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|
//: A program is a book of 'recipes' (functions)
:(before "End Globals")
//: Each recipe is stored at a specific page number, or ordinal.
map<recipe_ordinal, recipe> Recipe;
//: You can also refer to each recipe by its name.
map<string, recipe_ordinal> Recipe_ordinal;
recipe_ordinal Next_recipe_ordinal = 1;
//: Ordinals are like numbers, except you can't do arithmetic on them. Ordinal
//: 1 is not less than 2, it's just different. Phone numbers are ordinals;
//: adding two phone numbers is meaningless. Here each recipe does something
//: incommensurable with any other recipe.
:(after "Types")
typedef long long int recipe_ordinal;
:(before "End Types")
// Recipes are lists of instructions. To perform or 'run' a recipe, the
// computer runs its instructions.
struct recipe {
string name;
vector<instruction> steps;
// End recipe Fields
recipe();
};
:(before "struct recipe")
// Each instruction is either of the form:
// product1, product2, product3, ... <- operation ingredient1, ingredient2, ingredient3, ...
// or just a single 'label' starting with a non-alphanumeric character
// +label
// Labels don't do anything, they're just waypoints.
struct instruction {
bool is_label;
string label; // only if is_label
string name; // only if !is_label
string old_name; // before our automatic rewrite rules
string original_string;
recipe_ordinal operation; // get(Recipe_ordinal, name)
vector<reagent> ingredients; // only if !is_label
vector<reagent> products; // only if !is_label
// End instruction Fields
instruction();
void clear();
bool is_empty();
};
:(before "struct instruction")
// Ingredients and products are a single species -- a reagent. Reagents refer
// either to numbers or to locations in memory along with 'type' tags telling
// us how to interpret them. They also can contain arbitrary other lists of
// properties besides types, but we're getting ahead of ourselves.
struct reagent {
string original_string;
string name;
type_tree* type;
vector<pair<string, string_tree*> > properties; // can't be a map because the string_tree sometimes needs to be NULL, which can be confusing
double value;
bool initialized;
reagent(string s);
reagent() :type(NULL), value(0), initialized(false) {}
~reagent();
void clear();
reagent(const reagent& old);
reagent& operator=(const reagent& old);
void set_value(double v) { value = v; initialized = true; }
};
:(before "struct reagent")
// Types can range from a simple type ordinal, to arbitrarily complex trees of
// type parameters, like (map (address array character) (list number))
struct type_tree {
string name;
type_ordinal value;
type_tree* left;
type_tree* right;
~type_tree();
type_tree(const type_tree& old);
// simple: type ordinal
explicit type_tree(string name, type_ordinal v) :name(name), value(v), left(NULL), right(NULL) {}
// intermediate: list of type ordinals
type_tree(string name, type_ordinal v, type_tree* r) :name(name), value(v), left(NULL), right(r) {}
// advanced: tree containing type ordinals
type_tree(type_tree* l, type_tree* r) :value(0), left(l), right(r) {}
};
struct string_tree {
string value;
string_tree* left;
string_tree* right;
~string_tree();
string_tree(const string_tree& old);
// simple: flat string
explicit string_tree(string v) :value(v), left(NULL), right(NULL) {}
// intermediate: list of strings
string_tree(string v, string_tree* r) :value(v), left(NULL), right(r) {}
// advanced: tree containing strings
string_tree(string_tree* l, string_tree* r) :left(l), right(r) {}
};
:(before "End Globals")
// Locations refer to a common 'memory'. Each location can store a number.
map<long long int, double> Memory;
:(before "End Setup")
Memory.clear();
:(after "Types")
// Mu types encode how the numbers stored in different parts of memory are
// interpreted. A location tagged as a 'character' type will interpret the
// value 97 as the letter 'a', while a different location of type 'number'
// would not.
//
// Unlike most computers today, mu stores types in a single big table, shared
// by all the mu programs on the computer. This is useful in providing a
// seamless experience to help understand arbitrary mu programs.
typedef long long int type_ordinal;
:(before "End Globals")
map<string, type_ordinal> Type_ordinal;
map<type_ordinal, type_info> Type;
type_ordinal Next_type_ordinal = 1;
:(code)
void setup_types() {
Type.clear(); Type_ordinal.clear();
put(Type_ordinal, "literal", 0);
Next_type_ordinal = 1;
// Mu Types Initialization
type_ordinal number = put(Type_ordinal, "number", Next_type_ordinal++);
put(Type_ordinal, "location", get(Type_ordinal, "number")); // wildcard type: either a pointer or a scalar
get_or_insert(Type, number).name = "number";
type_ordinal address = put(Type_ordinal, "address", Next_type_ordinal++);
get_or_insert(Type, address).name = "address";
type_ordinal boolean = put(Type_ordinal, "boolean", Next_type_ordinal++);
get_or_insert(Type, boolean).name = "boolean";
type_ordinal character = put(Type_ordinal, "character", Next_type_ordinal++);
get_or_insert(Type, character).name = "character";
// Array types are a special modifier to any other type. For example,
// array:number or array:address:boolean.
type_ordinal array = put(Type_ordinal, "array", Next_type_ordinal++);
get_or_insert(Type, array).name = "array";
// End Mu Types Initialization
}
void teardown_types() {
for (map<type_ordinal, type_info>::iterator p = Type.begin(); p != Type.end(); ++p) {
for (long long int i = 0; i < SIZE(p->second.elements); ++i)
p->second.elements.clear();
}
Type_ordinal.clear();
}
:(before "End One-time Setup")
setup_types();
atexit(teardown_types);
:(before "End Types")
// You can construct arbitrary new types. New types are either 'containers'
// with multiple 'elements' of other types, or 'exclusive containers' containing
// one of multiple 'variants'. (These are similar to C structs and unions,
// respectively, though exclusive containers implicitly include a tag element
// recording which variant they should be interpreted as.)
//
// For example, storing bank balance and name for an account might require a
// container, but if bank accounts may be either for individuals or groups,
// with different properties for each, that may require an exclusive container
// whose variants are individual-account and joint-account containers.
enum kind_of_type {
PRIMITIVE,
CONTAINER,
EXCLUSIVE_CONTAINER
};
struct type_info {
string name;
kind_of_type kind;
long long int size; // only if type is not primitive; primitives and addresses have size 1 (except arrays are dynamic)
vector<reagent> elements;
// End type_info Fields
type_info() :kind(PRIMITIVE), size(0) {}
};
enum primitive_recipes {
IDLE = 0,
COPY,
// End Primitive Recipe Declarations
MAX_PRIMITIVE_RECIPES,
};
:(code)
//: It's all very well to construct recipes out of other recipes, but we need
//: to know how to do *something* out of the box. For the following
//: recipes there are only codes, no entries in the book, because mu just knows
//: what to do for them.
void setup_recipes() {
Recipe.clear(); Recipe_ordinal.clear();
put(Recipe_ordinal, "idle", IDLE);
// Primitive Recipe Numbers
put(Recipe_ordinal, "copy", COPY);
// End Primitive Recipe Numbers
}
//: We could just reset the recipe table after every test, but that gets slow
//: all too quickly. Instead, initialize the common stuff just once at
//: startup. Later layers will carefully undo each test's additions after
//: itself.
:(before "End One-time Setup")
setup_recipes();
assert(MAX_PRIMITIVE_RECIPES < 200); // level 0 is primitives; until 199
Next_recipe_ordinal = 200;
put(Recipe_ordinal, "main", Next_recipe_ordinal++);
// End Load Recipes
:(before "End Test Run Initialization")
assert(Next_recipe_ordinal < 1000); // recipes being tested didn't overflow into test space
:(before "End Setup")
Next_recipe_ordinal = 1000; // consistent new numbers for each test
//:: Helpers
:(code)
recipe::recipe() {
// End recipe Constructor
}
instruction::instruction() :is_label(false), operation(IDLE) {
// End instruction Constructor
}
void instruction::clear() { is_label=false; label.clear(); name.clear(); old_name.clear(); operation=IDLE; ingredients.clear(); products.clear(); original_string.clear(); }
bool instruction::is_empty() { return !is_label && name.empty(); }
// Reagents have the form <name>:<type>:<type>:.../<property>/<property>/...
reagent::reagent(string s) :original_string(s), type(NULL), value(0), initialized(false) {
// Parsing reagent(string s)
istringstream in(s);
in >> std::noskipws;
// name and type
istringstream first_row(slurp_until(in, '/'));
first_row >> std::noskipws;
name = slurp_until(first_row, ':');
string_tree* type_names = parse_property_list(first_row);
type = new_type_tree(type_names);
delete type_names;
// special cases
if (is_integer(name) && type == NULL)
type = new type_tree("literal", get(Type_ordinal, "literal"));
if (name == "_" && type == NULL)
type = new type_tree("literal", get(Type_ordinal, "literal"));
// other properties
while (has_data(in)) {
istringstream row(slurp_until(in, '/'));
row >> std::noskipws;
string key = slurp_until(row, ':');
string_tree* value = parse_property_list(row);
properties.push_back(pair<string, string_tree*>(key, value));
}
// End Parsing reagent
}
string_tree* parse_property_list(istream& in) {
skip_whitespace_but_not_newline(in);
if (!has_data(in)) return NULL;
string_tree* result = new string_tree(slurp_until(in, ':'));
result->right = parse_property_list(in);
return result;
}
type_tree* new_type_tree(const string_tree* properties) {
if (!properties) return NULL;
type_tree* result = new type_tree("", 0);
if (!properties->value.empty()) {
const string& type_name = result->name = properties->value;
if (contains_key(Type_ordinal, type_name))
result->value = get(Type_ordinal, type_name);
else if (is_integer(type_name)) // sometimes types will contain non-type tags, like numbers for the size of an array
result->value = 0;
else if (properties->value != "->") // used in recipe types
result->value = -1; // should never happen; will trigger errors later
}
result->left = new_type_tree(properties->left);
result->right = new_type_tree(properties->right);
return result;
}
//: avoid memory leaks for the type tree
reagent::reagent(const reagent& old) {
original_string = old.original_string;
name = old.name;
value = old.value;
initialized = old.initialized;
for (long long int i = 0; i < SIZE(old.properties); ++i) {
properties.push_back(pair<string, string_tree*>(old.properties.at(i).first,
old.properties.at(i).second ? new string_tree(*old.properties.at(i).second) : NULL));
}
type = old.type ? new type_tree(*old.type) : NULL;
}
type_tree::type_tree(const type_tree& old) {
name = old.name;
value = old.value;
left = old.left ? new type_tree(*old.left) : NULL;
right = old.right ? new type_tree(*old.right) : NULL;
}
string_tree::string_tree(const string_tree& old) { // :value(old.value) {
value = old.value;
left = old.left ? new string_tree(*old.left) : NULL;
right = old.right ? new string_tree(*old.right) : NULL;
}
reagent& reagent::operator=(const reagent& old) {
original_string = old.original_string;
for (long long int i = 0; i < SIZE(properties); ++i)
if (properties.at(i).second) delete properties.at(i).second;
properties.clear();
for (long long int i = 0; i < SIZE(old.properties); ++i)
properties.push_back(pair<string, string_tree*>(old.properties.at(i).first, old.properties.at(i).second ? new string_tree(*old.properties.at(i).second) : NULL));
name = old.name;
value = old.value;
initialized = old.initialized;
if (type) delete type;
type = old.type ? new type_tree(*old.type) : NULL;
return *this;
}
reagent::~reagent() {
clear();
}
void reagent::clear() {
for (long long int i = 0; i < SIZE(properties); ++i) {
if (properties.at(i).second) {
delete properties.at(i).second;
properties.at(i).second = NULL;
}
}
delete type;
type = NULL;
}
type_tree::~type_tree() {
delete left;
delete right;
}
string_tree::~string_tree() {
delete left;
delete right;
}
string slurp_until(istream& in, char delim) {
ostringstream out;
char c;
while (in >> c) {
if (c == delim) {
// drop the delim
break;
}
out << c;
}
return out.str();
}
bool has_property(reagent x, string name) {
for (long long int i = 0; i < SIZE(x.properties); ++i) {
if (x.properties.at(i).first == name) return true;
}
return false;
}
string_tree* property(const reagent& r, const string& name) {
for (long long int p = 0; p != SIZE(r.properties); ++p) {
if (r.properties.at(p).first == name)
return r.properties.at(p).second;
}
return NULL;
}
:(before "End Globals")
const string Ignore(","); // commas are ignored in mu except within [] strings
:(code)
void skip_whitespace_but_not_newline(istream& in) {
while (true) {
if (!has_data(in)) break;
else if (in.peek() == '\n') break;
else if (isspace(in.peek())) in.get();
else if (Ignore.find(in.peek()) != string::npos) in.get();
else break;
}
}
void dump_memory() {
for (map<long long int, double>::iterator p = Memory.begin(); p != Memory.end(); ++p) {
cout << p->first << ": " << no_scientific(p->second) << '\n';
}
}
//:: Helpers for converting various values to string
//: Use to_string() in trace(), and try to avoid relying on unstable codes that
//: will perturb .traces/ from commit to commit.
//: Use debug_string() while debugging, and throw everything into it.
//: Use inspect() only for emitting a canonical format that can be parsed back
//: into the value.
string to_string(const recipe& r) {
ostringstream out;
out << "recipe " << r.name << " [\n";
for (long long int i = 0; i < SIZE(r.steps); ++i)
out << " " << to_string(r.steps.at(i)) << '\n';
out << "]\n";
return out.str();
}
string debug_string(const recipe& x) {
ostringstream out;
out << "- recipe " << x.name << '\n';
// Begin debug_string(recipe x)
for (long long int index = 0; index < SIZE(x.steps); ++index) {
const instruction& inst = x.steps.at(index);
out << "inst: " << to_string(inst) << '\n';
out << " ingredients\n";
for (long long int i = 0; i < SIZE(inst.ingredients); ++i)
out << " " << debug_string(inst.ingredients.at(i)) << '\n';
out << " products\n";
for (long long int i = 0; i < SIZE(inst.products); ++i)
out << " " << debug_string(inst.products.at(i)) << '\n';
}
return out.str();
}
string to_string(const instruction& inst) {
if (inst.is_label) return inst.label;
ostringstream out;
for (long long int i = 0; i < SIZE(inst.products); ++i) {
if (i > 0) out << ", ";
out << inst.products.at(i).original_string;
}
if (!inst.products.empty()) out << " <- ";
out << inst.name << ' ';
for (long long int i = 0; i < SIZE(inst.ingredients); ++i) {
if (i > 0) out << ", ";
out << inst.ingredients.at(i).original_string;
}
return out.str();
}
string to_string(const reagent& r) {
ostringstream out;
out << r.name << ": " << names_to_string(r.type);
if (!r.properties.empty()) {
out << ", {";
for (long long int i = 0; i < SIZE(r.properties); ++i) {
if (i > 0) out << ", ";
out << "\"" << r.properties.at(i).first << "\": " << to_string(r.properties.at(i).second);
}
out << "}";
}
return out.str();
}
string debug_string(const reagent& x) {
ostringstream out;
out << x.name << ": " << x.value << ' ' << to_string(x.type) << " -- " << to_string(x);
return out.str();
}
string to_string(const string_tree* property) {
if (!property) return "()";
ostringstream out;
if (!property->left && !property->right)
// abbreviate a single-node tree to just its contents
out << '"' << property->value << '"';
else
dump(property, out);
return out.str();
}
void dump(const string_tree* x, ostream& out) {
if (!x->left && !x->right) {
out << x->value;
return;
}
out << '(';
for (const string_tree* curr = x; curr; curr = curr->right) {
if (curr != x) out << ' ';
if (curr->left)
dump(curr->left, out);
else
out << '"' << curr->value << '"';
}
out << ')';
}
string to_string(const type_tree* type) {
// abbreviate a single-node tree to just its contents
if (!type) return "NULLNULLNULL"; // should never happen
ostringstream out;
dump(type, out);
return out.str();
}
void dump(const type_tree* x, ostream& out) {
if (!x->left && !x->right) {
dump(x->value, out);
return;
}
out << '(';
for (const type_tree* curr = x; curr; curr = curr->right) {
if (curr != x) out << ' ';
if (curr->left)
dump(curr->left, out);
else
dump(curr->value, out);
}
out << ')';
}
void dump(type_ordinal type, ostream& out) {
if (contains_key(Type, type))
out << get(Type, type).name;
else
out << "?" << type;
}
string names_to_string(const type_tree* type) {
// abbreviate a single-node tree to just its contents
if (!type) return "()"; // should never happen
ostringstream out;
dump_names(type, out);
return out.str();
}
void dump_names(const type_tree* type, ostream& out) {
if (!type->left && !type->right) {
out << '"' << type->name << '"';
return;
}
out << '(';
for (const type_tree* curr = type; curr; curr = curr->right) {
if (curr != type) out << ' ';
if (curr->left)
dump_names(curr->left, out);
else
out << '"' << curr->name << '"';
}
out << ')';
}
string names_to_string_without_quotes(const type_tree* type) {
// abbreviate a single-node tree to just its contents
if (!type) return "NULLNULLNULL"; // should never happen
ostringstream out;
dump_names_without_quotes(type, out);
return out.str();
}
void dump_names_without_quotes(const type_tree* type, ostream& out) {
if (!type->left && !type->right) {
out << type->name;
return;
}
out << '(';
for (const type_tree* curr = type; curr; curr = curr->right) {
if (curr != type) out << ' ';
if (curr->left)
dump_names_without_quotes(curr->left, out);
else
out << curr->name;
}
out << ')';
}
//: helper to print numbers without excessive precision
:(before "End Types")
struct no_scientific {
double x;
explicit no_scientific(double y) :x(y) {}
};
:(code)
ostream& operator<<(ostream& os, no_scientific x) {
if (!isfinite(x.x)) {
// Infinity or NaN
os << x.x;
return os;
}
ostringstream tmp;
tmp << std::fixed << x.x;
os << trim_floating_point(tmp.str());
return os;
}
string trim_floating_point(const string& in) {
if (in.empty()) return "";
long long int len = SIZE(in);
while (len > 1) {
if (in.at(len-1) != '0') break;
--len;
}
if (in.at(len-1) == '.') --len;
return in.substr(0, len);
}
void test_trim_floating_point() {
CHECK_EQ("", trim_floating_point(""));
CHECK_EQ("0", trim_floating_point("000000000"));
CHECK_EQ("1.5", trim_floating_point("1.5000"));
CHECK_EQ("1.000001", trim_floating_point("1.000001"));
CHECK_EQ("23", trim_floating_point("23.000000"));
CHECK_EQ("23", trim_floating_point("23.0"));
CHECK_EQ("23", trim_floating_point("23."));
CHECK_EQ("23", trim_floating_point("23"));
CHECK_EQ("3", trim_floating_point("3.000000"));
CHECK_EQ("3", trim_floating_point("3.0"));
CHECK_EQ("3", trim_floating_point("3."));
CHECK_EQ("3", trim_floating_point("3"));
}
:(before "End Includes")
#include<utility>
using std::pair;
#include<math.h>
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