}
}
-typedef enum {
- RC_XPR,
- RC_PC,
- RC_FPR,
- RC_CSR
-} register_class_t;
-
-typedef struct {
- register_class_t clss;
- int index;
-} register_access_t;
-
// gdb's register list is defined in riscv_gdb_reg_names gdb/riscv-tdep.c in
-// its source tree. The definition here must match that one.
-const register_access_t register_access[] = {
- { RC_XPR, 0 },
- { RC_XPR, 1 },
- { RC_XPR, 2 },
- { RC_XPR, 3 },
- { RC_XPR, 4 },
- { RC_XPR, 5 },
- { RC_XPR, 6 },
- { RC_XPR, 7 },
- { RC_XPR, 8 },
- { RC_XPR, 9 },
- { RC_XPR, 10 },
- { RC_XPR, 11 },
- { RC_XPR, 12 },
- { RC_XPR, 13 },
- { RC_XPR, 14 },
- { RC_XPR, 15 },
- { RC_XPR, 16 },
- { RC_XPR, 17 },
- { RC_XPR, 18 },
- { RC_XPR, 19 },
- { RC_XPR, 20 },
- { RC_XPR, 21 },
- { RC_XPR, 22 },
- { RC_XPR, 23 },
- { RC_XPR, 24 },
- { RC_XPR, 25 },
- { RC_XPR, 26 },
- { RC_XPR, 27 },
- { RC_XPR, 28 },
- { RC_XPR, 29 },
- { RC_XPR, 30 },
- { RC_XPR, 31 },
- { RC_PC, 0 },
- { RC_FPR, 0 },
- { RC_FPR, 1 },
- { RC_FPR, 2 },
- { RC_FPR, 3 },
- { RC_FPR, 4 },
- { RC_FPR, 5 },
- { RC_FPR, 6 },
- { RC_FPR, 7 },
- { RC_FPR, 8 },
- { RC_FPR, 9 },
- { RC_FPR, 10 },
- { RC_FPR, 11 },
- { RC_FPR, 12 },
- { RC_FPR, 13 },
- { RC_FPR, 14 },
- { RC_FPR, 15 },
- { RC_FPR, 16 },
- { RC_FPR, 17 },
- { RC_FPR, 18 },
- { RC_FPR, 19 },
- { RC_FPR, 20 },
- { RC_FPR, 21 },
- { RC_FPR, 22 },
- { RC_FPR, 23 },
- { RC_FPR, 24 },
- { RC_FPR, 25 },
- { RC_FPR, 26 },
- { RC_FPR, 27 },
- { RC_FPR, 28 },
- { RC_FPR, 29 },
- { RC_FPR, 30 },
- { RC_FPR, 31 },
-
-#define DECLARE_CSR(name, num) { RC_CSR, num },
-#include "encoding.h"
-#undef DECLARE_CSR
+// its source tree. We must interpret the numbers the same here.
+enum {
+ REG_XPR0 = 0,
+ REG_XPR31 = 31,
+ REG_PC = 32,
+ REG_FPR0 = 33,
+ REG_FPR31 = 64,
+ REG_CSR0 = 65,
+ REG_CSR4095 = 4160,
+ REG_END = 4161
};
void gdbserver_t::handle_register_read(const std::vector<uint8_t> &packet)
if (*iter != '#')
return send_packet("E01");
- if (n >= sizeof(register_access) / sizeof(*register_access))
- return send_packet("E02");
-
processor_t *p = sim->get_core(0);
send("$");
running_checksum = 0;
- register_access_t access = register_access[n];
- switch (access.clss) {
- case RC_XPR:
- send(p->state.XPR[access.index]);
- break;
- case RC_PC:
- send(p->state.pc);
- break;
- case RC_FPR:
- send(p->state.FPR[access.index]);
- break;
- case RC_CSR:
- try {
- send(p->get_csr(access.index));
- } catch(trap_t& t) {
- send((reg_t) 0);
- }
- break;
+ if (n >= REG_XPR0 && n <= REG_XPR31) {
+ send(p->state.XPR[n - REG_XPR0]);
+ } else if (n == REG_PC) {
+ send(p->state.pc);
+ } else if (n >= REG_FPR0 && n <= REG_FPR31) {
+ send(p->state.FPR[n - REG_FPR0]);
+ } else if (n >= REG_CSR0 && n <= REG_CSR4095) {
+ try {
+ send(p->get_csr(n - REG_CSR0));
+ } catch(trap_t& t) {
+ // TODO, can we return error here, and update 'info reg all' to display
+ // it sensibly?
+ send((reg_t) 0);
+ }
+ } else {
+ return send_packet("E02");
}
send_running_checksum();
return send_packet("E05");
iter++;
- if (n >= sizeof(register_access) / sizeof(*register_access))
- return send_packet("E07");
-
reg_t value = consume_hex_number_le(iter, packet.end());
if (*iter != '#')
return send_packet("E06");
processor_t *p = sim->get_core(0);
- register_access_t access = register_access[n];
- switch (access.clss) {
- case RC_XPR:
- p->state.XPR.write(access.index, value);
- break;
- case RC_PC:
- p->state.pc = value;
- break;
- case RC_FPR:
- p->state.FPR.write(access.index, value);
- break;
- case RC_CSR:
- try {
- p->set_csr(access.index, value);
- } catch(trap_t& t) {
- return send_packet("EFF");
- }
- break;
+ if (n >= REG_XPR0 && n <= REG_XPR31) {
+ p->state.XPR.write(n - REG_XPR0, value);
+ } else if (n == REG_PC) {
+ p->state.pc = value;
+ } else if (n >= REG_FPR0 && n <= REG_FPR31) {
+ p->state.FPR.write(n - REG_FPR0, value);
+ } else if (n >= REG_CSR0 && n <= REG_CSR4095) {
+ try {
+ p->set_csr(n - REG_CSR0, value);
+ } catch(trap_t& t) {
+ return send_packet("EFF");
+ }
+ } else {
+ return send_packet("E07");
}
return send_packet("OK");
# The time register should always be changing.
last_time = None
for _ in range(5):
- time = self.gdb.command("p $time").split('=')[-1]
+ time = self.gdb.p("$time")
self.assertNotEqual(time, last_time)
last_time = time
self.gdb.command("stepi")
self.assertEqual(self.gdb.x("data+%d" % (8*n), 'g'),
n*0xdeadbeef+17)
+ def test_write_csrs(self):
+ # As much a test of gdb as of the simulator.
+ self.gdb.p("$mscratch=0")
+ self.gdb.stepi()
+ self.assertEqual(self.gdb.p("$mscratch"), 0)
+ self.gdb.p("$mscratch=123")
+ self.gdb.stepi()
+ self.assertEqual(self.gdb.p("$mscratch"), 123)
+
if __name__ == '__main__':
unittest.main()