ysyx-workbench/npc/csrc/Flow/gdbstub_wrapper.cpp

extern "C" {
#include <gdbstub.h>
}
#include "components.hpp"
#include <VFlow.h>
#include <config.hpp>
#include <cstdint>
#include <cstdlib>
#include <devices.hpp>
#include <string>
#include <types.h>
#include <vl_wrapper.hpp>
#include <vpi_user.h>
#include <vpi_wrapper.hpp>

using Registers = _RegistersVPI<uint32_t, 32>;
using VlModule = VlModuleInterfaceCommon<VFlow, Registers>;

// SDB::SDB<NPC::npc_interface> sdb_dut;
bool g_skip_memcheck = false;
VlModule *top;
Registers *regs;
vpiHandle pc = nullptr;

const size_t PMEM_START = 0x80000000;
const size_t PMEM_END = 0x87ffffff;

extern "C" {
/* === Memory Access === */
using MMap = MemoryMap<Memory<128 * 1024>, Devices::DeviceMap>;
void *pmem_get() {
  static Devices::DeviceMap devices{
      new Devices::Serial(0x10000000, 0x1000),
      new Devices::RTC(0x10001000, 0x1000),
  };
  static auto pmem = new MemoryMap<Memory<128 * 1024>, Devices::DeviceMap>(
      std::make_unique<Memory<128 * 1024>>(config.memory_file, true, PMEM_START,
                                           PMEM_END),
      std::make_unique<Devices::DeviceMap>(devices));
  return pmem;
}

int pmem_read(int raddr, int rmask) {
  void *pmem = pmem_get();
  auto mem = static_cast<MMap *>(pmem);
  // TODO: Do memory difftest at memory read and write to diagnose at a finer
  // granularity
  if (g_skip_memcheck)
    return mem->read(PMEM_START, rmask);
  return mem->read(raddr, rmask);
}

void pmem_write(int waddr, int wdata, char wmask) {
  void *pmem = pmem_get();
  auto mem = static_cast<MMap *>(pmem);
  return mem->write((std::size_t)waddr, wdata, wmask);
}

/* === For gdbstub === */

int npc_read_mem(void *args, size_t addr, size_t len, void *val) {
  void *pmem = pmem_get();
  auto mmap = static_cast<MMap *>(pmem);
  return mmap->copy_to(addr, (uint8_t *)val, len);
}

int npc_write_mem(void *args, size_t addr, size_t len, void *val) {
  void *pmem = pmem_get();
  auto mmap = static_cast<MMap *>(pmem);
  return mmap->copy_from(addr, (uint8_t *)val, len);
}

int npc_read_reg(void *args, int regno, size_t *value) {
  if (regno == 32)
    *value = regs->get_pc();
  else
    *value = (*regs)[regno];
  return 0;
}

int npc_write_reg(void *args, int regno, size_t value) { return 1; }

inline void breakpoint_to_action(const Breakpoint *bp, gdb_action_t *res) {
  if (bp == nullptr) {
    res->reason = gdb_action_t::ACT_NONE;
    return;
  }
  switch (bp->type) {
  case BP_SOFTWARE:
    res->reason = gdb_action_t::ACT_BREAKPOINT;
    break;
  case BP_ACCESS:
    res->reason = gdb_action_t::ACT_WATCH;
    break;
  case BP_WRITE:
    res->reason = gdb_action_t::ACT_WWATCH;
    break;
  case BP_READ:
    res->reason = gdb_action_t::ACT_RWATCH;
    break;
  }
  res->data = bp->addr;
}

void npc_cont(void *args, gdb_action_t *res) {
  DbgState *dbg = (DbgState *)args;
  const Breakpoint *stopped_at = nullptr;
  stopped_at = top->cont(*dbg->bp);
  breakpoint_to_action(stopped_at, res);
}

void npc_stepi(void *args, gdb_action_t *res) {
  DbgState *dbg = (DbgState *)args;
  const Breakpoint *stopped_at = nullptr;
  stopped_at = top->stepi(*dbg->bp);
  breakpoint_to_action(stopped_at, res);
}

bool npc_set_bp(void *args, size_t addr, bp_type_t type) {
  DbgState *dbg = (DbgState *)args;
  for (const auto &bp : *dbg->bp) {
    if (bp.addr == addr && bp.type == type) {
      return true;
    }
  }
  dbg->bp->push_back({.addr = addr, .type = type});
  return true;
}

bool npc_del_bp(void *args, size_t addr, bp_type_t type) {
  DbgState *dbg = (DbgState *)args;
  for (auto it = dbg->bp->begin(); it != dbg->bp->end(); it++) {
    if (it->addr == addr && it->type == type) {
      std::swap(*it, *dbg->bp->rbegin());
      dbg->bp->pop_back();
      return true;
    }
  }
  return false;
}

void npc_on_interrupt(void *args) { ; }

void npc_init(void *args) {
  DbgState *dbg = (DbgState *)args;
  void *mem = pmem_get();
  dbg->bp = new std::vector<Breakpoint>;
  dbg->cmd_return_buf = new std::string;

  top = new VlModule;
  regs = new Registers("TOP.Flow.ID.regs_regFile_",
                       "TOP.Flow.WB.msgio_in_bits_pc");
  top->setup(config.wavefile, regs);
  top->reset_eval(10);
}

char *npc_monitor(void *args, char **argv, int argc) {
  DbgState *dbg = (DbgState *)args;
  std::string *cmd_return_buf = dbg->cmd_return_buf;

  if (strncmp(argv[0], "trace", 5) == 0) {
    if (strncmp(argv[1], "on", 2) == 0) {
      *cmd_return_buf = "Tracing turned on\n";
      if (!top->start_trace())
        *cmd_return_buf = "Failed to turn on tracing\n";
      return cmd_return_buf->data();
    } else if (strncmp(argv[1], "off", 3) == 0) {
      *cmd_return_buf = "Tracing turned off\n";
      if (!top->end_trace())
        *cmd_return_buf = "Failed to turn on tracing\n";
      return cmd_return_buf->data();
    }
  }

  *cmd_return_buf = "Command not found\n";
  return cmd_return_buf->data();
}

bool npc_do_difftest = true;

static gdbstub_t gdbstub_priv;
arch_info_t npc_isa_arch_info{
    .target_desc = strdup(TARGET_RV32), .reg_num = 32, .reg_byte = 4};

size_t npc_dbg_state_size = sizeof(DbgState);

} // extern "C"

int gdbstub_loop() {
  DbgState dbg;

  target_ops npc_gdbstub_ops = {.cont = npc_cont,
                                .stepi = npc_stepi,
                                .read_reg = npc_read_reg,
                                .write_reg = npc_write_reg,
                                .read_mem = npc_read_mem,
                                .write_mem = npc_write_mem,
                                .set_bp = npc_set_bp,
                                .del_bp = npc_del_bp,
                                .on_interrupt = NULL};

  if (!config.do_debug) {
    gdb_action_t res;
    npc_init(&dbg);
    npc_cont(&dbg, &res);
    return !(res.reason == gdb_action_t::ACT_SHUTDOWN);
  }

  if (!gdbstub_init(&gdbstub_priv, &npc_gdbstub_ops,
                    (arch_info_t)npc_isa_arch_info, NULL,
                    config.gdbsocket.c_str())) {
    return EINVAL;
  }
  npc_init(&dbg);

  bool success = gdbstub_run(&gdbstub_priv, &dbg);
  // gdbstub_close(&gdbstub_priv);
  return !success;
}
npc: split gdbstub api into seperate file 2024-08-01 10:53:17 +00:00			`extern "C" {`
			`#include <gdbstub.h>`
			`}`
			`#include "components.hpp"`
			`#include <VFlow.h>`
			`#include <config.hpp>`
			`#include <cstdint>`
			`#include <cstdlib>`
			`#include <devices.hpp>`
npc,fix: bugs of new arch in cpu-tests 2024-09-06 06:56:10 +00:00			`#include <string>`
npc: split gdbstub api into seperate file 2024-08-01 10:53:17 +00:00			`#include <types.h>`
			`#include <vl_wrapper.hpp>`
			`#include <vpi_user.h>`
			`#include <vpi_wrapper.hpp>`

			`using Registers = _RegistersVPI<uint32_t, 32>;`
			`using VlModule = VlModuleInterfaceCommon<VFlow, Registers>;`

			`// SDB::SDB<NPC::npc_interface> sdb_dut;`
			`bool g_skip_memcheck = false;`
			`VlModule *top;`
			`Registers *regs;`
			`vpiHandle pc = nullptr;`

			`const size_t PMEM_START = 0x80000000;`
			`const size_t PMEM_END = 0x87ffffff;`

			`extern "C" {`
			`/* === Memory Access === */`
			`using MMap = MemoryMap<Memory<128 * 1024>, Devices::DeviceMap>;`
			`void *pmem_get() {`
			`static Devices::DeviceMap devices{`
			`new Devices::Serial(0x10000000, 0x1000),`
			`new Devices::RTC(0x10001000, 0x1000),`
			`};`
			`static auto pmem = new MemoryMap<Memory<128 * 1024>, Devices::DeviceMap>(`
			`std::make_unique<Memory<128 * 1024>>(config.memory_file, true, PMEM_START,`
			`PMEM_END),`
			`std::make_unique<Devices::DeviceMap>(devices));`
			`return pmem;`
			`}`

npc,fix: bugs of new arch in cpu-tests 2024-09-06 06:56:10 +00:00			`int pmem_read(int raddr, int rmask) {`
npc: split gdbstub api into seperate file 2024-08-01 10:53:17 +00:00			`void *pmem = pmem_get();`
			`auto mem = static_cast<MMap *>(pmem);`
			`// TODO: Do memory difftest at memory read and write to diagnose at a finer`
			`// granularity`
			`if (g_skip_memcheck)`
npc,fix: bugs of new arch in cpu-tests 2024-09-06 06:56:10 +00:00			`return mem->read(PMEM_START, rmask);`
			`return mem->read(raddr, rmask);`
npc: split gdbstub api into seperate file 2024-08-01 10:53:17 +00:00			`}`

			`void pmem_write(int waddr, int wdata, char wmask) {`
			`void *pmem = pmem_get();`
			`auto mem = static_cast<MMap *>(pmem);`
			`return mem->write((std::size_t)waddr, wdata, wmask);`
			`}`

			`/* === For gdbstub === */`

			`int npc_read_mem(void args, size_t addr, size_t len, void val) {`
			`void *pmem = pmem_get();`
			`auto mmap = static_cast<MMap *>(pmem);`
			`return mmap->copy_to(addr, (uint8_t *)val, len);`
			`}`

			`int npc_write_mem(void args, size_t addr, size_t len, void val) {`
			`void *pmem = pmem_get();`
			`auto mmap = static_cast<MMap *>(pmem);`
			`return mmap->copy_from(addr, (uint8_t *)val, len);`
			`}`

			`int npc_read_reg(void args, int regno, size_t value) {`
			`if (regno == 32)`
			`*value = regs->get_pc();`
			`else`
			`value = (regs)[regno];`
			`return 0;`
			`}`

			`int npc_write_reg(void *args, int regno, size_t value) { return 1; }`

			`inline void breakpoint_to_action(const Breakpoint bp, gdb_action_t res) {`
			`if (bp == nullptr) {`
			`res->reason = gdb_action_t::ACT_NONE;`
			`return;`
			`}`
			`switch (bp->type) {`
			`case BP_SOFTWARE:`
			`res->reason = gdb_action_t::ACT_BREAKPOINT;`
			`break;`
			`case BP_ACCESS:`
			`res->reason = gdb_action_t::ACT_WATCH;`
			`break;`
			`case BP_WRITE:`
			`res->reason = gdb_action_t::ACT_WWATCH;`
			`break;`
			`case BP_READ:`
			`res->reason = gdb_action_t::ACT_RWATCH;`
			`break;`
			`}`
			`res->data = bp->addr;`
			`}`

			`void npc_cont(void args, gdb_action_t res) {`
			`DbgState dbg = (DbgState )args;`
			`const Breakpoint *stopped_at = nullptr;`
			`stopped_at = top->cont(*dbg->bp);`
			`breakpoint_to_action(stopped_at, res);`
			`}`

			`void npc_stepi(void args, gdb_action_t res) {`
			`DbgState dbg = (DbgState )args;`
			`const Breakpoint *stopped_at = nullptr;`
			`stopped_at = top->stepi(*dbg->bp);`
			`breakpoint_to_action(stopped_at, res);`
			`}`

			`bool npc_set_bp(void *args, size_t addr, bp_type_t type) {`
			`DbgState dbg = (DbgState )args;`
			`for (const auto &bp : *dbg->bp) {`
			`if (bp.addr == addr && bp.type == type) {`
			`return true;`
			`}`
			`}`
			`dbg->bp->push_back({.addr = addr, .type = type});`
			`return true;`
			`}`

			`bool npc_del_bp(void *args, size_t addr, bp_type_t type) {`
			`DbgState dbg = (DbgState )args;`
			`for (auto it = dbg->bp->begin(); it != dbg->bp->end(); it++) {`
			`if (it->addr == addr && it->type == type) {`
			`std::swap(it, dbg->bp->rbegin());`
			`dbg->bp->pop_back();`
			`return true;`
			`}`
			`}`
			`return false;`
			`}`

			`void npc_on_interrupt(void *args) { ; }`

			`void npc_init(void *args) {`
			`DbgState dbg = (DbgState )args;`
			`void *mem = pmem_get();`
			`dbg->bp = new std::vector<Breakpoint>;`
npc,fix: bugs of new arch in cpu-tests 2024-09-06 06:56:10 +00:00			`dbg->cmd_return_buf = new std::string;`
npc: split gdbstub api into seperate file 2024-08-01 10:53:17 +00:00
			`top = new VlModule;`
npc,fix: bugs of new arch in cpu-tests 2024-09-06 06:56:10 +00:00			`regs = new Registers("TOP.Flow.ID.regs_regFile_",`
			`"TOP.Flow.WB.msgio_in_bits_pc");`
npc: split gdbstub api into seperate file 2024-08-01 10:53:17 +00:00			`top->setup(config.wavefile, regs);`
			`top->reset_eval(10);`
			`}`

npc,fix: bugs of new arch in cpu-tests 2024-09-06 06:56:10 +00:00			`char npc_monitor(void args, char **argv, int argc) {`
			`DbgState dbg = (DbgState )args;`
			`std::string *cmd_return_buf = dbg->cmd_return_buf;`

			`if (strncmp(argv[0], "trace", 5) == 0) {`
			`if (strncmp(argv[1], "on", 2) == 0) {`
			`*cmd_return_buf = "Tracing turned on\n";`
			`if (!top->start_trace())`
			`*cmd_return_buf = "Failed to turn on tracing\n";`
			`return cmd_return_buf->data();`
			`} else if (strncmp(argv[1], "off", 3) == 0) {`
			`*cmd_return_buf = "Tracing turned off\n";`
			`if (!top->end_trace())`
			`*cmd_return_buf = "Failed to turn on tracing\n";`
			`return cmd_return_buf->data();`
			`}`
			`}`

			`*cmd_return_buf = "Command not found\n";`
			`return cmd_return_buf->data();`
			`}`

npc: split gdbstub api into seperate file 2024-08-01 10:53:17 +00:00			`bool npc_do_difftest = true;`

			`static gdbstub_t gdbstub_priv;`
			`arch_info_t npc_isa_arch_info{`
			`.target_desc = strdup(TARGET_RV32), .reg_num = 32, .reg_byte = 4};`

			`size_t npc_dbg_state_size = sizeof(DbgState);`

			`} // extern "C"`

			`int gdbstub_loop() {`
			`DbgState dbg;`

			`target_ops npc_gdbstub_ops = {.cont = npc_cont,`
			`.stepi = npc_stepi,`
			`.read_reg = npc_read_reg,`
			`.write_reg = npc_write_reg,`
			`.read_mem = npc_read_mem,`
			`.write_mem = npc_write_mem,`
			`.set_bp = npc_set_bp,`
			`.del_bp = npc_del_bp,`
			`.on_interrupt = NULL};`

			`if (!config.do_debug) {`
			`gdb_action_t res;`
			`npc_init(&dbg);`
			`npc_cont(&dbg, &res);`
			`return !(res.reason == gdb_action_t::ACT_SHUTDOWN);`
			`}`

			`if (!gdbstub_init(&gdbstub_priv, &npc_gdbstub_ops,`
			`(arch_info_t)npc_isa_arch_info, NULL,`
			`config.gdbsocket.c_str())) {`
			`return EINVAL;`
			`}`
			`npc_init(&dbg);`

			`bool success = gdbstub_run(&gdbstub_priv, &dbg);`
			`// gdbstub_close(&gdbstub_priv);`
			`return !success;`
			`}`