTRACTAUTO,
+ 1 << DMI_ABSTRACTAUTO_AUTOEXECDATA_OFFSET);
- /* Copying memory might fail because we're going too quickly, in which
- * case we need to back off a bit and try again. There's two
- * termination conditions to this loop: a non-BUSY error message, or
- * the data was all copied. */
- riscv_addr_t cur_addr = riscv_read_debug_buffer_x(target, d_addr);
+ // read_addr is the next address that the hart will read from, which is the
+ // value in s0.
+ riscv_addr_t read_addr = address + size;
+ // The next address that we need to receive data for.
+ riscv_addr_t receive_addr = address;
riscv_addr_t fin_addr = address + (count * size);
- LOG_DEBUG("reading until final address 0x%" PRIx64, fin_addr);
- while (cur_addr < fin_addr) {
- // Invariant:
- // d_data contains *addr
- // d_addr contains addr + size
-
- unsigned start = (cur_addr - address) / size;
- LOG_DEBUG("creating burst to read address 0x%" TARGET_PRIxADDR
- " up to 0x%" TARGET_PRIxADDR "; start=0x%d", cur_addr, fin_addr, start);
- assert(cur_addr >= address && cur_addr < fin_addr);
- struct riscv_batch *batch = riscv_batch_alloc(
- target,
- 32,
- info->dmi_busy_delay + info->ac_busy_delay);
+ unsigned skip = 1;
+ while (read_addr < fin_addr) {
+ LOG_DEBUG("read_addr=0x%" PRIx64 ", receive_addr=0x%" PRIx64
+ ", fin_addr=0x%" PRIx64, read_addr, receive_addr, fin_addr);
+ // The pipeline looks like this:
+ // memory -> s1 -> dm_data0 -> debugger
+ // It advances every time the debugger reads dmdata0.
+ // So at any time the debugger has just read mem[s0 - 3*size],
+ // dm_data0 contains mem[s0 - 2*size]
+ // s1 contains mem[s0-size]
+
+ LOG_DEBUG("creating burst to read from 0x%" TARGET_PRIxADDR
+ " up to 0x%" TARGET_PRIxADDR, read_addr, fin_addr);
+ assert(read_addr >= address && read_addr < fin_addr);
+ struct riscv_batch *batch = riscv_batch_alloc(target, 32,
+ info->dmi_busy_delay + info->ac_busy_delay);
size_t reads = 0;
- for (riscv_addr_t addr = cur_addr; addr < fin_addr; addr += size) {
- size_t const index =
- riscv_batch_add_dmi_read(
- batch,
- riscv013_debug_buffer_register(target, r_data));
- assert(index == reads);
+ for (riscv_addr_t addr = read_addr; addr < fin_addr; addr += size) {
+ riscv_batch_add_dmi_read(batch, DMI_DATA0);
reads++;
if (riscv_batch_full(batch))
@@ -1437,62 +1625,126 @@ static int read_memory(struct target *target, target_addr_t address,
abstractcs = dmi_read(target, DMI_ABSTRACTCS);
info->cmderr = get_field(abstractcs, DMI_ABSTRACTCS_CMDERR);
+ unsigned cmderr = info->cmderr;
+ riscv_addr_t next_read_addr;
+ uint32_t dmi_data0 = -1;
switch (info->cmderr) {
- case CMDERR_NONE:
- LOG_DEBUG("successful (partial?) memory read");
- break;
- case CMDERR_BUSY:
- LOG_DEBUG("memory read resulted in busy response");
- increase_ac_busy_delay(target);
- riscv013_clear_abstract_error(target);
- break;
- default:
- LOG_ERROR("error when reading memory, abstractcs=0x%08lx", (long)abstractcs);
- riscv013_set_autoexec(target, d_data, 0);
- riscv_set_register(target, GDB_REGNO_S0, s0);
- riscv_set_register(target, GDB_REGNO_S1, s1);
- riscv013_clear_abstract_error(target);
- riscv_batch_free(batch);
- return ERROR_FAIL;
- }
+ case CMDERR_NONE:
+ LOG_DEBUG("successful (partial?) memory read");
+ next_read_addr = read_addr + reads * size;
+ break;
+ case CMDERR_BUSY:
+ LOG_DEBUG("memory read resulted in busy response");
+
+ /*
+ * If you want to exercise this code path, apply the following patch to spike:
+--- a/riscv/debug_module.cc
++++ b/riscv/debug_module.cc
+@@ -1,3 +1,5 @@
++#include <unistd.h>
++
+ #include <cassert>
+
+ #include "debug_module.h"
+@@ -398,6 +400,15 @@ bool debug_module_t::perform_abstract_command()
+ // Since the next instruction is what we will use, just use nother NOP
+ // to get there.
+ write32(debug_abstract, 1, addi(ZERO, ZERO, 0));
++
++ if (abstractauto.autoexecdata &&
++ program_buffer[0] == 0x83 &&
++ program_buffer[1] == 0x24 &&
++ program_buffer[2] == 0x04 &&
++ program_buffer[3] == 0 &&
++ rand() < RAND_MAX / 10) {
++ usleep(1000000);
++ }
+ } else {
+ write32(debug_abstract, 1, ebreak());
+ }
+ */
+ increase_ac_busy_delay(target);
+ riscv013_clear_abstract_error(target);
+
+ dmi_write(target, DMI_ABSTRACTAUTO, 0);
+
+ // This is definitely a good version of the value that we
+ // attempted to read when we discovered that the target was
+ // busy.
+ dmi_data0 = dmi_read(target, DMI_DATA0);
+
+ // Clobbers DMI_DATA0.
+ if (register_read_direct(target, &next_read_addr, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+ // Restore the command, and execute it.
+ // Now DMI_DATA0 contains the next value just as it would if no
+ // error had occurred.
+ dmi_write(target, DMI_COMMAND, command);
- // Figure out how far we managed to read.
- riscv_addr_t next_addr = riscv_read_debug_buffer_x(target, d_addr);
- LOG_DEBUG("Batch read [0x%" TARGET_PRIxADDR ", 0x%" TARGET_PRIxADDR
- "); reads=%d", cur_addr, next_addr, (unsigned) reads);
- assert(next_addr >= address && next_addr <= fin_addr);
- assert(info->cmderr != CMDERR_NONE ||
- next_addr == cur_addr + reads * size);
+ dmi_write(target, DMI_ABSTRACTAUTO,
+ 1 << DMI_ABSTRACTAUTO_AUTOEXECDATA_OFFSET);
+ break;
+ default:
+ LOG_ERROR("error when reading memory, abstractcs=0x%08lx", (long)abstractcs);
+ dmi_write(target, DMI_ABSTRACTAUTO, 0);
+ riscv_set_register(target, GDB_REGNO_S0, s0);
+ riscv_set_register(target, GDB_REGNO_S1, s1);
+ riscv013_clear_abstract_error(target);
+ riscv_batch_free(batch);
+ return ERROR_FAIL;
+ }
// Now read whatever we got out of the batch.
- unsigned rereads = 0;
- for (riscv_addr_t addr = cur_addr - size; addr < next_addr - size;
- addr += size) {
- riscv_addr_t offset = addr - address;
+ for (size_t i = 0; i < reads; i++) {
+ if (read_addr >= next_read_addr) {
+ break;
+ }
+
+ read_addr += size;
+
+ if (skip > 0) {
+ skip--;
+ continue;
+ }
- uint64_t dmi_out = riscv_batch_get_dmi_read(batch, rereads);
+ riscv_addr_t offset = receive_addr - address;
+ uint64_t dmi_out = riscv_batch_get_dmi_read(batch, i);
uint32_t value = get_field(dmi_out, DTM_DMI_DATA);
write_to_buf(buffer + offset, value, size);
+ LOG_DEBUG("M[0x%" TARGET_PRIxADDR "] reads 0x%08x", receive_addr,
+ value);
- rereads++;
-
- LOG_DEBUG("M[0x%" TARGET_PRIxADDR "] reads 0x%08x", addr, value);
+ receive_addr += size;
}
riscv_batch_free(batch);
- cur_addr = next_addr;
+ if (cmderr == CMDERR_BUSY) {
+ riscv_addr_t offset = receive_addr - address;
+ write_to_buf(buffer + offset, dmi_data0, size);
+ LOG_DEBUG("M[0x%" TARGET_PRIxADDR "] reads 0x%08x", receive_addr,
+ dmi_data0);
+ read_addr += size;
+ receive_addr += size;
+ }
}
- riscv013_set_autoexec(target, d_data, 0);
+ dmi_write(target, DMI_ABSTRACTAUTO, 0);
- // Read the last word.
+ if (count > 1) {
+ // Read the penultimate word.
+ uint64_t value = dmi_read(target, DMI_DATA0);
+ write_to_buf(buffer + receive_addr - address, value, size);
+ LOG_DEBUG("M[0x%" TARGET_PRIxADDR "] reads 0x%" PRIx64, receive_addr, value);
+ receive_addr += size;
+ }
- // Access debug buffer without executing a program. This
- // address logic was taken from program.c.
- uint32_t value = riscv013_read_debug_buffer(target, d_data);
- riscv_addr_t addr = cur_addr - size;
- write_to_buf(buffer + addr - address, value, size);
- LOG_DEBUG("M[0x%" TARGET_PRIxADDR "] reads 0x%08x", addr, value);
+ // Read the last word.
+ uint64_t value;
+ if (register_read_direct(target, &value, GDB_REGNO_S1) != ERROR_OK)
+ return ERROR_FAIL;
+ write_to_buf(buffer + receive_addr - address, value, size);
+ LOG_DEBUG("M[0x%" TARGET_PRIxADDR "] reads 0x%" PRIx64, receive_addr, value);
+ receive_addr += size;
riscv_set_register(target, GDB_REGNO_S0, s0);
riscv_set_register(target, GDB_REGNO_S1, s1);
@@ -1508,22 +1760,19 @@ static int write_memory(struct target *target, target_addr_t address,
select_dmi(target);
- /* This program uses two temporary registers. A word of data and the
- * associated address are stored at some location in memory. The
- * program stores the word to that address and then increments the
- * address. The debugger is expected to feed the memory word-by-word
- * into the chip with AUTOEXEC set in order to trigger program
- * execution on every word. */
- uint64_t s0 = riscv_get_register(target, GDB_REGNO_S0);
- uint64_t s1 = riscv_get_register(target, GDB_REGNO_S1);
+ /* s0 holds the next address to write to
+ * s1 holds the next data value to write
+ */
+ uint64_t s0, s1;
+ if (register_read_direct(target, &s0, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+ if (register_read_direct(target, &s1, GDB_REGNO_S1) != ERROR_OK)
+ return ERROR_FAIL;
+
+ // Write the program (store, increment)
struct riscv_program program;
riscv_program_init(&program, target);
- riscv_addr_t r_data = riscv_program_alloc_w(&program);
- riscv_addr_t r_addr = riscv_program_alloc_x(&program);
- riscv_program_fence(&program);
- riscv_program_lx(&program, GDB_REGNO_S0, r_addr);
- riscv_program_lw(&program, GDB_REGNO_S1, r_data);
switch (size) {
case 1:
@@ -1541,83 +1790,31 @@ static int write_memory(struct target *target, target_addr_t address,
}
riscv_program_addi(&program, GDB_REGNO_S0, GDB_REGNO_S0, size);
- riscv_program_sx(&program, GDB_REGNO_S0, r_addr);
-
- /* The first round through the program's execution we use the regular
- * program execution mechanism. */
- uint32_t value;
- switch (size) {
- case 1:
- value = buffer[0];
- break;
- case 2:
- value = buffer[0]
- | ((uint32_t) buffer[1] << 8);
- break;
- case 4:
- value = buffer[0]
- | ((uint32_t) buffer[1] << 8)
- | ((uint32_t) buffer[2] << 16)
- | ((uint32_t) buffer[3] << 24);
- break;
- default:
- LOG_ERROR("unsupported access size: %d", size);
- return ERROR_FAIL;
- }
-
- switch (riscv_xlen(target)) {
- case 64:
- riscv_program_write_ram(&program, r_addr + 4, (uint64_t)address >> 32);
- case 32:
- riscv_program_write_ram(&program, r_addr, address);
- break;
- default:
- LOG_ERROR("unknown XLEN %d", riscv_xlen(target));
- return ERROR_FAIL;
- }
- riscv_program_write_ram(&program, r_data, value);
-
- LOG_DEBUG("M[0x%08lx] writes 0x%08x", (long)address, value);
- if (riscv_program_exec(&program, target) != ERROR_OK) {
- uint32_t acs = dmi_read(target, DMI_ABSTRACTCS);
- LOG_ERROR("failed to execute program, abstractcs=0x%08x", acs);
- riscv013_clear_abstract_error(target);
- riscv_set_register(target, GDB_REGNO_S0, s0);
- riscv_set_register(target, GDB_REGNO_S1, s1);
- LOG_ERROR(" exiting with ERROR_FAIL");
+ if (riscv_program_ebreak(&program) != ERROR_OK)
return ERROR_FAIL;
- }
-
- /* The rest of this program is designed to be fast so it reads various
- * DMI registers directly. */
- int d_data = (r_data - riscv_debug_buffer_addr(target)) / 4;
- int d_addr = (r_addr - riscv_debug_buffer_addr(target)) / 4;
-
- riscv013_set_autoexec(target, d_data, 1);
+ riscv_program_write(&program);
- /* Copying memory might fail because we're going too quickly, in which
- * case we need to back off a bit and try again. There's two
- * termination conditions to this loop: a non-BUSY error message, or
- * the data was all copied. */
- riscv_addr_t cur_addr = 0xbadbeef;
+ riscv_addr_t cur_addr = address;
riscv_addr_t fin_addr = address + (count * size);
+ bool setup_needed = true;
LOG_DEBUG("writing until final address 0x%016" PRIx64, fin_addr);
- while ((cur_addr = riscv_read_debug_buffer_x(target, d_addr)) < fin_addr) {
+ while (cur_addr < fin_addr) {
LOG_DEBUG("transferring burst starting at address 0x%016" PRIx64,
cur_addr);
- riscv_addr_t start = (cur_addr - address) / size;
- assert (cur_addr > address);
+
struct riscv_batch *batch = riscv_batch_alloc(
- target,
- 32,
- info->dmi_busy_delay + info->ac_busy_delay);
+ target,
+ 32,
+ info->dmi_busy_delay + info->ac_busy_delay);
- for (riscv_addr_t i = start; i < count; ++i) {
- riscv_addr_t offset = size*i;
- riscv_addr_t t_addr = address + offset;
+ /* To write another word, we put it in S1 and execute the program. */
+ unsigned start = (cur_addr - address) / size;
+ for (unsigned i = start; i < count; ++i) {
+ unsigned offset = size*i;
const uint8_t *t_buffer = buffer + offset;
+ uint32_t value;
switch (size) {
case 1:
value = t_buffer[0];
@@ -1637,14 +1834,37 @@ static int write_memory(struct target *target, target_addr_t address,
return ERROR_FAIL;
}
- LOG_DEBUG("M[0x%08lx] writes 0x%08x", (long)t_addr, value);
+ LOG_DEBUG("M[0x%08" PRIx64 "] writes 0x%08x", address + offset, value);
+ cur_addr += size;
- riscv_batch_add_dmi_write(
- batch,
- riscv013_debug_buffer_register(target, r_data),
- value);
- if (riscv_batch_full(batch))
- break;
+ if (setup_needed) {
+ if (register_write_direct(target, GDB_REGNO_S0,
+ address + offset) != ERROR_OK)
+ return ERROR_FAIL;
+
+ // Write value.
+ 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(GDB_REGNO_S1, 32,
+ AC_ACCESS_REGISTER_POSTEXEC |
+ AC_ACCESS_REGISTER_TRANSFER |
+ AC_ACCESS_REGISTER_WRITE);
+ int result = execute_abstract_command(target, command);
+ if (result != ERROR_OK)
+ return result;
+
+ // Turn on autoexec
+ dmi_write(target, DMI_ABSTRACTAUTO,
+ 1 << DMI_ABSTRACTAUTO_AUTOEXECDATA_OFFSET);
+
+ setup_needed = false;
+ } else {
+ riscv_batch_add_dmi_write(batch, DMI_DATA0, value);
+ if (riscv_batch_full(batch))
+ break;
+ }
}
riscv_batch_run(batch);
@@ -1652,35 +1872,47 @@ static int write_memory(struct target *target, target_addr_t address,
// Note that if the scan resulted in a Busy DMI response, it
// is this read to abstractcs that will cause the dmi_busy_delay
- // to be incremented if necessary. The loop condition above
- // catches the case where no writes went through at all.
+ // to be incremented if necessary.
uint32_t abstractcs = dmi_read(target, DMI_ABSTRACTCS);
while (get_field(abstractcs, DMI_ABSTRACTCS_BUSY))
abstractcs = dmi_read(target, DMI_ABSTRACTCS);
info->cmderr = get_field(abstractcs, DMI_ABSTRACTCS_CMDERR);
switch (info->cmderr) {
- case CMDERR_NONE:
- LOG_DEBUG("successful (partial?) memory write");
- break;
- case CMDERR_BUSY:
- LOG_DEBUG("memory write resulted in busy response");
- riscv013_clear_abstract_error(target);
- increase_ac_busy_delay(target);
- break;
- default:
- LOG_ERROR("error when writing memory, abstractcs=0x%08lx", (long)abstractcs);
- riscv013_set_autoexec(target, d_data, 0);
- riscv013_clear_abstract_error(target);
- riscv_set_register(target, GDB_REGNO_S0, s0);
- riscv_set_register(target, GDB_REGNO_S1, s1);
- return ERROR_FAIL;
+ case CMDERR_NONE:
+ LOG_DEBUG("successful (partial?) memory write");
+ break;
+ case CMDERR_BUSY:
+ LOG_DEBUG("memory write resulted in busy response");
+ riscv013_clear_abstract_error(target);
+ increase_ac_busy_delay(target);
+
+ dmi_write(target, DMI_ABSTRACTAUTO, 0);
+ if (register_read_direct(target, &cur_addr, GDB_REGNO_S0) != ERROR_OK)
+ return ERROR_FAIL;
+ setup_needed = true;
+ break;
+
+ default:
+ LOG_ERROR("error when writing memory, abstractcs=0x%08lx", (long)abstractcs);
+ dmi_write(target, DMI_ABSTRACTAUTO, 0);
+ riscv013_clear_abstract_error(target);
+ riscv_set_register(target, GDB_REGNO_S0, s0);
+ riscv_set_register(target, GDB_REGNO_S1, s1);
+ return ERROR_FAIL;
}
}
- riscv013_set_autoexec(target, d_data, 0);
- riscv_set_register(target, GDB_REGNO_S0, s0);
- riscv_set_register(target, GDB_REGNO_S1, s1);
+ dmi_write(target, DMI_ABSTRACTAUTO, 0);
+
+ if (register_write_direct(target, GDB_REGNO_S1, s1) != ERROR_OK)
+ return ERROR_FAIL;
+ if (register_write_direct(target, GDB_REGNO_S0, s0) != ERROR_OK)
+ return ERROR_FAIL;
+
+ if (execute_fence(target) != ERROR_OK)
+ return ERROR_FAIL;
+
return ERROR_OK;
}
@@ -1860,25 +2092,13 @@ static enum riscv_halt_reason riscv013_halt_reason(struct target *target)
abort();
}
-void riscv013_debug_buffer_enter(struct target *target, struct riscv_program *program)
-{
-}
-
-void riscv013_debug_buffer_leave(struct target *target, struct riscv_program *program)
-{
-}
-
void riscv013_write_debug_buffer(struct target *target, unsigned index, riscv_insn_t data)
{
- if (index >= riscv013_progbuf_size(target))
- return dmi_write(target, DMI_DATA0 + index - riscv013_progbuf_size(target), data);
return dmi_write(target, DMI_PROGBUF0 + index, data);
}
riscv_insn_t riscv013_read_debug_buffer(struct target *target, unsigned index)
{
- if (index >= riscv013_progbuf_size(target))
- return dmi_read(target, DMI_DATA0 + index - riscv013_progbuf_size(target));
return dmi_read(target, DMI_PROGBUF0 + index);
}
@@ -1936,7 +2156,6 @@ static void riscv013_on_step_or_resume(struct target *target, bool step)
uint64_t dcsr = riscv_get_register(target, GDB_REGNO_DCSR);
dcsr = set_field(dcsr, CSR_DCSR_STEP, step);
dcsr = set_field(dcsr, CSR_DCSR_EBREAKM, 1);
- dcsr = set_field(dcsr, CSR_DCSR_EBREAKH, 1);
dcsr = set_field(dcsr, CSR_DCSR_EBREAKS, 1);
dcsr = set_field(dcsr, CSR_DCSR_EBREAKU, 1);
riscv_set_register(target, GDB_REGNO_DCSR, dcsr);
@@ -1987,72 +2206,6 @@ static void riscv013_step_or_resume_current_hart(struct target *target, bool ste
abort();
}
-riscv_addr_t riscv013_progbuf_addr(struct target *target)
-{
- RISCV013_INFO(info);
- assert(info->progbuf_addr != -1);
- return info->progbuf_addr;
-}
-
-riscv_addr_t riscv013_progbuf_size(struct target *target)
-{
- RISCV013_INFO(info);
- if (info->progbuf_size == -1) {
- uint32_t acs = dmi_read(target, DMI_ABSTRACTCS);
- info->progbuf_size = get_field(acs, DMI_ABSTRACTCS_PROGSIZE);
- }
- return info->progbuf_size;
-}
-
-riscv_addr_t riscv013_data_size(struct target *target)
-{
- RISCV013_INFO(info);
- if (info->data_size == -1) {
- uint32_t acs = dmi_read(target, DMI_HARTINFO);
- info->data_size = get_field(acs, DMI_HARTINFO_DATASIZE);
- }
- return info->data_size;
-}
-
-riscv_addr_t riscv013_data_addr(struct target *target)
-{
- RISCV013_INFO(info);
- if (info->data_addr == -1) {
- uint32_t acs = dmi_read(target, DMI_HARTINFO);
- info->data_addr = get_field(acs, DMI_HARTINFO_DATAACCESS) ? get_field(acs, DMI_HARTINFO_DATAADDR) : 0;
- }
- return info->data_addr;
-}
-
-void riscv013_set_autoexec(struct target *target, unsigned index, bool enabled)
-{
- if (index >= riscv013_progbuf_size(target)) {
- LOG_DEBUG("setting bit %d in AUTOEXECDATA to %d", index, enabled);
- uint32_t aa = dmi_read(target, DMI_ABSTRACTAUTO);
- uint32_t aa_aed = get_field(aa, DMI_ABSTRACTAUTO_AUTOEXECDATA);
- aa_aed &= ~(1 << (index - riscv013_progbuf_size(target)));
- aa_aed |= (enabled << (index - riscv013_progbuf_size(target)));
- aa = set_field(aa, DMI_ABSTRACTAUTO_AUTOEXECDATA, aa_aed);
- dmi_write(target, DMI_ABSTRACTAUTO, aa);
- } else {
- LOG_DEBUG("setting bit %d in AUTOEXECPROGBUF to %d", index, enabled);
- uint32_t aa = dmi_read(target, DMI_ABSTRACTAUTO);
- uint32_t aa_aed = get_field(aa, DMI_ABSTRACTAUTO_AUTOEXECPROGBUF);
- aa_aed &= ~(1 << index);
- aa_aed |= (enabled << index);
- aa = set_field(aa, DMI_ABSTRACTAUTO_AUTOEXECPROGBUF, aa_aed);
- dmi_write(target, DMI_ABSTRACTAUTO, aa);
- }
-}
-
-int riscv013_debug_buffer_register(struct target *target, riscv_addr_t addr)
-{
- if (addr >= riscv013_data_addr(target))
- return DMI_DATA0 + (addr - riscv013_data_addr(target)) / 4;
- else
- return DMI_PROGBUF0 + (addr - riscv013_progbuf_addr(target)) / 4;
-}
-
void riscv013_clear_abstract_error(struct target *target)
{
// Wait for busy to go away.
diff --git a/src/target/riscv/riscv.c b/src/target/riscv/riscv.c
index a8fc437..b9be133 100644
--- a/src/target/riscv/riscv.c
+++ b/src/target/riscv/riscv.c
@@ -200,6 +200,9 @@ int riscv_command_timeout_sec = DEFAULT_COMMAND_TIMEOUT_SEC;
/* Wall-clock timeout after reset. Settable via RISC-V Target commands.*/
int riscv_reset_timeout_sec = DEFAULT_RESET_TIMEOUT_SEC;
+bool riscv_use_scratch_ram = false;
+uint64_t riscv_scratch_ram_address = 0;
+
static uint32_t dtmcontrol_scan(struct target *target, uint32_t out)
{
struct scan_field field;
@@ -1120,8 +1123,8 @@ int riscv_openocd_step(
}
/* Command Handlers */
-COMMAND_HANDLER(riscv_set_command_timeout_sec) {
-
+COMMAND_HANDLER(riscv_set_command_timeout_sec)
+{
if (CMD_ARGC != 1) {
LOG_ERROR("Command takes exactly 1 parameter");
return ERROR_COMMAND_SYNTAX_ERROR;
@@ -1137,11 +1140,11 @@ COMMAND_HANDLER(riscv_set_command_timeout_sec) {
return ERROR_OK;
}
-COMMAND_HANDLER(riscv_set_reset_timeout_sec) {
-
+COMMAND_HANDLER(riscv_set_reset_timeout_sec)
+{
if (CMD_ARGC != 1) {
- LOG_ERROR("Command takes exactly 1 parameter");
- return ERROR_COMMAND_SYNTAX_ERROR;
+ LOG_ERROR("Command takes exactly 1 parameter");
+ return ERROR_COMMAND_SYNTAX_ERROR;
}
int timeout = atoi(CMD_ARGV[0]);
if (timeout <= 0){
@@ -1153,6 +1156,29 @@ COMMAND_HANDLER(riscv_set_reset_timeout_sec) {
return ERROR_OK;
}
+COMMAND_HANDLER(riscv_set_scratch_ram)
+{
+ if (CMD_ARGC != 1) {
+ LOG_ERROR("Command takes exactly 1 parameter");
+ return ERROR_COMMAND_SYNTAX_ERROR;
+ }
+ if (!strcmp(CMD_ARGV[0], "none")) {
+ riscv_use_scratch_ram = false;
+ return ERROR_OK;
+ }
+
+ long long unsigned int address;
+ int result = sscanf(CMD_ARGV[0], "%Lx", &address);
+ if (result != (int) strlen(CMD_ARGV[0])) {
+ LOG_ERROR("%s is not a valid address for command.", CMD_ARGV[0]);
+ riscv_use_scratch_ram = false;
+ return ERROR_FAIL;
+ }
+
+ riscv_scratch_ram_address = address;
+ riscv_use_scratch_ram = true;
+ return ERROR_OK;
+}
static const struct command_registration riscv_exec_command_handlers[] = {
{
@@ -1161,14 +1187,21 @@ static const struct command_registration riscv_exec_command_handlers[] = {
.mode = COMMAND_ANY,
.usage = "riscv set_command_timeout_sec [sec]",
.help = "Set the wall-clock timeout (in seconds) for individual commands"
- },
- {
+ },
+ {
.name = "set_reset_timeout_sec",
.handler = riscv_set_reset_timeout_sec,
.mode = COMMAND_ANY,
.usage = "riscv set_reset_timeout_sec [sec]",
.help = "Set the wall-clock timeout (in seconds) after reset is deasserted"
},
+ {
+ .name = "set_scratch_ram",
+ .handler = riscv_set_scratch_ram,
+ .mode = COMMAND_ANY,
+ .usage = "riscv set_scratch_ram none|[address]",
+ .help = "Set address of 16 bytes of scratch RAM the debugger can use, or 'none'."
+ },
COMMAND_REGISTRATION_DONE
};
@@ -1235,7 +1268,6 @@ void riscv_info_init(struct target *target, riscv_info_t *r)
for (size_t h = 0; h < RISCV_MAX_HARTS; ++h) {
r->xlen[h] = -1;
- r->debug_buffer_addr[h] = -1;
for (size_t e = 0; e < RISCV_MAX_REGISTERS; ++e)
r->valid_saved_registers[h][e] = false;
@@ -1483,28 +1515,6 @@ size_t riscv_debug_buffer_size(struct target *target)
return r->debug_buffer_size[riscv_current_hartid(target)];
}
-riscv_addr_t riscv_debug_buffer_addr(struct target *target)
-{
- RISCV_INFO(r);
- riscv_addr_t out = r->debug_buffer_addr[riscv_current_hartid(target)];
- assert((out & 3) == 0);
- return out;
-}
-
-int riscv_debug_buffer_enter(struct target *target, struct riscv_program *program)
-{
- RISCV_INFO(r);
- r->debug_buffer_enter(target, program);
- return ERROR_OK;
-}
-
-int riscv_debug_buffer_leave(struct target *target, struct riscv_program *program)
-{
- RISCV_INFO(r);
- r->debug_buffer_leave(target, program);
- return ERROR_OK;
-}
-
int riscv_write_debug_buffer(struct target *target, int index, riscv_insn_t insn)
{
RISCV_INFO(r);
diff --git a/src/target/riscv/riscv.h b/src/target/riscv/riscv.h
index 1197cbf..4ff6127 100644
--- a/src/target/riscv/riscv.h
+++ b/src/target/riscv/riscv.h
@@ -72,15 +72,15 @@ typedef struct {
* target controls, while otherwise only a single hart is controlled. */
int trigger_unique_id[RISCV_MAX_HWBPS];
- /* The address of the debug RAM buffer. */
- riscv_addr_t debug_buffer_addr[RISCV_MAX_HARTS];
-
/* The number of entries in the debug buffer. */
int debug_buffer_size[RISCV_MAX_HARTS];
/* This avoids invalidating the register cache too often. */
bool registers_initialized;
+ /* This hart contains an implicit ebreak at the end of the program buffer. */
+ bool impebreak;
+
/* Helper functions that target the various RISC-V debug spec
* implementations. */
riscv_reg_t (*get_register)(struct target *, int hartid, int regid);
@@ -95,8 +95,6 @@ typedef struct {
void (*on_resume)(struct target *target);
void (*on_step)(struct target *target);
enum riscv_halt_reason (*halt_reason)(struct target *target);
- void (*debug_buffer_enter)(struct target *target, struct riscv_program *program);
- void (*debug_buffer_leave)(struct target *target, struct riscv_program *program);
void (*write_debug_buffer)(struct target *target, unsigned index,
riscv_insn_t d);
riscv_insn_t (*read_debug_buffer)(struct target *target, unsigned index);
@@ -113,6 +111,9 @@ extern int riscv_command_timeout_sec;
/* Wall-clock timeout after reset. Settable via RISC-V Target commands.*/
extern int riscv_reset_timeout_sec;
+extern bool riscv_use_scratch_ram;
+extern uint64_t riscv_scratch_ram_address;
+
/* Everything needs the RISC-V specific info structure, so here's a nice macro
* that provides that. */
static inline riscv_info_t *riscv_info(const struct target *target) __attribute__((unused));
@@ -213,10 +214,6 @@ int riscv_count_triggers_of_hart(struct target *target, int hartid);
/* These helper functions let the generic program interface get target-specific
* information. */
size_t riscv_debug_buffer_size(struct target *target);
-riscv_addr_t riscv_debug_buffer_addr(struct target *target);
-
-int riscv_debug_buffer_enter(struct target *target, struct riscv_program *program);
-int riscv_debug_buffer_leave(struct target *target, struct riscv_program *program);
riscv_insn_t riscv_read_debug_buffer(struct target *target, int index);
riscv_addr_t riscv_read_debug_buffer_x(struct target *target, int index);