#include #include #include #include #include #include #include #include #include #include #include #include #include "elf.h" #include "sail.h" #include "rts.h" #include "riscv_platform.h" #include "riscv_platform_impl.h" #include "riscv_sail.h" #ifdef ENABLE_SPIKE #include "tv_spike_intf.h" #else struct tv_spike_t; #endif const char *RV64ISA = "RV64IMAC"; const char *RV32ISA = "RV32IMAC"; /* Selected CSRs from riscv-isa-sim/riscv/encoding.h */ #define CSR_STVEC 0x105 #define CSR_SEPC 0x141 #define CSR_SCAUSE 0x142 #define CSR_STVAL 0x143 #define CSR_MSTATUS 0x300 #define CSR_MISA 0x301 #define CSR_MEDELEG 0x302 #define CSR_MIDELEG 0x303 #define CSR_MIE 0x304 #define CSR_MTVEC 0x305 #define CSR_MEPC 0x341 #define CSR_MCAUSE 0x342 #define CSR_MTVAL 0x343 #define CSR_MIP 0x344 static bool do_dump_dts = false; static bool do_show_times = false; struct tv_spike_t *s = NULL; char *term_log = NULL; char *dtb_file = NULL; unsigned char *dtb = NULL; size_t dtb_len = 0; #ifdef RVFI_DII static bool rvfi_dii = false; static int rvfi_dii_port; static int rvfi_dii_sock; #endif unsigned char *spike_dtb = NULL; size_t spike_dtb_len = 0; char *sig_file = NULL; uint64_t mem_sig_start = 0; uint64_t mem_sig_end = 0; bool config_print_instr = true; bool config_print_reg = true; bool config_print_mem_access = true; bool config_print_platform = true; void set_config_print(char *var, bool val) { if (optarg == NULL || strcmp("all", optarg) == 0) { config_print_instr = val; config_print_mem_access = val; config_print_reg = val; config_print_platform = val; } else if (strcmp("instr", optarg) == 0) { config_print_instr = val; } else if (strcmp("reg", optarg) == 0) { config_print_reg = val; } else if (strcmp("mem", optarg) == 0) { config_print_mem_access = val; } else if (strcmp("platform", optarg) == 0) { config_print_platform = val; } else { fprintf(stderr, "Unknown trace category: '%s' (should be instr|reg|mem|platform|all)\n", var); exit(1); } } struct timeval init_start, init_end, run_end; int total_insns = 0; int insn_limit = 0; static struct option options[] = { {"enable-dirty-update", no_argument, 0, 'd'}, {"enable-misaligned", no_argument, 0, 'm'}, {"enable-pmp", no_argument, 0, 'P'}, {"ram-size", required_argument, 0, 'z'}, {"disable-compressed", no_argument, 0, 'C'}, {"disable-writable-misa", no_argument, 0, 'I'}, {"mtval-has-illegal-inst-bits", no_argument, 0, 'i'}, {"device-tree-blob", required_argument, 0, 'b'}, {"terminal-log", required_argument, 0, 't'}, {"show-times", required_argument, 0, 'p'}, {"report-arch", no_argument, 0, 'a'}, {"test-signature", required_argument, 0, 'T'}, #ifdef RVFI_DII {"rvfi-dii", required_argument, 0, 'r'}, #endif {"help", no_argument, 0, 'h'}, {"trace", optional_argument, 0, 'v'}, {"no-trace", optional_argument, 0, 'V'}, {"inst-limit", required_argument, 0, 'l'}, {0, 0, 0, 0} }; static void print_usage(const char *argv0, int ec) { #ifdef RVFI_DII fprintf(stdout, "Usage: %s [options] \n %s [options] -r \n", argv0, argv0); #else fprintf(stdout, "Usage: %s [options] \n", argv0); #endif struct option *opt = options; while (opt->name) { fprintf(stdout, "\t -%c\t --%s\n", (char)opt->val, opt->name); opt++; } exit(ec); } static void report_arch(void) { fprintf(stdout, "RV%" PRIu64 "\n", zxlen_val); exit(0); } static bool is_32bit_model(void) { return zxlen_val == 32; } static void dump_dts(void) { #ifdef ENABLE_SPIKE size_t dts_len = 0; const char *isa = is_32bit_model() ? RV32ISA : RV64ISA; struct tv_spike_t *s = tv_init(isa, rv_ram_size, 0); tv_get_dts(s, NULL, &dts_len); if (dts_len > 0) { unsigned char *dts = (unsigned char *)malloc(dts_len + 1); dts[dts_len] = '\0'; tv_get_dts(s, dts, &dts_len); fprintf(stdout, "%s\n", dts); } #else fprintf(stdout, "Spike linkage is currently needed to generate DTS.\n"); #endif exit(0); } static void read_dtb(const char *path) { int fd = open(path, O_RDONLY); if (fd < 0) { fprintf(stderr, "Unable to read DTB file %s: %s\n", path, strerror(errno)); exit(1); } struct stat st; if (fstat(fd, &st) < 0) { fprintf(stderr, "Unable to stat DTB file %s: %s\n", path, strerror(errno)); exit(1); } char *m = (char *)mmap(NULL, st.st_size, PROT_READ, MAP_PRIVATE, fd, 0); if (m == MAP_FAILED) { fprintf(stderr, "Unable to map DTB file %s: %s\n", path, strerror(errno)); exit(1); } dtb = (unsigned char *)malloc(st.st_size); if (dtb == NULL) { fprintf(stderr, "Cannot allocate DTB from file %s!\n", path); exit(1); } memcpy(dtb, m, st.st_size); dtb_len = st.st_size; munmap(m, st.st_size); close(fd); fprintf(stdout, "Read %" PRIi64 " bytes of DTB from %s.\n", dtb_len, path); } char *process_args(int argc, char **argv) { int c, idx = 1; uint64_t ram_size = 0; while(true) { c = getopt_long(argc, argv, "admCIispz:b:t:v:hr:T:V::v::l:", options, &idx); if (c == -1) break; switch (c) { case 'a': report_arch(); break; case 'd': fprintf(stderr, "enabling dirty update.\n"); rv_enable_dirty_update = true; break; case 'm': fprintf(stderr, "enabling misaligned access.\n"); rv_enable_misaligned = true; break; case 'P': fprintf(stderr, "enabling PMP support.\n"); rv_enable_pmp = true; break; case 'C': fprintf(stderr, "disabling RVC compressed instructions.\n"); rv_enable_rvc = false; break; case 'I': fprintf(stderr, "disabling writable misa CSR.\n"); rv_enable_writable_misa = false; break; case 'i': fprintf(stderr, "enabling storing illegal instruction bits in mtval.\n"); rv_mtval_has_illegal_inst_bits = true; break; case 's': do_dump_dts = true; break; case 'p': fprintf(stderr, "will show execution times on completion.\n"); do_show_times = true; break; case 'z': ram_size = atol(optarg); if (ram_size) { fprintf(stderr, "setting ram-size to %" PRIu64 " MB\n", ram_size); rv_ram_size = ram_size << 20; } else { fprintf(stderr, "invalid ram-size '%s' provided.\n", optarg); exit(1); } break; case 'b': dtb_file = strdup(optarg); fprintf(stderr, "using %s as DTB file.\n", dtb_file); break; case 't': term_log = strdup(optarg); fprintf(stderr, "using %s for terminal output.\n", term_log); break; case 'T': sig_file = strdup(optarg); fprintf(stderr, "using %s for test-signature output.\n", sig_file); break; case 'h': print_usage(argv[0], 0); break; #ifdef RVFI_DII case 'r': rvfi_dii = true; rvfi_dii_port = atoi(optarg); fprintf(stderr, "using %d as RVFI port.\n", rvfi_dii_port); break; #endif case 'V': set_config_print(optarg, false); break; case 'v': set_config_print(optarg, true); break; case 'l': insn_limit = atoi(optarg); break; case '?': print_usage(argv[0], 1); break; } } if (do_dump_dts) dump_dts(); #ifdef RVFI_DII if (idx > argc || (idx == argc && !rvfi_dii)) print_usage(argv[0], 0); #else if (optind >= argc) { fprintf(stderr, "No elf file provided.\n"); print_usage(argv[0], 0); } #endif if (dtb_file) read_dtb(dtb_file); #ifdef RVFI_DII if (!rvfi_dii) #endif fprintf(stdout, "Running file %s.\n", argv[optind]); return argv[optind]; } void check_elf(bool is32bit) { if (is32bit) { if (zxlen_val != 32) { fprintf(stderr, "32-bit ELF not supported by RV%" PRIu64 " model.\n", zxlen_val); exit(1); } } else { if (zxlen_val != 64) { fprintf(stderr, "64-bit ELF not supported by RV%" PRIu64 " model.\n", zxlen_val); exit(1); } } } uint64_t load_sail(char *f) { bool is32bit; uint64_t entry; uint64_t begin_sig, end_sig; load_elf(f, &is32bit, &entry); check_elf(is32bit); fprintf(stdout, "ELF Entry @ 0x%" PRIx64 "\n", entry); /* locate htif ports */ if (lookup_sym(f, "tohost", &rv_htif_tohost) < 0) { fprintf(stderr, "Unable to locate htif tohost port.\n"); exit(1); } fprintf(stderr, "tohost located at 0x%0" PRIx64 "\n", rv_htif_tohost); /* locate test-signature locations if any */ if (!lookup_sym(f, "begin_signature", &begin_sig)) { fprintf(stdout, "begin_signature: 0x%0" PRIx64 "\n", begin_sig); mem_sig_start = begin_sig; } if (!lookup_sym(f, "end_signature", &end_sig)) { fprintf(stdout, "end_signature: 0x%0" PRIx64 "\n", end_sig); mem_sig_end = end_sig; } return entry; } void init_spike(const char *f, uint64_t entry, uint64_t ram_size) { #ifdef ENABLE_SPIKE bool mismatch = false; const char *isa = is_32bit_model() ? RV32ISA : RV64ISA; s = tv_init(isa, ram_size, 1); if (tv_is_dirty_enabled(s) != rv_enable_dirty_update) { mismatch = true; fprintf(stderr, "inconsistent enable-dirty-update setting: spike %s, sail %s\n", tv_is_dirty_enabled(s) ? "on" : "off", rv_enable_dirty_update ? "on" : "off"); } if (tv_is_misaligned_enabled(s) != rv_enable_misaligned) { mismatch = true; fprintf(stderr, "inconsistent enable-misaligned-access setting: spike %s, sail %s\n", tv_is_misaligned_enabled(s) ? "on" : "off", rv_enable_misaligned ? "on" : "off"); } if (tv_ram_size(s) != rv_ram_size) { mismatch = true; fprintf(stderr, "inconsistent ram-size setting: spike 0x%" PRIx64 ", sail 0x%" PRIx64 "\n", tv_ram_size(s), rv_ram_size); } if (mismatch) exit(1); /* The initialization order below matters. */ tv_set_verbose(s, 1); tv_set_dtb_in_rom(s, 1); tv_load_elf(s, f); tv_reset(s); /* sync the insns per tick */ rv_insns_per_tick = tv_get_insns_per_tick(s); /* get DTB from spike */ tv_get_dtb(s, NULL, &spike_dtb_len); if (spike_dtb_len > 0) { spike_dtb = (unsigned char *)malloc(spike_dtb_len + 1); spike_dtb[spike_dtb_len] = '\0'; if (!tv_get_dtb(s, spike_dtb, &spike_dtb_len)) { fprintf(stderr, "Got %" PRIu64 " bytes of dtb at %p\n", spike_dtb_len, spike_dtb); } else { fprintf(stderr, "Error getting DTB from Spike.\n"); exit(1); } } else { fprintf(stderr, "No DTB available from Spike.\n"); } #else s = NULL; #endif } void tick_spike() { #ifdef ENABLE_SPIKE tv_tick_clock(s); tv_step_io(s); #endif } void init_sail_reset_vector(uint64_t entry) { #define RST_VEC_SIZE 8 uint32_t reset_vec[RST_VEC_SIZE] = { 0x297, // auipc t0,0x0 0x28593 + (RST_VEC_SIZE * 4 << 20), // addi a1, t0, &dtb 0xf1402573, // csrr a0, mhartid is_32bit_model() ? 0x0182a283u : // lw t0,24(t0) 0x0182b283u, // ld t0,24(t0) 0x28067, // jr t0 0, (uint32_t) (entry & 0xffffffff), (uint32_t) (entry >> 32) }; rv_rom_base = DEFAULT_RSTVEC; uint64_t addr = rv_rom_base; for (int i = 0; i < sizeof(reset_vec); i++) write_mem(addr++, (uint64_t)((char *)reset_vec)[i]); if (dtb && dtb_len) { for (size_t i = 0; i < dtb_len; i++) write_mem(addr++, dtb[i]); } #ifdef ENABLE_SPIKE if (dtb && dtb_len) { // Ensure that Spike's DTB matches the one provided. bool matched = dtb_len == spike_dtb_len; if (matched) { for (size_t i = 0; i < dtb_len; i++) matched = matched && (dtb[i] == spike_dtb[i]); } if (!matched) { fprintf(stderr, "Provided DTB does not match Spike's!\n"); exit(1); } } else { if (spike_dtb_len > 0) { // Use the DTB from Spike. for (size_t i = 0; i < spike_dtb_len; i++) write_mem(addr++, spike_dtb[i]); } else { fprintf(stderr, "Running without rom device tree.\n"); } } #endif /* zero-fill to page boundary */ const int align = 0x1000; uint64_t rom_end = (addr + align -1)/align * align; for (int i = addr; i < rom_end; i++) write_mem(addr++, 0); /* set rom size */ rv_rom_size = rom_end - rv_rom_base; /* boot at reset vector */ zPC = rv_rom_base; } void preinit_sail() { model_init(); } void init_sail(uint64_t elf_entry) { zinit_model(UNIT); #ifdef RVFI_DII if (rvfi_dii) { rv_ram_base = UINT64_C(0x80000000); rv_ram_size = UINT64_C(0x10000); rv_rom_base = UINT64_C(0); rv_rom_size = UINT64_C(0); rv_clint_base = UINT64_C(0); rv_clint_size = UINT64_C(0); rv_htif_tohost = UINT64_C(0); zPC = elf_entry; } else #endif init_sail_reset_vector(elf_entry); // this is probably unnecessary now; remove if (!rv_enable_rvc) z_set_Misa_C(&zmisa, 0); } /* reinitialize to clear state and memory, typically across tests runs */ void reinit_sail(uint64_t elf_entry) { model_fini(); model_init(); init_sail(elf_entry); } int init_check(struct tv_spike_t *s) { int passed = 1; #ifdef ENABLE_SPIKE passed &= tv_check_csr(s, CSR_MISA, zmisa.zMisa_chunk_0); #endif return passed; } void write_signature(const char *file) { if (mem_sig_start >= mem_sig_end) { fprintf(stderr, "Invalid signature region [0x%0" PRIx64 ",0x%0" PRIx64 "] to %s.\n", mem_sig_start, mem_sig_end, file); return; } FILE *f = fopen(file, "w"); if (!f) { fprintf(stderr, "Cannot open file '%s': %s\n", file, strerror(errno)); return; } /* write out words in signature area */ for (uint64_t addr = mem_sig_start; addr < mem_sig_end; addr += 4) { /* most-significant byte first */ for (int i = 3; i >= 0; i--) { uint8_t byte = (uint8_t) read_mem(addr+i); fprintf(f, "%02x", byte); } fprintf(f, "\n"); } fclose(f); } void finish(int ec) { if (sig_file) write_signature(sig_file); model_fini(); #ifdef ENABLE_SPIKE tv_free(s); #endif if (gettimeofday(&run_end, NULL) < 0) { fprintf(stderr, "Cannot gettimeofday: %s\n", strerror(errno)); exit(1); } if (do_show_times) { int init_msecs = (init_end.tv_sec - init_start.tv_sec)*1000 + (init_end.tv_usec - init_start.tv_usec)/1000; int exec_msecs = (run_end.tv_sec - init_end.tv_sec)*1000 + (run_end.tv_usec - init_end.tv_usec)/1000; double Kips = ((double)total_insns)/((double)exec_msecs); fprintf(stderr, "Initialization: %d msecs\n", init_msecs); fprintf(stderr, "Execution: %d msecs\n", exec_msecs); fprintf(stderr, "Instructions: %d\n", total_insns); fprintf(stderr, "Perf: %.3f Kips\n", Kips); } exit(ec); } int compare_states(struct tv_spike_t *s) { int passed = 1; #ifdef ENABLE_SPIKE #define TV_CHECK(reg, spike_reg, sail_reg) \ passed &= tv_check_ ## reg(s, spike_reg, sail_reg); // fix default C enum map for cur_privilege uint8_t priv = (zcur_privilege == 2) ? 3 : zcur_privilege; passed &= tv_check_priv(s, priv); passed &= tv_check_pc(s, zPC); TV_CHECK(gpr, 1, zx1); TV_CHECK(gpr, 2, zx2); TV_CHECK(gpr, 3, zx3); TV_CHECK(gpr, 4, zx4); TV_CHECK(gpr, 5, zx5); TV_CHECK(gpr, 6, zx6); TV_CHECK(gpr, 7, zx7); TV_CHECK(gpr, 8, zx8); TV_CHECK(gpr, 9, zx9); TV_CHECK(gpr, 10, zx10); TV_CHECK(gpr, 11, zx11); TV_CHECK(gpr, 12, zx12); TV_CHECK(gpr, 13, zx13); TV_CHECK(gpr, 14, zx14); TV_CHECK(gpr, 15, zx15); TV_CHECK(gpr, 15, zx15); TV_CHECK(gpr, 16, zx16); TV_CHECK(gpr, 17, zx17); TV_CHECK(gpr, 18, zx18); TV_CHECK(gpr, 19, zx19); TV_CHECK(gpr, 20, zx20); TV_CHECK(gpr, 21, zx21); TV_CHECK(gpr, 22, zx22); TV_CHECK(gpr, 23, zx23); TV_CHECK(gpr, 24, zx24); TV_CHECK(gpr, 25, zx25); TV_CHECK(gpr, 25, zx25); TV_CHECK(gpr, 26, zx26); TV_CHECK(gpr, 27, zx27); TV_CHECK(gpr, 28, zx28); TV_CHECK(gpr, 29, zx29); TV_CHECK(gpr, 30, zx30); TV_CHECK(gpr, 31, zx31); /* some selected CSRs for now */ TV_CHECK(csr, CSR_MCAUSE, zmcause.zMcause_chunk_0); TV_CHECK(csr, CSR_MEPC, zmepc); TV_CHECK(csr, CSR_MTVAL, zmtval); TV_CHECK(csr, CSR_MSTATUS, zmstatus); TV_CHECK(csr, CSR_SCAUSE, zscause.zMcause_chunk_0); TV_CHECK(csr, CSR_SEPC, zsepc); TV_CHECK(csr, CSR_STVAL, zstval); #undef TV_CHECK #endif return passed; } void flush_logs(void) { if(config_print_instr) { fprintf(stderr, "\n"); fflush(stderr); fprintf(stdout, "\n"); fflush(stdout); } } #ifdef RVFI_DII void rvfi_send_trace(void) { sail_bits packet; CREATE(lbits)(&packet); zrvfi_get_exec_packet(&packet, UNIT); if (packet.len % 8 != 0) { fprintf(stderr, "RVFI-DII trace packet not byte aligned: %d\n", (int)packet.len); exit(1); } unsigned char bytes[packet.len / 8]; /* mpz_export might not write all of the null bytes */ memset(bytes, 0, sizeof(bytes)); mpz_export(bytes, NULL, -1, 1, 0, 0, *(packet.bits)); if (write(rvfi_dii_sock, bytes, packet.len / 8) == -1) { fprintf(stderr, "Writing RVFI DII trace failed: %s", strerror(errno)); exit(1); } KILL(lbits)(&packet); } #endif void run_sail(void) { bool spike_done; bool stepped; bool diverged = false; /* initialize the step number */ mach_int step_no = 0; int insn_cnt = 0; #ifdef RVFI_DII bool need_instr = true; #endif struct timeval interval_start; if (gettimeofday(&interval_start, NULL) < 0) { fprintf(stderr, "Cannot gettimeofday: %s\n", strerror(errno)); exit(1); } while (!zhtif_done && (insn_limit == 0 || total_insns < insn_limit)) { #ifdef RVFI_DII if (rvfi_dii) { if (need_instr) { mach_bits instr_bits; int res = read(rvfi_dii_sock, &instr_bits, sizeof(instr_bits)); if (res == 0) { rvfi_dii = false; return; } if (res < sizeof(instr_bits)) { fprintf(stderr, "Reading RVFI DII command failed: insufficient input"); exit(1); } if (res == -1) { fprintf(stderr, "Reading RVFI DII command failed: %s", strerror(errno)); exit(1); } zrvfi_set_instr_packet(instr_bits); zrvfi_zzero_exec_packet(UNIT); mach_bits cmd = zrvfi_get_cmd(UNIT); switch (cmd) { case 0: /* EndOfTrace */ zrvfi_halt_exec_packet(UNIT); rvfi_send_trace(); return; case 1: /* Instruction */ break; default: fprintf(stderr, "Unknown RVFI-DII command: %d\n", (int)cmd); exit(1); } } sail_int sail_step; CREATE(sail_int)(&sail_step); CONVERT_OF(sail_int, mach_int)(&sail_step, step_no); stepped = zstep(sail_step); if (have_exception) goto step_exception; flush_logs(); KILL(sail_int)(&sail_step); if (stepped) { need_instr = true; rvfi_send_trace(); } else need_instr = false; } else #endif { /* run a Sail step */ sail_int sail_step; CREATE(sail_int)(&sail_step); CONVERT_OF(sail_int, mach_int)(&sail_step, step_no); stepped = zstep(sail_step); if (have_exception) goto step_exception; flush_logs(); KILL(sail_int)(&sail_step); } if (stepped) { step_no++; insn_cnt++; total_insns++; } if (do_show_times && (total_insns & 0xfffff) == 0) { uint64_t start_us = 1000000 * ((uint64_t) interval_start.tv_sec) + ((uint64_t)interval_start.tv_usec); if (gettimeofday(&interval_start, NULL) < 0) { fprintf(stderr, "Cannot gettimeofday: %s\n", strerror(errno)); exit(1); } uint64_t end_us = 1000000 * ((uint64_t) interval_start.tv_sec) + ((uint64_t)interval_start.tv_usec); fprintf(stdout, "kips: %" PRIu64 "\n", ((uint64_t)1000) * 0x100000 / (end_us - start_us)); } #ifdef ENABLE_SPIKE { /* run a Spike step */ tv_step(s); spike_done = tv_is_done(s); flush_logs(); } if (zhtif_done) { if (!spike_done) { fprintf(stdout, "Sail done (exit-code %" PRIi64 "), but not Spike!\n", zhtif_exit_code); exit(1); } } else { if (spike_done) { fprintf(stdout, "Spike done, but not Sail!\n"); exit(1); } } if (!compare_states(s)) { diverged = true; break; } #endif if (zhtif_done) { /* check exit code */ if (zhtif_exit_code == 0) fprintf(stdout, "SUCCESS\n"); else fprintf(stdout, "FAILURE: %" PRIi64 "\n", zhtif_exit_code); } if (insn_cnt == rv_insns_per_tick) { insn_cnt = 0; ztick_clock(UNIT); ztick_platform(UNIT); tick_spike(); } } dump_state: if (diverged) { /* TODO */ } finish(diverged); step_exception: fprintf(stderr, "Sail exception!"); goto dump_state; } void init_logs() { #ifdef ENABLE_SPIKE // The Spike interface uses stdout for terminal output, and stderr for logs. // Do the same here. if (dup2(1, 2) < 0) { fprintf(stderr, "Unable to dup 1 -> 2: %s\n", strerror(errno)); exit(1); } #endif if (term_log != NULL && (term_fd = open(term_log, O_WRONLY|O_CREAT|O_TRUNC, S_IRUSR|S_IRGRP|S_IROTH|S_IWUSR)) < 0) { fprintf(stderr, "Cannot create terminal log '%s': %s\n", term_log, strerror(errno)); exit(1); } } int main(int argc, char **argv) { // Initialize model so that we can check or report its architecture. preinit_sail(); char *file = process_args(argc, argv); init_logs(); if (gettimeofday(&init_start, NULL) < 0) { fprintf(stderr, "Cannot gettimeofday: %s\n", strerror(errno)); exit(1); } #ifdef RVFI_DII uint64_t entry; if (rvfi_dii) { entry = 0x80000000; int listen_sock = socket(AF_INET, SOCK_STREAM, 0); if (listen_sock == -1) { fprintf(stderr, "Unable to create socket: %s", strerror(errno)); return 1; } int opt = 1; if (setsockopt(listen_sock, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)) == -1) { fprintf(stderr, "Unable to set reuseaddr on socket: %s", strerror(errno)); return 1; } struct sockaddr_in addr = { .sin_family = AF_INET, .sin_addr.s_addr = INADDR_ANY, .sin_port = htons(rvfi_dii_port) }; if (bind(listen_sock, (struct sockaddr *)&addr, sizeof(addr)) == -1) { fprintf(stderr, "Unable to set bind socket: %s", strerror(errno)); return 1; } if (listen(listen_sock, 1) == -1) { fprintf(stderr, "Unable to listen on socket: %s", strerror(errno)); return 1; } printf("Waiting for connection\n"); rvfi_dii_sock = accept(listen_sock, NULL, NULL); if (rvfi_dii_sock == -1) { fprintf(stderr, "Unable to accept connection on socket: %s", strerror(errno)); return 1; } close(listen_sock); printf("Connected\n"); } else entry = load_sail(file); #else uint64_t entry = load_sail(file); #endif /* initialize spike before sail so that we can access the device-tree blob, * until we roll our own. */ init_spike(file, entry, rv_ram_size); init_sail(entry); if (!init_check(s)) finish(1); if (gettimeofday(&init_end, NULL) < 0) { fprintf(stderr, "Cannot gettimeofday: %s\n", strerror(errno)); exit(1); } do { run_sail(); #ifndef RVFI_DII } while (0); #else if (rvfi_dii) { /* Reset for next test */ reinit_sail(entry); } } while (rvfi_dii); #endif model_fini(); flush_logs(); }