blob: 957a43f6b9c0ca8c2c5ec3bdd6e11f92ededbcde (
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//: So far the recipes we define can't run each other. Let's fix that.
:(scenario calling_recipe)
recipe main [
f
]
recipe f [
3:number <- add 2, 2
]
+mem: storing 4 in location 3
:(scenario return_on_fallthrough)
recipe main [
f
1:number <- copy 0
2:number <- copy 0
3:number <- copy 0
]
recipe f [
4:number <- copy 0
5:number <- copy 0
]
+run: f
# running f
+run: 4:number <- copy 0
+run: 5:number <- copy 0
# back out to main
+run: 1:number <- copy 0
+run: 2:number <- copy 0
+run: 3:number <- copy 0
:(before "struct routine {")
// Everytime a recipe runs another, we interrupt it and start running the new
// recipe. When that finishes, we continue this one where we left off.
// This requires maintaining a 'stack' of interrupted recipes or 'calls'.
struct call {
recipe_ordinal running_recipe;
long long int running_step_index;
// End call Fields
call(recipe_ordinal r) {
running_recipe = r;
running_step_index = 0;
// End call Constructor
}
~call() {
// End call Destructor
}
};
typedef list<call> call_stack;
:(replace{} "struct routine")
struct routine {
call_stack calls;
// End routine Fields
routine(recipe_ordinal r);
bool completed() const;
const vector<instruction>& steps() const;
};
:(code)
routine::routine(recipe_ordinal r) {
if (Trace_stream) {
++Trace_stream->callstack_depth;
trace(9999, "trace") << "new routine; incrementing callstack depth to " << Trace_stream->callstack_depth << end();
assert(Trace_stream->callstack_depth < 9000); // 9998-101 plus cushion
}
calls.push_front(call(r));
// End routine Constructor
}
:(code)
inline call& current_call() {
return Current_routine->calls.front();
}
//:: now update routine's helpers
:(replace{} "inline long long int& current_step_index()")
inline long long int& current_step_index() {
assert(!Current_routine->calls.empty());
return current_call().running_step_index;
}
:(replace{} "inline const string& current_recipe_name()")
inline const string& current_recipe_name() {
assert(!Current_routine->calls.empty());
return get(Recipe, current_call().running_recipe).name;
}
:(replace{} "inline const instruction& current_instruction()")
inline const instruction& current_instruction() {
assert(!Current_routine->calls.empty());
return to_instruction(current_call());
}
:(code)
inline const instruction& to_instruction(const call& call) {
return get(Recipe, call.running_recipe).steps.at(call.running_step_index);
}
:(after "Defined Recipe Checks")
// not a primitive; check that it's present in the book of recipes
if (!contains_key(Recipe, inst.operation)) {
raise_error << maybe(get(Recipe, r).name) << "undefined operation in '" << inst.to_string() << "'\n" << end();
break;
}
:(replace{} "default:" following "End Primitive Recipe Implementations")
default: {
const instruction& call_instruction = current_instruction();
if (Recipe.find(current_instruction().operation) == Recipe.end()) { // duplicate from Checks
// stop running this instruction immediately
++current_step_index();
continue;
}
// not a primitive; look up the book of recipes
if (Trace_stream) {
++Trace_stream->callstack_depth;
trace(9999, "trace") << "incrementing callstack depth to " << Trace_stream->callstack_depth << end();
assert(Trace_stream->callstack_depth < 9000); // 9998-101 plus cushion
}
Current_routine->calls.push_front(call(current_instruction().operation));
// End Call Housekeeping
continue; // not done with caller; don't increment current_step_index()
}
:(scenario calling_undefined_recipe_fails)
% Hide_errors = true;
recipe main [
foo
]
+error: main: undefined operation in 'foo '
:(scenario calling_undefined_recipe_handles_missing_result)
% Hide_errors = true;
recipe main [
x:number <- foo
]
+error: main: undefined operation in 'x:number <- foo '
//:: finally, we need to fix the termination conditions for the run loop
:(replace{} "inline bool routine::completed() const")
inline bool routine::completed() const {
return calls.empty();
}
inline const vector<instruction>& routine::steps() const {
assert(!calls.empty());
return get(Recipe, calls.front().running_recipe).steps;
}
:(before "Running One Instruction")
// when we reach the end of one call, we may reach the end of the one below
// it, and the one below that, and so on
while (current_step_index() >= SIZE(Current_routine->steps())) {
// Falling Through End Of Recipe
if (Trace_stream) {
trace(9999, "trace") << "fall-through: exiting " << current_recipe_name() << "; decrementing callstack depth from " << Trace_stream->callstack_depth << end();
--Trace_stream->callstack_depth;
assert(Trace_stream->callstack_depth >= 0);
}
Current_routine->calls.pop_front();
if (Current_routine->calls.empty()) return;
// Complete Call Fallthrough
// todo: fail if no products returned
++current_step_index();
}
:(before "End Includes")
#include <stack>
using std::stack;
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