/* g/e.c ** */ #include #include #include #include "all.h" #if 0 /* Image check. */ struct { c3_w nor_w; c3_w sou_w; c3_w mug_w[u3a_pages]; } u3K; /* _ce_check_page(): checksum page. */ static c3_w _ce_check_page(c3_w pag_w) { c3_w* mem_w = u3_Loom + (pag_w << u3a_page); c3_w mug_w = u3r_mug_words(mem_w, (1 << u3a_page)); return mug_w; } /* u3e_check(): compute a checksum on all memory within the watermarks. */ void u3e_check(c3_c* cap_c) { c3_w nor_w = 0; c3_w sou_w = 0; { c3_w nwr_w, swu_w; u3m_water(&nwr_w, &swu_w); nor_w = (nwr_w + ((1 << u3a_page) - 1)) >> u3a_page; sou_w = (swu_w + ((1 << u3a_page) - 1)) >> u3a_page; } /* Count dirty pages. */ { c3_w i_w, sum_w, mug_w; sum_w = 0; for ( i_w = 0; i_w < nor_w; i_w++ ) { mug_w = _ce_check_page(i_w); if ( strcmp(cap_c, "boot") ) { c3_assert(mug_w == u3K.mug_w[i_w]); } sum_w += mug_w; } for ( i_w = 0; i_w < sou_w; i_w++ ) { mug_w = _ce_check_page((u3a_pages - (i_w + 1))); if ( strcmp(cap_c, "boot") ) { c3_assert(mug_w == u3K.mug_w[(u3a_pages - (i_w + 1))]); } sum_w += mug_w; } printf("%s: sum %x (%x, %x)\r\n", cap_c, sum_w, nor_w, sou_w); } } /* _ce_maplloc(): crude off-loom allocator. */ static void* _ce_maplloc(c3_w len_w) { void* map_v; map_v = mmap(0, len_w, (PROT_READ | PROT_WRITE), (MAP_ANON | MAP_PRIVATE), -1, 0); if ( -1 == (c3_ps)map_v ) { c3_assert(0); } else { c3_w* map_w = map_v; map_w[0] = len_w; return map_w + 1; } } /* _ce_mapfree(): crude off-loom allocator. */ static void _ce_mapfree(void* map_v) { c3_w* map_w = map_v; c3_i res_i; map_w -= 1; res_i = munmap(map_w, map_w[0]); c3_assert(0 == res_i); } #endif /* u3e_fault(): handle a memory event with libsigsegv protocol. */ c3_i u3e_fault(void* adr_v, c3_i ser_i) { c3_w* adr_w = (c3_w*) adr_v; if ( (adr_w < u3_Loom) || (adr_w >= (u3_Loom + u3a_words)) ) { fprintf(stderr, "address %p out of loom!\r\n", adr_v); fprintf(stderr, "loom: [%p : %p)\r\n", u3_Loom, u3_Loom + u3a_words); c3_assert(0); return 0; } else { c3_w off_w = (adr_w - u3_Loom); c3_w pag_w = off_w >> u3a_page; c3_w blk_w = (pag_w >> 5); c3_w bit_w = (pag_w & 31); #if 0 if ( pag_w == 131041 ) { printf("dirty page %d (at %p); unprotecting %p to %p\r\n", pag_w, adr_v, (u3_Loom + (pag_w << u3a_page)), (u3_Loom + (pag_w << u3a_page) + (1 << u3a_page))); } #endif if ( 0 != (u3P.dit_w[blk_w] & (1 << bit_w)) ) { fprintf(stderr, "strange page: %d, at %p, off %x\r\n", pag_w, adr_w, off_w); abort(); } c3_assert(0 == (u3P.dit_w[blk_w] & (1 << bit_w))); u3P.dit_w[blk_w] |= (1 << bit_w); if ( -1 == mprotect((void *)(u3_Loom + (pag_w << u3a_page)), (1 << (u3a_page + 2)), (PROT_READ | PROT_WRITE)) ) { perror("mprotect"); c3_assert(0); return 0; } } return 1; } /* _ce_image_open(): open or create image. */ static c3_o _ce_image_open(u3e_image* img_u, c3_o nuu_o) { c3_i mod_i = _(nuu_o) ? (O_RDWR | O_CREAT) : O_RDWR; c3_c ful_c[8193]; snprintf(ful_c, 8192, "%s", u3P.dir_c); mkdir(ful_c, 0700); snprintf(ful_c, 8192, "%s/.urb", u3P.dir_c); mkdir(ful_c, 0700); snprintf(ful_c, 8192, "%s/.urb/chk", u3P.dir_c); mkdir(ful_c, 0700); snprintf(ful_c, 8192, "%s/.urb/chk/%s.bin", u3P.dir_c, img_u->nam_c); if ( -1 == (img_u->fid_i = open(ful_c, mod_i, 0666)) ) { perror(ful_c); return c3n; } else { struct stat buf_u; if ( -1 == fstat(img_u->fid_i, &buf_u) ) { perror(ful_c); c3_assert(0); return c3n; } else { c3_d siz_d = buf_u.st_size; c3_d pgs_d = (siz_d + (c3_d)((1 << (u3a_page + 2)) - 1)) >> (c3_d)(u3a_page + 2); if ( c3y == nuu_o ) { if ( siz_d ) { c3_assert(0); return c3n; } return c3y; } else { if ( siz_d != (pgs_d << (c3_d)(u3a_page + 2)) ) { fprintf(stderr, "%s: corrupt size %" PRIx64 "\r\n", ful_c, siz_d); return c3n; } img_u->pgs_w = (c3_w) pgs_d; c3_assert(pgs_d == (c3_d)img_u->pgs_w); return c3y; } } } } /* _ce_patch_write_control(): write control block file. */ static void _ce_patch_write_control(u3_ce_patch* pat_u) { c3_w len_w = sizeof(u3e_control) + (pat_u->con_u->pgs_w * sizeof(u3e_line)); if ( len_w != write(pat_u->ctl_i, pat_u->con_u, len_w) ) { c3_assert(0); } } /* _ce_patch_read_control(): read control block file. */ static c3_o _ce_patch_read_control(u3_ce_patch* pat_u) { c3_w len_w; c3_assert(0 == pat_u->con_u); { struct stat buf_u; if ( -1 == fstat(pat_u->ctl_i, &buf_u) ) { c3_assert(0); return c3n; } len_w = (c3_w) buf_u.st_size; } pat_u->con_u = malloc(len_w); if ( (len_w != read(pat_u->ctl_i, pat_u->con_u, len_w)) || (len_w != sizeof(u3e_control) + (pat_u->con_u->pgs_w * sizeof(u3e_line))) ) { free(pat_u->con_u); pat_u->con_u = 0; return c3n; } return c3y; } /* _ce_patch_create(): create patch files. */ static void _ce_patch_create(u3_ce_patch* pat_u) { c3_c ful_c[8193]; snprintf(ful_c, 8192, "%s", u3P.dir_c); mkdir(ful_c, 0700); snprintf(ful_c, 8192, "%s/.urb", u3P.dir_c); mkdir(ful_c, 0700); snprintf(ful_c, 8192, "%s/.urb/chk/control.bin", u3P.dir_c); if ( -1 == (pat_u->ctl_i = open(ful_c, O_RDWR | O_CREAT | O_EXCL, 0666)) ) { c3_assert(0); } snprintf(ful_c, 8192, "%s/.urb/chk/memory.bin", u3P.dir_c); if ( -1 == (pat_u->mem_i = open(ful_c, O_RDWR | O_CREAT | O_EXCL, 0666)) ) { c3_assert(0); } } /* _ce_patch_delete(): delete a patch. */ static void _ce_patch_delete(void) { c3_c ful_c[8193]; snprintf(ful_c, 8192, "%s/.urb/chk/control.bin", u3P.dir_c); unlink(ful_c); snprintf(ful_c, 8192, "%s/.urb/chk/memory.bin", u3P.dir_c); unlink(ful_c); } /* _ce_patch_verify(): check patch data mug. */ static c3_o _ce_patch_verify(u3_ce_patch* pat_u) { c3_w i_w; for ( i_w = 0; i_w < pat_u->con_u->pgs_w; i_w++ ) { c3_w pag_w = pat_u->con_u->mem_u[i_w].pag_w; c3_w mug_w = pat_u->con_u->mem_u[i_w].mug_w; c3_w mem_w[1 << u3a_page]; if ( -1 == lseek(pat_u->mem_i, (i_w << (u3a_page + 2)), SEEK_SET) ) { perror("seek"); c3_assert(0); return c3n; } if ( -1 == read(pat_u->mem_i, mem_w, (1 << (u3a_page + 2))) ) { perror("read"); c3_assert(0); return c3n; } { c3_w nug_w = u3r_mug_words(mem_w, (1 << u3a_page)); if ( mug_w != nug_w ) { printf("_ce_patch_verify: mug mismatch %d/%d; (%x, %x)\r\n", pag_w, i_w, mug_w, nug_w); c3_assert(0); return c3n; } #if 0 else { printf("verify: patch %d/%d, %x\r\n", pag_w, i_w, mug_w); } #endif } } return c3y; } /* _ce_patch_free(): free a patch. */ static void _ce_patch_free(u3_ce_patch* pat_u) { free(pat_u->con_u); close(pat_u->ctl_i); close(pat_u->mem_i); free(pat_u); } /* _ce_patch_open(): open patch, if any. */ static u3_ce_patch* _ce_patch_open(void) { u3_ce_patch* pat_u; c3_c ful_c[8193]; c3_i ctl_i, mem_i; snprintf(ful_c, 8192, "%s", u3P.dir_c); mkdir(ful_c, 0700); snprintf(ful_c, 8192, "%s/.urb", u3P.dir_c); mkdir(ful_c, 0700); snprintf(ful_c, 8192, "%s/.urb/chk/control.bin", u3P.dir_c); if ( -1 == (ctl_i = open(ful_c, O_RDWR)) ) { return 0; } snprintf(ful_c, 8192, "%s/.urb/chk/memory.bin", u3P.dir_c); if ( -1 == (mem_i = open(ful_c, O_RDWR)) ) { close(ctl_i); _ce_patch_delete(); return 0; } pat_u = malloc(sizeof(u3_ce_patch)); pat_u->ctl_i = ctl_i; pat_u->mem_i = mem_i; pat_u->con_u = 0; if ( c3n == _ce_patch_read_control(pat_u) ) { close(pat_u->ctl_i); close(pat_u->mem_i); free(pat_u); _ce_patch_delete(); return 0; } if ( c3n == _ce_patch_verify(pat_u) ) { _ce_patch_free(pat_u); _ce_patch_delete(); return 0; } return pat_u; } /* _ce_patch_write_page(): write a page of patch memory. */ static void _ce_patch_write_page(u3_ce_patch* pat_u, c3_w pgc_w, c3_w* mem_w) { if ( -1 == lseek(pat_u->mem_i, (pgc_w << (u3a_page + 2)), SEEK_SET) ) { c3_assert(0); } if ( (1 << (u3a_page + 2)) != write(pat_u->mem_i, mem_w, (1 << (u3a_page + 2))) ) { c3_assert(0); } } /* _ce_patch_count_page(): count a page, producing new counter. */ static c3_w _ce_patch_count_page(c3_w pag_w, c3_w pgc_w) { c3_w blk_w = (pag_w >> 5); c3_w bit_w = (pag_w & 31); if ( u3P.dit_w[blk_w] & (1 << bit_w) ) { pgc_w += 1; } return pgc_w; } /* _ce_patch_save_page(): save a page, producing new page counter. */ static c3_w _ce_patch_save_page(u3_ce_patch* pat_u, c3_w pag_w, c3_w pgc_w) { c3_w blk_w = (pag_w >> 5); c3_w bit_w = (pag_w & 31); if ( u3P.dit_w[blk_w] & (1 << bit_w) ) { c3_w* mem_w = u3_Loom + (pag_w << u3a_page); pat_u->con_u->mem_u[pgc_w].pag_w = pag_w; pat_u->con_u->mem_u[pgc_w].mug_w = u3r_mug_words(mem_w, (1 << u3a_page)); #if 0 printf("protect a: page %d\r\n", pag_w); #endif _ce_patch_write_page(pat_u, pgc_w, mem_w); if ( -1 == mprotect(u3_Loom + (pag_w << u3a_page), (1 << (u3a_page + 2)), PROT_READ) ) { c3_assert(0); } u3P.dit_w[blk_w] &= ~(1 << bit_w); pgc_w += 1; } return pgc_w; } /* _ce_patch_junk_page(): mark a page as junk. */ static void _ce_patch_junk_page(u3_ce_patch* pat_u, c3_w pag_w) { c3_w blk_w = (pag_w >> 5); c3_w bit_w = (pag_w & 31); // printf("protect b: page %d\r\n", pag_w); if ( -1 == mprotect(u3_Loom + (pag_w << u3a_page), (1 << (u3a_page + 2)), PROT_READ) ) { c3_assert(0); } u3P.dit_w[blk_w] &= ~(1 << bit_w); } /* u3e_dirty(): count dirty pages. */ c3_w u3e_dirty(void) { c3_w pgs_w = 0; c3_w nor_w = 0; c3_w sou_w = 0; /* Calculate number of saved pages, north and south. */ { c3_w nwr_w, swu_w; u3m_water(&nwr_w, &swu_w); nor_w = (nwr_w + ((1 << u3a_page) - 1)) >> u3a_page; sou_w = (swu_w + ((1 << u3a_page) - 1)) >> u3a_page; } // u3K.nor_w = nor_w; // u3K.sou_w = sou_w; /* Count dirty pages. */ { c3_w i_w; for ( i_w = 0; i_w < nor_w; i_w++ ) { pgs_w = _ce_patch_count_page(i_w, pgs_w); } for ( i_w = 0; i_w < sou_w; i_w++ ) { pgs_w = _ce_patch_count_page((u3a_pages - (i_w + 1)), pgs_w); } } return pgs_w; } /* _ce_patch_compose(): make and write current patch. */ static u3_ce_patch* _ce_patch_compose(void) { c3_w pgs_w = 0; c3_w nor_w = 0; c3_w sou_w = 0; /* Calculate number of saved pages, north and south. */ { c3_w nwr_w, swu_w; u3m_water(&nwr_w, &swu_w); nor_w = (nwr_w + ((1 << u3a_page) - 1)) >> u3a_page; sou_w = (swu_w + ((1 << u3a_page) - 1)) >> u3a_page; } // u3K.nor_w = nor_w; // u3K.sou_w = sou_w; /* Count dirty pages. */ { c3_w i_w; for ( i_w = 0; i_w < nor_w; i_w++ ) { pgs_w = _ce_patch_count_page(i_w, pgs_w); } for ( i_w = 0; i_w < sou_w; i_w++ ) { pgs_w = _ce_patch_count_page((u3a_pages - (i_w + 1)), pgs_w); } } if ( !pgs_w ) { return 0; } else { u3_ce_patch* pat_u = malloc(sizeof(u3_ce_patch)); c3_w i_w, pgc_w; _ce_patch_create(pat_u); pat_u->con_u = malloc(sizeof(u3e_control) + (pgs_w * sizeof(u3e_line))); pgc_w = 0; for ( i_w = 0; i_w < nor_w; i_w++ ) { pgc_w = _ce_patch_save_page(pat_u, i_w, pgc_w); } for ( i_w = 0; i_w < sou_w; i_w++ ) { pgc_w = _ce_patch_save_page(pat_u, (u3a_pages - (i_w + 1)), pgc_w); } for ( i_w = nor_w; i_w < (u3a_pages - sou_w); i_w++ ) { _ce_patch_junk_page(pat_u, i_w); } pat_u->con_u->nor_w = nor_w; pat_u->con_u->sou_w = sou_w; pat_u->con_u->pgs_w = pgc_w; _ce_patch_write_control(pat_u); return pat_u; } } /* _ce_sync(): sync a file descriptor. */ static void _ce_sync(c3_i fid_i) { #if defined(U3_OS_linux) fdatasync(fid_i); #elif defined(U3_OS_osx) fcntl(fid_i, F_FULLFSYNC); #elif defined(U3_OS_bsd) fsync(fid_i); #else # error "port: datasync" #endif } /* _ce_patch_sync(): make sure patch is synced to disk. */ static void _ce_patch_sync(u3_ce_patch* pat_u) { _ce_sync(pat_u->ctl_i); _ce_sync(pat_u->mem_i); } /* _ce_image_sync(): make sure image is synced to disk. */ static void _ce_image_sync(u3e_image* img_u) { _ce_sync(img_u->fid_i); } /* _ce_patch_apply(): apply patch to image. */ static void _ce_patch_apply(u3_ce_patch* pat_u) { c3_w i_w; //printf("image: nor_w %d, new %d\r\n", u3P.nor_u.pgs_w, pat_u->con_u->nor_w); //printf("image: sou_w %d, new %d\r\n", u3P.sou_u.pgs_w, pat_u->con_u->sou_w); if ( u3P.nor_u.pgs_w > pat_u->con_u->nor_w ) { ftruncate(u3P.nor_u.fid_i, u3P.nor_u.pgs_w << (u3a_page + 2)); } u3P.nor_u.pgs_w = pat_u->con_u->nor_w; if ( u3P.sou_u.pgs_w > pat_u->con_u->sou_w ) { ftruncate(u3P.sou_u.fid_i, u3P.sou_u.pgs_w << (u3a_page + 2)); } u3P.sou_u.pgs_w = pat_u->con_u->sou_w; if ( (-1 == lseek(pat_u->mem_i, 0, SEEK_SET)) || (-1 == lseek(u3P.nor_u.fid_i, 0, SEEK_SET)) || (-1 == lseek(u3P.sou_u.fid_i, 0, SEEK_SET)) ) { perror("apply: seek"); c3_assert(0); } for ( i_w = 0; i_w < pat_u->con_u->pgs_w; i_w++ ) { c3_w pag_w = pat_u->con_u->mem_u[i_w].pag_w; c3_w mem_w[1 << u3a_page]; c3_i fid_i; c3_w off_w; if ( pag_w < pat_u->con_u->nor_w ) { fid_i = u3P.nor_u.fid_i; off_w = pag_w; } else { fid_i = u3P.sou_u.fid_i; off_w = (u3a_pages - (pag_w + 1)); } if ( -1 == read(pat_u->mem_i, mem_w, (1 << (u3a_page + 2))) ) { perror("apply: read"); c3_assert(0); } else { if ( -1 == lseek(fid_i, (off_w << (u3a_page + 2)), SEEK_SET) ) { perror("apply: lseek"); c3_assert(0); } if ( -1 == write(fid_i, mem_w, (1 << (u3a_page + 2))) ) { perror("apply: write"); c3_assert(0); } } #if 0 printf("apply: %d, %x\n", pag_w, u3r_mug_words(mem_w, (1 << u3a_page))); #endif } } /* _ce_image_blit(): apply image to memory. */ static void _ce_image_blit(u3e_image* img_u, c3_w* ptr_w, c3_ws stp_ws) { c3_w i_w; lseek(img_u->fid_i, 0, SEEK_SET); for ( i_w=0; i_w < img_u->pgs_w; i_w++ ) { if ( -1 == read(img_u->fid_i, ptr_w, (1 << (u3a_page + 2))) ) { perror("read"); c3_assert(0); } #if 0 { c3_w off_w = (ptr_w - u3_Loom); c3_w pag_w = (off_w >> u3a_page); printf("blit: page %d, mug %x\r\n", pag_w, u3r_mug_words(ptr_w, (1 << u3a_page))); } #endif ptr_w += stp_ws; } } #if 0 /* _ce_image_fine(): compare image to memory. */ static void _ce_image_fine(u3e_image* img_u, c3_w* ptr_w, c3_ws stp_ws) { c3_w i_w; c3_w buf_w[1 << u3a_page]; lseek(img_u->fid_i, 0, SEEK_SET); for ( i_w=0; i_w < img_u->pgs_w; i_w++ ) { c3_w mem_w, fil_w; if ( -1 == read(img_u->fid_i, buf_w, (1 << (u3a_page + 2))) ) { perror("read"); c3_assert(0); } mem_w = u3r_mug_words(ptr_w, (1 << u3a_page)); fil_w = u3r_mug_words(buf_w, (1 << u3a_page)); if ( mem_w != fil_w ) { c3_w pag_w = (ptr_w - u3_Loom) >> u3a_page; fprintf(stderr, "mismatch: page %d, mem_w %x, fil_w %x, K %x\r\n", pag_w, mem_w, fil_w, u3K.mug_w[pag_w]); abort(); } ptr_w += stp_ws; } } #endif /* u3e_save(): save current changes. */ void u3e_save(void) { u3_ce_patch* pat_u; // In dry-run mode, we never touch this stuff. // if ( u3C.wag_w & u3o_dryrun ) { return; } // Write all dirty pages to disk; clear protection and dirty bits. // // This has to block the main thread. All further processing can happen // in a separate thread, though we can't save again till this completes. // if ( !(pat_u = _ce_patch_compose()) ) { return; } // Sync the patch files. // // u3a_print_memory("sync: save", 4096 * pat_u->con_u->pgs_w); _ce_patch_sync(pat_u); // Verify the patch - because why not? // // printf("_ce_patch_verify\r\n"); _ce_patch_verify(pat_u); // Write the patch data into the image file. Idempotent. // // printf("_ce_patch_apply\r\n"); _ce_patch_apply(pat_u); #if 0 { _ce_image_fine(&u3P.nor_u, u3_Loom, (1 << u3a_page)); _ce_image_fine(&u3P.sou_u, (u3_Loom + (1 << u3a_bits) - (1 << u3a_page)), -(1 << u3a_page)); c3_assert(u3P.nor_u.pgs_w == u3K.nor_w); c3_assert(u3P.sou_u.pgs_w == u3K.sou_w); } #endif // Sync the image file. // // printf("_ce_image_sync\r\n"); _ce_image_sync(&u3P.nor_u); _ce_image_sync(&u3P.sou_u); // Delete the patchfile and free it. // // printf("_ce_patch_delete\r\n"); _ce_patch_delete(); // printf("_ce_patch_free\r\n"); _ce_patch_free(pat_u); } /* u3e_live(): start the persistence system. */ c3_o u3e_live(c3_o nuu_o, c3_c* dir_c) { u3P.dir_c = dir_c; u3P.nor_u.nam_c = "north"; u3P.sou_u.nam_c = "south"; #if 0 if ( u3C.wag_w & u3o_dryrun ) { return c3y; } else #endif { /* Open and apply any patches. */ if ( _(nuu_o) ) { if ( (c3n == _ce_image_open(&u3P.nor_u, c3y)) || (c3n == _ce_image_open(&u3P.sou_u, c3y)) ) { printf("boot: image failed\r\n"); exit(1); } } else { u3_ce_patch* pat_u; /* Open image files. */ { if ( (c3n == _ce_image_open(&u3P.nor_u, c3n)) || (c3n == _ce_image_open(&u3P.sou_u, c3n)) ) { fprintf(stderr, "boot: no image\r\n"); return u3e_live(c3y, dir_c); } } /* Load any patch files; apply them to images. */ if ( 0 != (pat_u = _ce_patch_open()) ) { printf("_ce_patch_apply\r\n"); _ce_patch_apply(pat_u); printf("_ce_image_sync\r\n"); _ce_image_sync(&u3P.nor_u); _ce_image_sync(&u3P.sou_u); printf("_ce_patch_delete\r\n"); _ce_patch_delete(); printf("_ce_patch_free\r\n"); _ce_patch_free(pat_u); } /* Write image files to memory; reinstate protection. */ { _ce_image_blit(&u3P.nor_u, u3_Loom, (1 << u3a_page)); _ce_image_blit(&u3P.sou_u, (u3_Loom + (1 << u3a_bits) - (1 << u3a_page)), -(1 << u3a_page)); if ( 0 != mprotect((void *)u3_Loom, u3a_bytes, PROT_READ) ) { perror("protect"); c3_assert(0); } printf("protected loom\r\n"); } /* If the images were empty, we are logically booting. */ if ( (0 == u3P.nor_u.pgs_w) && (0 == u3P.sou_u.pgs_w) ) { printf("live: logical boot\r\n"); nuu_o = c3y; } else { u3a_print_memory("live: loaded", (u3P.nor_u.pgs_w + u3P.sou_u.pgs_w) << u3a_page); } } } return nuu_o; }