// Abstract semantic graph (ASG) intermediate representation (IR)
//
// Copyright (C) 2014-2022 Ryan Specialty Group, LLC.
//
// This file is part of TAME.
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see .
//! Abstract semantic graph.
//!
//! The [abstract semantic graph][asg] (ASG) is an IR representing the
//! relationship between objects using a directed [graph][].
//! An _object_ is an identifier or expression.
//!
//! Since TAME is a declarative language,
//! the ASG does not represent control flow;
//! instead, it represents the relationship between objects and their
//! dependencies.
//! Control flow is determined solely by the [linker][crate::ld] based on
//! these dependencies.
//!
//! See [`crate::global`] for available index sizes depending on context.
//! For example,
//! a linker may choose to use [`crate::global::ProgIdentSize`];
//!
//!
//! Graph Structure
//! ===============
//! Each node (vector) in the graph represents an [object][IdentObject],
//! such as an identifier or an expression.
//! Each directed edge `(A->B)` represents that `A` depends upon `B`.
//!
//! Graphs may contain cycles for recursive functions—that is,
//! TAME's ASG is _not_ a DAG.
//! Mutually recursive functions are therefore represented as
//! [strongly connected components][scc].
//!
//! [asg]: https://en.wikipedia.org/wiki/Abstract_semantic_graph
//! [graph]: https://en.wikipedia.org/wiki/Graph_(discrete_mathematics)
//! [scc]: https://en.wikipedia.org/wiki/Strongly_connected_component
//!
//! Each object may have a number of valid states;
//! see [`IdentObject`] for valid object states and transitions.
//!
//!
//! How To Use
//! ==========
//! A suitable concrete [`Asg`] implementation is provided by
//! [`DefaultAsg`].
//!
//! ```
//! use tamer::global;
//! use tamer::asg::{DefaultAsg, IdentKind, IdentObject, Source};
//! use tamer::sym::{Interner, DefaultProgInterner};
//!
//! # fn main() -> Result<(), Box> {
//! // Be sure to choose size and initial capacities appropriate for your
//! // situation.
//! let mut asg = DefaultAsg::::with_capacity(
//! 1024,
//! 1024,
//! );
//!
//! let interner = DefaultProgInterner::new();
//! let identa_sym = interner.intern("identa");
//! let identb_sym = interner.intern("identb");
//!
//! let identa = asg.declare(identa_sym, IdentKind::Meta, Source::default())?;
//! let identb = asg.declare_extern(identb_sym, IdentKind::Meta, Source::default())?;
//!
//! assert_eq!(
//! Some(&IdentObject::Extern(identb_sym, IdentKind::Meta, Source::default())),
//! asg.get(identb),
//! );
//!
//! // Dependencies can be declared even if an identifier is
//! // unresolved. This declares `(identa)->(identb)`.
//! asg.add_dep(identa, identb);
//! assert!(asg.has_dep(identa, identb));
//!
//! // TODO: extern resolution
//!
//! // Identifiers are indexed by symbol name.
//! assert_eq!(Some(identa), asg.lookup(identa_sym));
//! #
//! # Ok(()) // main
//! # }
//! ```
//!
//! Missing Identifiers
//! -------------------
//! Since identifiers in TAME can be defined in any order relative to their
//! dependencies within a source file,
//! it is often the case that a dependency will have to be added to the
//! graph before it is resolved.
//! For example,
//! [`Asg::add_dep_lookup`] will add an [`IdentObject::Missing`] to the graph
//! if either identifier has not yet been declared.
//!
//! ```
//! # use tamer::global;
//! # use tamer::asg::{DefaultAsg, IdentKind, IdentObject, FragmentText, Source};
//! # use tamer::sym::{Interner, DefaultProgInterner};
//! #
//! # fn main() -> Result<(), Box> {
//! # let mut asg = DefaultAsg::::with_capacity(
//! # 1024,
//! # 1024,
//! # );
//! # let interner = DefaultProgInterner::new();
//! #
//! let identa_sym = interner.intern("identa");
//! let identb_sym = interner.intern("identb");
//! let (identa, identb) = asg.add_dep_lookup(identa_sym, identb_sym);
//!
//! assert_eq!(Some(&IdentObject::Missing(identa_sym)), asg.get(identa));
//! assert_eq!(Some(&IdentObject::Missing(identb_sym)), asg.get(identb));
//!
//! // The identifiers returned above are proper objects on the graph.
//! assert_eq!(Some(identa), asg.lookup(identa_sym));
//! assert_eq!(Some(identb), asg.lookup(identb_sym));
//!
//! // Once declared, the missing identifier changes state and dependencies
//! // are retained.
//! asg.declare(identa_sym, IdentKind::Meta, Source::default())?;
//!
//! assert_eq!(
//! Some(&IdentObject::Ident(identa_sym, IdentKind::Meta, Source::default())),
//! asg.get(identa),
//! );
//!
//! assert!(asg.has_dep(identa, identb));
//! #
//! # Ok(()) // main
//! # }
//! ```
//!
//! Fragments
//! ---------
//! A compiled fragment can be attached to any resolved identifier (see
//! [`IdentObject::Ident`]) using [`Asg::set_fragment`].
//! Doing so changes the state of the identifier to [`IdentObject::IdentFragment`],
//! and it is an error to attempt to overwrite that fragment once it is
//! set.
//!
//! ```
//! # use tamer::global;
//! # use tamer::asg::{DefaultAsg, IdentKind, IdentObject, FragmentText, Source};
//! # use tamer::sym::{Interner, DefaultProgInterner};
//! #
//! # fn main() -> Result<(), Box> {
//! # let mut asg = DefaultAsg::::with_capacity(
//! # 1024,
//! # 1024,
//! # );
//! # let interner = DefaultProgInterner::new();
//! #
//! // Fragments can be attached to resolved identifiers.
//! let ident = asg.declare(
//! interner.intern("ident"), IdentKind::Meta, Source::default()
//! )?;
//! asg.set_fragment(ident, FragmentText::from("test fragment"))?;
//!
//! assert_eq!(
//! Some(&IdentObject::IdentFragment(
//! interner.intern("ident"),
//! IdentKind::Meta,
//! Source::default(),
//! FragmentText::from("test fragment"),
//! )),
//! asg.get(ident),
//! );
//!
//! // But overwriting will fail
//! let bad = asg.set_fragment(ident, FragmentText::from("overwrite"));
//! assert!(bad.is_err());
//! #
//! # Ok(()) // main
//! # }
//! ```
mod error;
mod graph;
mod ident;
mod object;
pub use error::AsgError;
pub use graph::{Asg, AsgResult, IndexType, ObjectRef};
pub use ident::{DataType, Dim, IdentKind, IdentKindError};
pub use object::{
FragmentText, IdentObject, IdentObjectData, IdentObjectState, Source,
TransitionError, TransitionResult, UnresolvedError,
};
/// Default concrete ASG implementation.
pub type DefaultAsg = graph::Asg;