FreeCalypso > hg > freecalypso-tools
view ffstools/tiffs-mkfs/output.c @ 926:6a0aa8d36d06
rvinterf backslash escape: introduce libprint
The new helper function library named libprint is meant to replace
the badly misnamed libg23, and will soon contain functions for
printing all of the same kinds of GPF TST packets that are now handled
in libg23. However, we are also moving safe_print_trace() from libasync
to this new library, and changing it to emit our new backslash escape
format.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Tue, 23 May 2023 03:47:46 +0000 |
| parents | 178ed445021d |
| children |
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#include <sys/types.h> #include <sys/param.h> #include <sys/file.h> #include <stdio.h> #include <stdint.h> #include <endian.h> #include <stdlib.h> #include <string.h> #include <strings.h> #include <unistd.h> #include "struct.h" #include "globals.h" u_char tiffs_header[6] = {'F', 'f', 's', '#', 0x10, 0x02}; void prepare_output_buffers() { inode_block = malloc(ffs_sector_size); if (!inode_block) { perror("malloc of inode block buffer"); exit(1); } memset(inode_block, 0xFF, ffs_sector_size); bcopy(tiffs_header, inode_block, 6); inode_block[8] = 0xAB; inode_array = (struct tiffs_inode *) inode_block; inode_fill_level = 1; data_block = malloc(ffs_sector_size); if (!data_block) { perror("malloc of data block buffer"); exit(1); } memset(data_block, 0xFF, ffs_sector_size); bcopy(tiffs_header, data_block, 6); data_block[8] = 0xBD; data_fill_level = 0x10; objects_in_block = 0; chunk_buffer = malloc(chunk_size_max); if (!chunk_buffer) { perror("malloc of file chunk buffer"); exit(1); } } void open_output_file() { output_fd = open(output_filename, O_WRONLY|O_CREAT|O_TRUNC, 0666); if (output_fd < 0) { perror(output_filename); exit(1); } lseek(output_fd, (off_t) ffs_sector_size, SEEK_SET); } void write_out_block(buf) u_char *buf; { if (write(output_fd, buf, ffs_sector_size) != ffs_sector_size) { perror("write of sector bits to output file"); exit(1); } } void flush_data_block() { write_out_block(data_block); blocks_written++; memset(data_block + 0x10, 0xFF, ffs_sector_size - 0x10); data_fill_level = 0x10; objects_in_block = 0; } create_object(name, type, data, datalen) char *name; u_char *data; unsigned datalen; { int ino; struct tiffs_inode *inp; unsigned size, location; u_char *dp; if (inode_fill_level >= (ffs_sector_size >> 4)) { fprintf(stderr, "error: inode block is full\n"); exit(1); } ino = inode_fill_level++; inp = inode_array + ino; if (name) size = strlen(name) + 1; else size = 0; if (datalen) size += datalen + 1; size = (size + 15) & ~15; if (ffs_sector_size - data_fill_level < size || objects_in_block >= block_files_max) flush_data_block(); if (blocks_written >= ffs_nsectors - 2) { fprintf(stderr, "error: wrote max number of data blocks\n"); exit(1); } location = (blocks_written + 1) * ffs_sector_size + data_fill_level; /* write the data */ dp = data_block + data_fill_level; if (name) { strcpy(dp, name); dp += strlen(name) + 1; } if (datalen) { if (data) bcopy(data, dp, datalen); dp += datalen; *dp++ = 0; } /* fill the inode */ inp->size = htole16(size); inp->type = type; inp->location = htole32(location >> 4); inp->sequence = htole16(ino - 1); inp->updates = 0; /* accounting */ data_fill_level += size; objects_in_block++; return ino; } void create_root_dir() { int rootino; rootino = create_object(format_name, OBJTYPE_DIR, (u_char *) 0, 0); root.u.d.ffs_link_ptr = &inode_array[rootino].child; } create_file_object(to) struct tree_object *to; { int fd, cc; int head, seg; struct tiffs_inode *inp; fd = open(to->u.f.host_pathname, O_RDONLY); if (fd < 0) { perror(to->u.f.host_pathname); exit(1); } cc = read(fd, chunk_buffer, chunk_size_max); if (cc < 0) { read_err: perror("error reading file content"); exit(1); } if (cc == 0) { /* zero length file */ close(fd); return create_object(to->name, OBJTYPE_FILE, (u_char *) 0, 0); } head = create_object(to->name, OBJTYPE_FILE, chunk_buffer, cc); inp = inode_array + head; for (;;) { cc = read(fd, chunk_buffer, chunk_size_max); if (cc < 0) goto read_err; if (cc == 0) break; seg = create_object((char *) 0, OBJTYPE_SEGMENT, chunk_buffer, cc); inp->child = htole16(seg); inp = inode_array + seg; } close(fd); return head; } create_subdir(to) struct tree_object *to; { int ino; ino = create_object(to->name, OBJTYPE_DIR, (u_char *) 0, 0); to->u.d.ffs_link_ptr = &inode_array[ino].child; return ino; } void process_dir_level(dto) struct tree_object *dto; { unsigned n; struct tree_object *cto; int child_ino; for (n = 0; n < dto->u.d.nchildren; n++) { cto = dto->u.d.children[n]; if (cto->is_dir) { child_ino = create_subdir(cto); process_dir_level(cto); } else child_ino = create_file_object(cto); *dto->u.d.ffs_link_ptr = htole16(child_ino); dto->u.d.ffs_link_ptr = &inode_array[child_ino].sibling; } } void create_journal() { int ino; ino = create_object(".journal", OBJTYPE_FILE_RO, (u_char *) 0, journal_size); *root.u.d.ffs_link_ptr = htole16(ino); root.u.d.ffs_link_ptr = &inode_array[ino].sibling; } void finish_output() { if (objects_in_block) flush_data_block(); while (blocks_written < ffs_nsectors - 2) { write_out_block(data_block); blocks_written++; } /* free block at the end */ data_block[8] = 0xBF; write_out_block(data_block); /* write out the inode block */ lseek(output_fd, (off_t) 0, SEEK_SET); write_out_block(inode_block); }