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tree)
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// So far instructions can only contain linear lists of properties. Now we add
// support for more complex trees of properties in dilated reagents. This will
// come in handy later for expressing complex types, like "a dictionary from
// (address to array of charaters) to (list of numbers)".
//
// Type trees aren't as general as s-expressions even if they look like them:
// the first element of a type tree is always an atom, and it can never be
// dotted (right->right->right->...->right is always NULL).
//
// For now you can't use the simpler 'colon-based' representation inside type
// trees. Once you start typing parens, keep on typing parens.
void test_dilated_reagent_with_nested_brackets() {
load(
"def main [\n"
" {1: number, foo: (bar (baz quux))} <- copy 34\n"
"]\n"
);
CHECK_TRACE_CONTENTS(
"parse: product: {1: \"number\", \"foo\": (\"bar\" (\"baz\" \"quux\"))}\n"
);
}
:(before "End Parsing Dilated Reagent Property(value)")
value = parse_string_tree(value);
:(before "End Parsing Dilated Reagent Type Property(type_names)")
type_names = parse_string_tree(type_names);
:(code)
string_tree* parse_string_tree(string_tree* s) {
assert(s->atom);
if (!starts_with(s->value, "(")) return s;
string_tree* result = parse_string_tree(s->value);
delete s;
return result;
}
string_tree* parse_string_tree(const string& s) {
istringstream in(s);
in >> std::noskipws;
return parse_string_tree(in);
}
string_tree* parse_string_tree(istream& in) {
skip_whitespace_but_not_newline(in);
if (!has_data(in)) return NULL;
if (in.peek() == ')') {
in.get();
return NULL;
}
if (in.peek() != '(') {
string s = next_word(in);
if (s.empty()) {
assert(!has_data(in));
raise << "incomplete string tree at end of file (0)\n" << end();
return NULL;
}
string_tree* result = new string_tree(s);
return result;
}
in.get(); // skip '('
string_tree* result = NULL;
string_tree** curr = &result;
while (true) {
skip_whitespace_but_not_newline(in);
assert(has_data(in));
if (in.peek() == ')') break;
*curr = new string_tree(NULL, NULL);
if (in.peek() == '(') {
(*curr)->left = parse_string_tree(in);
}
else {
string s = next_word(in);
if (s.empty()) {
assert(!has_data(in));
raise << "incomplete string tree at end of file (1)\n" << end();
return NULL;
}
(*curr)->left = new string_tree(s);
}
curr = &(*curr)->right;
}
in.get(); // skip ')'
assert(*curr == NULL);
return result;
}
void test_dilated_reagent_with_type_tree() {
Hide_errors = true; // 'map' isn't defined yet
load(
"def main [\n"
" {1: (foo (address array character) (bar number))} <- copy 34\n"
"]\n"
"container foo [\n"
"]\n"
"container bar [\n"
"]\n"
);
CHECK_TRACE_CONTENTS(
"parse: product: {1: (\"foo\" (\"address\" \"array\" \"character\") (\"bar\" \"number\"))}\n"
);
}
void test_dilated_empty_tree() {
load(
"def main [\n"
" {1: number, foo: ()} <- copy 34\n"
"]\n"
);
CHECK_TRACE_CONTENTS(
"parse: product: {1: \"number\", \"foo\": ()}\n"
);
}
void test_dilated_singleton_tree() {
load(
"def main [\n"
" {1: number, foo: (bar)} <- copy 34\n"
"]\n"
);
CHECK_TRACE_CONTENTS(
"parse: product: {1: \"number\", \"foo\": (\"bar\")}\n"
);
}
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