/** * Block parsing implementation. * * For a high-level overview of the block parsing process, * see http://spec.commonmark.org/0.24/#phase-1-block-structure */ #include #include #include #include "cmark_ctype.h" #include "config.h" #include "parser.h" #include "cmark.h" #include "node.h" #include "references.h" #include "utf8.h" #include "scanners.h" #include "inlines.h" #include "houdini.h" #include "buffer.h" #define CODE_INDENT 4 #define TAB_STOP 4 #ifndef MIN #define MIN(x, y) ((x < y) ? x : y) #endif #define peek_at(i, n) (i)->data[n] static bool S_last_line_blank(const cmark_node *node) { return (node->flags & CMARK_NODE__LAST_LINE_BLANK) != 0; } static bool S_last_line_checked(const cmark_node *node) { return (node->flags & CMARK_NODE__LAST_LINE_CHECKED) != 0; } static CMARK_INLINE cmark_node_type S_type(const cmark_node *node) { return (cmark_node_type)node->type; } static void S_set_last_line_blank(cmark_node *node, bool is_blank) { if (is_blank) node->flags |= CMARK_NODE__LAST_LINE_BLANK; else node->flags &= ~CMARK_NODE__LAST_LINE_BLANK; } static void S_set_last_line_checked(cmark_node *node) { node->flags |= CMARK_NODE__LAST_LINE_CHECKED; } static CMARK_INLINE bool S_is_line_end_char(char c) { return (c == '\n' || c == '\r'); } static CMARK_INLINE bool S_is_space_or_tab(char c) { return (c == ' ' || c == '\t'); } static void S_parser_feed(cmark_parser *parser, const unsigned char *buffer, size_t len, bool eof); static void S_process_line(cmark_parser *parser, const unsigned char *buffer, bufsize_t bytes); static cmark_node *make_block(cmark_mem *mem, cmark_node_type tag, int start_line, int start_column) { cmark_node *e; e = (cmark_node *)mem->calloc(1, sizeof(*e)); cmark_strbuf_init(mem, &e->content, 32); e->type = (uint16_t)tag; e->flags = CMARK_NODE__OPEN; e->start_line = start_line; e->start_column = start_column; e->end_line = start_line; return e; } // Create a root document node. static cmark_node *make_document(cmark_mem *mem) { cmark_node *e = make_block(mem, CMARK_NODE_DOCUMENT, 1, 1); return e; } cmark_parser *cmark_parser_new_with_mem(int options, cmark_mem *mem) { cmark_parser *parser = (cmark_parser *)mem->calloc(1, sizeof(cmark_parser)); parser->mem = mem; cmark_node *document = make_document(mem); cmark_strbuf_init(mem, &parser->curline, 256); cmark_strbuf_init(mem, &parser->linebuf, 0); parser->refmap = cmark_reference_map_new(mem); parser->root = document; parser->current = document; parser->line_number = 0; parser->offset = 0; parser->column = 0; parser->first_nonspace = 0; parser->first_nonspace_column = 0; parser->indent = 0; parser->blank = false; parser->partially_consumed_tab = false; parser->last_line_length = 0; parser->options = options; parser->last_buffer_ended_with_cr = false; return parser; } cmark_parser *cmark_parser_new(int options) { extern cmark_mem DEFAULT_MEM_ALLOCATOR; return cmark_parser_new_with_mem(options, &DEFAULT_MEM_ALLOCATOR); } void cmark_parser_free(cmark_parser *parser) { cmark_mem *mem = parser->mem; cmark_strbuf_free(&parser->curline); cmark_strbuf_free(&parser->linebuf); cmark_reference_map_free(parser->refmap); mem->free(parser); } static cmark_node *finalize(cmark_parser *parser, cmark_node *b); // Returns true if line has only space characters, else false. static bool is_blank(cmark_strbuf *s, bufsize_t offset) { while (offset < s->size) { switch (s->ptr[offset]) { case '\r': case '\n': return true; case ' ': offset++; break; case '\t': offset++; break; default: return false; } } return true; } static CMARK_INLINE bool can_contain(cmark_node_type parent_type, cmark_node_type child_type) { return (parent_type == CMARK_NODE_DOCUMENT || parent_type == CMARK_NODE_BLOCK_QUOTE || parent_type == CMARK_NODE_ITEM || (parent_type == CMARK_NODE_LIST && child_type == CMARK_NODE_ITEM)); } static CMARK_INLINE bool accepts_lines(cmark_node_type block_type) { return (block_type == CMARK_NODE_PARAGRAPH || block_type == CMARK_NODE_HEADING || block_type == CMARK_NODE_CODE_BLOCK); } static CMARK_INLINE bool contains_inlines(cmark_node_type block_type) { return (block_type == CMARK_NODE_PARAGRAPH || block_type == CMARK_NODE_HEADING); } static void add_line(cmark_node *node, cmark_chunk *ch, cmark_parser *parser) { int chars_to_tab; int i; assert(node->flags & CMARK_NODE__OPEN); if (parser->partially_consumed_tab) { parser->offset += 1; // skip over tab // add space characters: chars_to_tab = TAB_STOP - (parser->column % TAB_STOP); for (i = 0; i < chars_to_tab; i++) { cmark_strbuf_putc(&node->content, ' '); } } cmark_strbuf_put(&node->content, ch->data + parser->offset, ch->len - parser->offset); } static void remove_trailing_blank_lines(cmark_strbuf *ln) { bufsize_t i; unsigned char c; for (i = ln->size - 1; i >= 0; --i) { c = ln->ptr[i]; if (c != ' ' && c != '\t' && !S_is_line_end_char(c)) break; } if (i < 0) { cmark_strbuf_clear(ln); return; } for (; i < ln->size; ++i) { c = ln->ptr[i]; if (!S_is_line_end_char(c)) continue; cmark_strbuf_truncate(ln, i); break; } } // Check to see if a node ends with a blank line, descending // if needed into lists and sublists. static bool S_ends_with_blank_line(cmark_node *node) { if (S_last_line_checked(node)) { return(S_last_line_blank(node)); } else if ((S_type(node) == CMARK_NODE_LIST || S_type(node) == CMARK_NODE_ITEM) && node->last_child) { S_set_last_line_checked(node); return(S_ends_with_blank_line(node->last_child)); } else { S_set_last_line_checked(node); return (S_last_line_blank(node)); } } static cmark_node *finalize(cmark_parser *parser, cmark_node *b) { bufsize_t pos; cmark_node *item; cmark_node *subitem; cmark_node *parent; parent = b->parent; assert(b->flags & CMARK_NODE__OPEN); // shouldn't call finalize on closed blocks b->flags &= ~CMARK_NODE__OPEN; if (parser->curline.size == 0) { // end of input - line number has not been incremented b->end_line = parser->line_number; b->end_column = parser->last_line_length; } else if (S_type(b) == CMARK_NODE_DOCUMENT || (S_type(b) == CMARK_NODE_CODE_BLOCK && b->as.code.fenced) || (S_type(b) == CMARK_NODE_HEADING && b->as.heading.setext)) { b->end_line = parser->line_number; b->end_column = parser->curline.size; if (b->end_column && parser->curline.ptr[b->end_column - 1] == '\n') b->end_column -= 1; if (b->end_column && parser->curline.ptr[b->end_column - 1] == '\r') b->end_column -= 1; } else { b->end_line = parser->line_number - 1; b->end_column = parser->last_line_length; } cmark_strbuf *node_content = &b->content; switch (S_type(b)) { case CMARK_NODE_PARAGRAPH: { cmark_chunk chunk = {node_content->ptr, node_content->size, 0}; while (chunk.len && chunk.data[0] == '[' && (pos = cmark_parse_reference_inline(parser->mem, &chunk, parser->refmap))) { chunk.data += pos; chunk.len -= pos; } cmark_strbuf_drop(node_content, (node_content->size - chunk.len)); if (is_blank(node_content, 0)) { // remove blank node (former reference def) cmark_node_free(b); } break; } case CMARK_NODE_CODE_BLOCK: if (!b->as.code.fenced) { // indented code remove_trailing_blank_lines(node_content); cmark_strbuf_putc(node_content, '\n'); } else { // first line of contents becomes info for (pos = 0; pos < node_content->size; ++pos) { if (S_is_line_end_char(node_content->ptr[pos])) break; } assert(pos < node_content->size); cmark_strbuf tmp = CMARK_BUF_INIT(parser->mem); houdini_unescape_html_f(&tmp, node_content->ptr, pos); cmark_strbuf_trim(&tmp); cmark_strbuf_unescape(&tmp); b->as.code.info = cmark_chunk_buf_detach(&tmp); if (node_content->ptr[pos] == '\r') pos += 1; if (node_content->ptr[pos] == '\n') pos += 1; cmark_strbuf_drop(node_content, pos); } b->as.code.literal = cmark_chunk_buf_detach(node_content); break; case CMARK_NODE_HTML_BLOCK: b->as.literal = cmark_chunk_buf_detach(node_content); break; case CMARK_NODE_LIST: // determine tight/loose status b->as.list.tight = true; // tight by default item = b->first_child; while (item) { // check for non-final non-empty list item ending with blank line: if (S_last_line_blank(item) && item->next) { b->as.list.tight = false; break; } // recurse into children of list item, to see if there are // spaces between them: subitem = item->first_child; while (subitem) { if (S_ends_with_blank_line(subitem) && (item->next || subitem->next)) { b->as.list.tight = false; break; } subitem = subitem->next; } if (!(b->as.list.tight)) { break; } item = item->next; } break; default: break; } return parent; } // Add a node as child of another. Return pointer to child. static cmark_node *add_child(cmark_parser *parser, cmark_node *parent, cmark_node_type block_type, int start_column) { assert(parent); // if 'parent' isn't the kind of node that can accept this child, // then back up til we hit a node that can. while (!can_contain(S_type(parent), block_type)) { parent = finalize(parser, parent); } cmark_node *child = make_block(parser->mem, block_type, parser->line_number, start_column); child->parent = parent; if (parent->last_child) { parent->last_child->next = child; child->prev = parent->last_child; } else { parent->first_child = child; child->prev = NULL; } parent->last_child = child; return child; } // Walk through node and all children, recursively, parsing // string content into inline content where appropriate. static void process_inlines(cmark_mem *mem, cmark_node *root, cmark_reference_map *refmap, int options) { cmark_iter *iter = cmark_iter_new(root); cmark_node *cur; cmark_event_type ev_type; while ((ev_type = cmark_iter_next(iter)) != CMARK_EVENT_DONE) { cur = cmark_iter_get_node(iter); if (ev_type == CMARK_EVENT_ENTER) { if (contains_inlines(S_type(cur))) { cmark_parse_inlines(mem, cur, refmap, options); } } } cmark_iter_free(iter); } // Attempts to parse a list item marker (bullet or enumerated). // On success, returns length of the marker, and populates // data with the details. On failure, returns 0. static bufsize_t parse_list_marker(cmark_mem *mem, cmark_chunk *input, bufsize_t pos, bool interrupts_paragraph, cmark_list **dataptr) { unsigned char c; bufsize_t startpos; cmark_list *data; bufsize_t i; startpos = pos; c = peek_at(input, pos); if (c == '*' || c == '-' || c == '+') { pos++; if (!cmark_isspace(peek_at(input, pos))) { return 0; } if (interrupts_paragraph) { i = pos; // require non-blank content after list marker: while (S_is_space_or_tab(peek_at(input, i))) { i++; } if (peek_at(input, i) == '\n') { return 0; } } data = (cmark_list *)mem->calloc(1, sizeof(*data)); data->marker_offset = 0; // will be adjusted later data->list_type = CMARK_BULLET_LIST; data->bullet_char = c; data->start = 0; data->delimiter = CMARK_NO_DELIM; data->tight = false; } else if (cmark_isdigit(c)) { int start = 0; int digits = 0; do { start = (10 * start) + (peek_at(input, pos) - '0'); pos++; digits++; // We limit to 9 digits to avoid overflow, // assuming max int is 2^31 - 1 // This also seems to be the limit for 'start' in some browsers. } while (digits < 9 && cmark_isdigit(peek_at(input, pos))); if (interrupts_paragraph && start != 1) { return 0; } c = peek_at(input, pos); if (c == '.' || c == ')') { pos++; if (!cmark_isspace(peek_at(input, pos))) { return 0; } if (interrupts_paragraph) { // require non-blank content after list marker: i = pos; while (S_is_space_or_tab(peek_at(input, i))) { i++; } if (S_is_line_end_char(peek_at(input, i))) { return 0; } } data = (cmark_list *)mem->calloc(1, sizeof(*data)); data->marker_offset = 0; // will be adjusted later data->list_type = CMARK_ORDERED_LIST; data->bullet_char = 0; data->start = start; data->delimiter = (c == '.' ? CMARK_PERIOD_DELIM : CMARK_PAREN_DELIM); data->tight = false; } else { return 0; } } else { return 0; } *dataptr = data; return (pos - startpos); } // Return 1 if list item belongs in list, else 0. static int lists_match(cmark_list *list_data, cmark_list *item_data) { return (list_data->list_type == item_data->list_type && list_data->delimiter == item_data->delimiter && // list_data->marker_offset == item_data.marker_offset && list_data->bullet_char == item_data->bullet_char); } static cmark_node *finalize_document(cmark_parser *parser) { while (parser->current != parser->root) { parser->current = finalize(parser, parser->current); } finalize(parser, parser->root); process_inlines(parser->mem, parser->root, parser->refmap, parser->options); return parser->root; } cmark_node *cmark_parse_file(FILE *f, int options) { unsigned char buffer[4096]; cmark_parser *parser = cmark_parser_new(options); size_t bytes; cmark_node *document; while ((bytes = fread(buffer, 1, sizeof(buffer), f)) > 0) { bool eof = bytes < sizeof(buffer); S_parser_feed(parser, buffer, bytes, eof); if (eof) { break; } } document = cmark_parser_finish(parser); cmark_parser_free(parser); return document; } cmark_node *cmark_parse_document(const char *buffer, size_t len, int options) { cmark_parser *parser = cmark_parser_new(options); cmark_node *document; S_parser_feed(parser, (const unsigned char *)buffer, len, true); document = cmark_parser_finish(parser); cmark_parser_free(parser); return document; } void cmark_parser_feed(cmark_parser *parser, const char *buffer, size_t len) { S_parser_feed(parser, (const unsigned char *)buffer, len, false); } static void S_parser_feed(cmark_parser *parser, const unsigned char *buffer, size_t len, bool eof) { const unsigned char *end = buffer + len; static const uint8_t repl[] = {239, 191, 189}; if (parser->last_buffer_ended_with_cr && *buffer == '\n') { // skip NL if last buffer ended with CR ; see #117 buffer++; } parser->last_buffer_ended_with_cr = false; while (buffer < end) { const unsigned char *eol; bufsize_t chunk_len; bool process = false; for (eol = buffer; eol < end; ++eol) { if (S_is_line_end_char(*eol)) { process = true; break; } if (*eol == '\0' && eol < end) { break; } } if (eol >= end && eof) { process = true; } chunk_len = (eol - buffer); if (process) { if (parser->linebuf.size > 0) { cmark_strbuf_put(&parser->linebuf, buffer, chunk_len); S_process_line(parser, parser->linebuf.ptr, parser->linebuf.size); cmark_strbuf_clear(&parser->linebuf); } else { S_process_line(parser, buffer, chunk_len); } } else { if (eol < end && *eol == '\0') { // omit NULL byte cmark_strbuf_put(&parser->linebuf, buffer, chunk_len); // add replacement character cmark_strbuf_put(&parser->linebuf, repl, 3); } else { cmark_strbuf_put(&parser->linebuf, buffer, chunk_len); } } buffer += chunk_len; if (buffer < end) { if (*buffer == '\0') { // skip over NULL buffer++; } else { // skip over line ending characters if (*buffer == '\r') { buffer++; if (buffer == end) parser->last_buffer_ended_with_cr = true; } if (buffer < end && *buffer == '\n') buffer++; } } } } static void chop_trailing_hashtags(cmark_chunk *ch) { bufsize_t n, orig_n; cmark_chunk_rtrim(ch); orig_n = n = ch->len - 1; // if string ends in space followed by #s, remove these: while (n >= 0 && peek_at(ch, n) == '#') n--; // Check for a space before the final #s: if (n != orig_n && n >= 0 && S_is_space_or_tab(peek_at(ch, n))) { ch->len = n; cmark_chunk_rtrim(ch); } } // Find first nonspace character from current offset, setting // parser->first_nonspace, parser->first_nonspace_column, // parser->indent, and parser->blank. Does not advance parser->offset. static void S_find_first_nonspace(cmark_parser *parser, cmark_chunk *input) { char c; int chars_to_tab = TAB_STOP - (parser->column % TAB_STOP); if (parser->first_nonspace <= parser->offset) { parser->first_nonspace = parser->offset; parser->first_nonspace_column = parser->column; while ((c = peek_at(input, parser->first_nonspace))) { if (c == ' ') { parser->first_nonspace += 1; parser->first_nonspace_column += 1; chars_to_tab = chars_to_tab - 1; if (chars_to_tab == 0) { chars_to_tab = TAB_STOP; } } else if (c == '\t') { parser->first_nonspace += 1; parser->first_nonspace_column += chars_to_tab; chars_to_tab = TAB_STOP; } else { break; } } } parser->indent = parser->first_nonspace_column - parser->column; parser->blank = S_is_line_end_char(peek_at(input, parser->first_nonspace)); } // Advance parser->offset and parser->column. parser->offset is the // byte position in input; parser->column is a virtual column number // that takes into account tabs. (Multibyte characters are not taken // into account, because the Markdown line prefixes we are interested in // analyzing are entirely ASCII.) The count parameter indicates // how far to advance the offset. If columns is true, then count // indicates a number of columns; otherwise, a number of bytes. // If advancing a certain number of columns partially consumes // a tab character, parser->partially_consumed_tab is set to true. static void S_advance_offset(cmark_parser *parser, cmark_chunk *input, bufsize_t count, bool columns) { char c; int chars_to_tab; int chars_to_advance; while (count > 0 && (c = peek_at(input, parser->offset))) { if (c == '\t') { chars_to_tab = TAB_STOP - (parser->column % TAB_STOP); if (columns) { parser->partially_consumed_tab = chars_to_tab > count; chars_to_advance = MIN(count, chars_to_tab); parser->column += chars_to_advance; parser->offset += (parser->partially_consumed_tab ? 0 : 1); count -= chars_to_advance; } else { parser->partially_consumed_tab = false; parser->column += chars_to_tab; parser->offset += 1; count -= 1; } } else { parser->partially_consumed_tab = false; parser->offset += 1; parser->column += 1; // assume ascii; block starts are ascii count -= 1; } } } static bool S_last_child_is_open(cmark_node *container) { return container->last_child && (container->last_child->flags & CMARK_NODE__OPEN); } static bool parse_block_quote_prefix(cmark_parser *parser, cmark_chunk *input) { bool res = false; bufsize_t matched = 0; matched = parser->indent <= 3 && peek_at(input, parser->first_nonspace) == '>'; if (matched) { S_advance_offset(parser, input, parser->indent + 1, true); if (S_is_space_or_tab(peek_at(input, parser->offset))) { S_advance_offset(parser, input, 1, true); } res = true; } return res; } static bool parse_node_item_prefix(cmark_parser *parser, cmark_chunk *input, cmark_node *container) { bool res = false; if (parser->indent >= container->as.list.marker_offset + container->as.list.padding) { S_advance_offset(parser, input, container->as.list.marker_offset + container->as.list.padding, true); res = true; } else if (parser->blank && container->first_child != NULL) { // if container->first_child is NULL, then the opening line // of the list item was blank after the list marker; in this // case, we are done with the list item. S_advance_offset(parser, input, parser->first_nonspace - parser->offset, false); res = true; } return res; } static bool parse_code_block_prefix(cmark_parser *parser, cmark_chunk *input, cmark_node *container, bool *should_continue) { bool res = false; if (!container->as.code.fenced) { // indented if (parser->indent >= CODE_INDENT) { S_advance_offset(parser, input, CODE_INDENT, true); res = true; } else if (parser->blank) { S_advance_offset(parser, input, parser->first_nonspace - parser->offset, false); res = true; } } else { // fenced bufsize_t matched = 0; if (parser->indent <= 3 && (peek_at(input, parser->first_nonspace) == container->as.code.fence_char)) { matched = scan_close_code_fence(input, parser->first_nonspace); } if (matched >= container->as.code.fence_length) { // closing fence - and since we're at // the end of a line, we can stop processing it: *should_continue = false; S_advance_offset(parser, input, matched, false); parser->current = finalize(parser, container); } else { // skip opt. spaces of fence parser->offset int i = container->as.code.fence_offset; while (i > 0 && S_is_space_or_tab(peek_at(input, parser->offset))) { S_advance_offset(parser, input, 1, true); i--; } res = true; } } return res; } static bool parse_html_block_prefix(cmark_parser *parser, cmark_node *container) { bool res = false; int html_block_type = container->as.html_block_type; assert(html_block_type >= 1 && html_block_type <= 7); switch (html_block_type) { case 1: case 2: case 3: case 4: case 5: // these types of blocks can accept blanks res = true; break; case 6: case 7: res = !parser->blank; break; } return res; } /** * For each containing node, try to parse the associated line start. * * Will not close unmatched blocks, as we may have a lazy continuation * line -> http://spec.commonmark.org/0.24/#lazy-continuation-line * * Returns: The last matching node, or NULL */ static cmark_node *check_open_blocks(cmark_parser *parser, cmark_chunk *input, bool *all_matched) { bool should_continue = true; *all_matched = false; cmark_node *container = parser->root; cmark_node_type cont_type; while (S_last_child_is_open(container)) { container = container->last_child; cont_type = S_type(container); S_find_first_nonspace(parser, input); switch (cont_type) { case CMARK_NODE_BLOCK_QUOTE: if (!parse_block_quote_prefix(parser, input)) goto done; break; case CMARK_NODE_ITEM: if (!parse_node_item_prefix(parser, input, container)) goto done; break; case CMARK_NODE_CODE_BLOCK: if (!parse_code_block_prefix(parser, input, container, &should_continue)) goto done; break; case CMARK_NODE_HEADING: // a heading can never contain more than one line goto done; case CMARK_NODE_HTML_BLOCK: if (!parse_html_block_prefix(parser, container)) goto done; break; case CMARK_NODE_PARAGRAPH: if (parser->blank) goto done; break; default: break; } } *all_matched = true; done: if (!*all_matched) { container = container->parent; // back up to last matching node } if (!should_continue) { container = NULL; } return container; } static void open_new_blocks(cmark_parser *parser, cmark_node **container, cmark_chunk *input, bool all_matched) { bool indented; cmark_list *data = NULL; bool maybe_lazy = S_type(parser->current) == CMARK_NODE_PARAGRAPH; cmark_node_type cont_type = S_type(*container); bufsize_t matched = 0; int lev = 0; bool save_partially_consumed_tab; int save_offset; int save_column; while (cont_type != CMARK_NODE_CODE_BLOCK && cont_type != CMARK_NODE_HTML_BLOCK) { S_find_first_nonspace(parser, input); indented = parser->indent >= CODE_INDENT; if (!indented && peek_at(input, parser->first_nonspace) == '>') { bufsize_t blockquote_startpos = parser->first_nonspace; S_advance_offset(parser, input, parser->first_nonspace + 1 - parser->offset, false); // optional following character if (S_is_space_or_tab(peek_at(input, parser->offset))) { S_advance_offset(parser, input, 1, true); } *container = add_child(parser, *container, CMARK_NODE_BLOCK_QUOTE, blockquote_startpos + 1); } else if (!indented && (matched = scan_atx_heading_start( input, parser->first_nonspace))) { bufsize_t hashpos; int level = 0; bufsize_t heading_startpos = parser->first_nonspace; S_advance_offset(parser, input, parser->first_nonspace + matched - parser->offset, false); *container = add_child(parser, *container, CMARK_NODE_HEADING, heading_startpos + 1); hashpos = cmark_chunk_strchr(input, '#', parser->first_nonspace); while (peek_at(input, hashpos) == '#') { level++; hashpos++; } (*container)->as.heading.level = level; (*container)->as.heading.setext = false; (*container)->internal_offset = matched; } else if (!indented && (matched = scan_open_code_fence( input, parser->first_nonspace))) { *container = add_child(parser, *container, CMARK_NODE_CODE_BLOCK, parser->first_nonspace + 1); (*container)->as.code.fenced = true; (*container)->as.code.fence_char = peek_at(input, parser->first_nonspace); (*container)->as.code.fence_length = (matched > 255) ? 255 : matched; (*container)->as.code.fence_offset = (int8_t)(parser->first_nonspace - parser->offset); (*container)->as.code.info = cmark_chunk_literal(""); S_advance_offset(parser, input, parser->first_nonspace + matched - parser->offset, false); } else if (!indented && ((matched = scan_html_block_start( input, parser->first_nonspace)) || (cont_type != CMARK_NODE_PARAGRAPH && (matched = scan_html_block_start_7( input, parser->first_nonspace))))) { *container = add_child(parser, *container, CMARK_NODE_HTML_BLOCK, parser->first_nonspace + 1); (*container)->as.html_block_type = matched; // note, we don't adjust parser->offset because the tag is part of the // text } else if (!indented && cont_type == CMARK_NODE_PARAGRAPH && (lev = scan_setext_heading_line(input, parser->first_nonspace))) { (*container)->type = (uint16_t)CMARK_NODE_HEADING; (*container)->as.heading.level = lev; (*container)->as.heading.setext = true; S_advance_offset(parser, input, input->len - 1 - parser->offset, false); } else if (!indented && !(cont_type == CMARK_NODE_PARAGRAPH && !all_matched) && (matched = scan_thematic_break(input, parser->first_nonspace))) { // it's only now that we know the line is not part of a setext heading: *container = add_child(parser, *container, CMARK_NODE_THEMATIC_BREAK, parser->first_nonspace + 1); S_advance_offset(parser, input, input->len - 1 - parser->offset, false); } else if ((!indented || cont_type == CMARK_NODE_LIST) && parser->indent < 4 && (matched = parse_list_marker( parser->mem, input, parser->first_nonspace, (*container)->type == CMARK_NODE_PARAGRAPH, &data))) { // Note that we can have new list items starting with >= 4 // spaces indent, as long as the list container is still open. int i = 0; // compute padding: S_advance_offset(parser, input, parser->first_nonspace + matched - parser->offset, false); save_partially_consumed_tab = parser->partially_consumed_tab; save_offset = parser->offset; save_column = parser->column; while (parser->column - save_column <= 5 && S_is_space_or_tab(peek_at(input, parser->offset))) { S_advance_offset(parser, input, 1, true); } i = parser->column - save_column; if (i >= 5 || i < 1 || // only spaces after list marker: S_is_line_end_char(peek_at(input, parser->offset))) { data->padding = matched + 1; parser->offset = save_offset; parser->column = save_column; parser->partially_consumed_tab = save_partially_consumed_tab; if (i > 0) { S_advance_offset(parser, input, 1, true); } } else { data->padding = matched + i; } // check container; if it's a list, see if this list item // can continue the list; otherwise, create a list container. data->marker_offset = parser->indent; if (cont_type != CMARK_NODE_LIST || !lists_match(&((*container)->as.list), data)) { *container = add_child(parser, *container, CMARK_NODE_LIST, parser->first_nonspace + 1); memcpy(&((*container)->as.list), data, sizeof(*data)); } // add the list item *container = add_child(parser, *container, CMARK_NODE_ITEM, parser->first_nonspace + 1); /* TODO: static */ memcpy(&((*container)->as.list), data, sizeof(*data)); parser->mem->free(data); } else if (indented && !maybe_lazy && !parser->blank) { S_advance_offset(parser, input, CODE_INDENT, true); *container = add_child(parser, *container, CMARK_NODE_CODE_BLOCK, parser->offset + 1); (*container)->as.code.fenced = false; (*container)->as.code.fence_char = 0; (*container)->as.code.fence_length = 0; (*container)->as.code.fence_offset = 0; (*container)->as.code.info = cmark_chunk_literal(""); } else { break; } if (accepts_lines(S_type(*container))) { // if it's a line container, it can't contain other containers break; } cont_type = S_type(*container); maybe_lazy = false; } } static void add_text_to_container(cmark_parser *parser, cmark_node *container, cmark_node *last_matched_container, cmark_chunk *input) { cmark_node *tmp; // what remains at parser->offset is a text line. add the text to the // appropriate container. S_find_first_nonspace(parser, input); if (parser->blank && container->last_child) S_set_last_line_blank(container->last_child, true); // block quote lines are never blank as they start with > // and we don't count blanks in fenced code for purposes of tight/loose // lists or breaking out of lists. we also don't set last_line_blank // on an empty list item. const cmark_node_type ctype = S_type(container); const bool last_line_blank = (parser->blank && ctype != CMARK_NODE_BLOCK_QUOTE && ctype != CMARK_NODE_HEADING && ctype != CMARK_NODE_THEMATIC_BREAK && !(ctype == CMARK_NODE_CODE_BLOCK && container->as.code.fenced) && !(ctype == CMARK_NODE_ITEM && container->first_child == NULL && container->start_line == parser->line_number)); S_set_last_line_blank(container, last_line_blank); tmp = container; while (tmp->parent) { S_set_last_line_blank(tmp->parent, false); tmp = tmp->parent; } // If the last line processed belonged to a paragraph node, // and we didn't match all of the line prefixes for the open containers, // and we didn't start any new containers, // and the line isn't blank, // then treat this as a "lazy continuation line" and add it to // the open paragraph. if (parser->current != last_matched_container && container == last_matched_container && !parser->blank && S_type(parser->current) == CMARK_NODE_PARAGRAPH) { add_line(parser->current, input, parser); } else { // not a lazy continuation // Finalize any blocks that were not matched and set cur to container: while (parser->current != last_matched_container) { parser->current = finalize(parser, parser->current); assert(parser->current != NULL); } if (S_type(container) == CMARK_NODE_CODE_BLOCK) { add_line(container, input, parser); } else if (S_type(container) == CMARK_NODE_HTML_BLOCK) { add_line(container, input, parser); int matches_end_condition; switch (container->as.html_block_type) { case 1: // , , matches_end_condition = scan_html_block_end_1(input, parser->first_nonspace); break; case 2: // --> matches_end_condition = scan_html_block_end_2(input, parser->first_nonspace); break; case 3: // ?> matches_end_condition = scan_html_block_end_3(input, parser->first_nonspace); break; case 4: // > matches_end_condition = scan_html_block_end_4(input, parser->first_nonspace); break; case 5: // ]]> matches_end_condition = scan_html_block_end_5(input, parser->first_nonspace); break; default: matches_end_condition = 0; break; } if (matches_end_condition) { container = finalize(parser, container); assert(parser->current != NULL); } } else if (parser->blank) { // ??? do nothing } else if (accepts_lines(S_type(container))) { if (S_type(container) == CMARK_NODE_HEADING && container->as.heading.setext == false) { chop_trailing_hashtags(input); } S_advance_offset(parser, input, parser->first_nonspace - parser->offset, false); add_line(container, input, parser); } else { // create paragraph container for line container = add_child(parser, container, CMARK_NODE_PARAGRAPH, parser->first_nonspace + 1); S_advance_offset(parser, input, parser->first_nonspace - parser->offset, false); add_line(container, input, parser); } parser->current = container; } } /* See http://spec.commonmark.org/0.24/#phase-1-block-structure */ static void S_process_line(cmark_parser *parser, const unsigned char *buffer, bufsize_t bytes) { cmark_node *last_matched_container; bool all_matched = true; cmark_node *container; cmark_chunk input; if (parser->options & CMARK_OPT_VALIDATE_UTF8) cmark_utf8proc_check(&parser->curline, buffer, bytes); else cmark_strbuf_put(&parser->curline, buffer, bytes); bytes = parser->curline.size; // ensure line ends with a newline: if (bytes == 0 || !S_is_line_end_char(parser->curline.ptr[bytes - 1])) cmark_strbuf_putc(&parser->curline, '\n'); parser->offset = 0; parser->column = 0; parser->first_nonspace = 0; parser->first_nonspace_column = 0; parser->indent = 0; parser->blank = false; parser->partially_consumed_tab = false; input.data = parser->curline.ptr; input.len = parser->curline.size; input.alloc = 0; parser->line_number++; last_matched_container = check_open_blocks(parser, &input, &all_matched); if (!last_matched_container) goto finished; container = last_matched_container; open_new_blocks(parser, &container, &input, all_matched); add_text_to_container(parser, container, last_matched_container, &input); finished: parser->last_line_length = input.len; if (parser->last_line_length && input.data[parser->last_line_length - 1] == '\n') parser->last_line_length -= 1; if (parser->last_line_length && input.data[parser->last_line_length - 1] == '\r') parser->last_line_length -= 1; cmark_strbuf_clear(&parser->curline); } cmark_node *cmark_parser_finish(cmark_parser *parser) { if (parser->linebuf.size) { S_process_line(parser, parser->linebuf.ptr, parser->linebuf.size); cmark_strbuf_clear(&parser->linebuf); } finalize_document(parser); cmark_consolidate_text_nodes(parser->root); cmark_strbuf_free(&parser->curline); #if CMARK_DEBUG_NODES if (cmark_node_check(parser->root, stderr)) { abort(); } #endif return parser->root; }