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anthem-rs/src/problem.rs

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mod proof_direction;
mod section_kind;
mod statement;
pub use proof_direction::ProofDirection;
pub(crate) use section_kind::SectionKind;
pub(crate) use statement::{ProofStatus, Statement, StatementKind};
#[derive(Copy, Clone, Eq, PartialEq)]
pub enum ProofResult
{
Proven,
NotProven,
Disproven,
}
type VariableDeclarationIDs
= std::collections::BTreeMap::<std::rc::Rc<foliage::VariableDeclaration>, usize>;
type InputConstantDeclarationDomains
= std::collections::BTreeMap<std::rc::Rc<foliage::FunctionDeclaration>, crate::Domain>;
type VariableDeclarationDomains
= std::collections::BTreeMap<std::rc::Rc<foliage::VariableDeclaration>, crate::Domain>;
struct FormatContext<'a, 'b>
{
pub program_variable_declaration_ids: std::cell::RefCell<VariableDeclarationIDs>,
pub integer_variable_declaration_ids: std::cell::RefCell<VariableDeclarationIDs>,
pub input_constant_declaration_domains: &'a InputConstantDeclarationDomains,
pub variable_declaration_domains: &'b VariableDeclarationDomains,
}
pub struct Problem
{
function_declarations: std::cell::RefCell<foliage::FunctionDeclarations>,
pub predicate_declarations: std::cell::RefCell<foliage::PredicateDeclarations>,
statements: std::cell::RefCell<std::collections::BTreeMap<SectionKind, Vec<Statement>>>,
pub input_constant_declarations: std::cell::RefCell<foliage::FunctionDeclarations>,
pub input_constant_declaration_domains: std::cell::RefCell<InputConstantDeclarationDomains>,
pub input_predicate_declarations: std::cell::RefCell<foliage::PredicateDeclarations>,
pub output_predicate_declarations: std::cell::RefCell<foliage::PredicateDeclarations>,
// TODO: clean up as variable declarations are dropped
variable_declaration_domains: std::cell::RefCell<VariableDeclarationDomains>,
shell: std::cell::RefCell<crate::output::Shell>,
}
impl Problem
{
pub fn new() -> Self
{
Self
{
function_declarations: std::cell::RefCell::new(foliage::FunctionDeclarations::new()),
predicate_declarations: std::cell::RefCell::new(foliage::PredicateDeclarations::new()),
statements: std::cell::RefCell::new(std::collections::BTreeMap::new()),
input_constant_declarations:
std::cell::RefCell::new(foliage::FunctionDeclarations::new()),
input_constant_declaration_domains:
std::cell::RefCell::new(InputConstantDeclarationDomains::new()),
input_predicate_declarations:
std::cell::RefCell::new(foliage::PredicateDeclarations::new()),
output_predicate_declarations:
std::cell::RefCell::new(foliage::PredicateDeclarations::new()),
variable_declaration_domains:
std::cell::RefCell::new(VariableDeclarationDomains::new()),
shell: std::cell::RefCell::new(crate::output::Shell::from_stdout()),
}
}
pub(crate) fn add_statement(&self, section_kind: SectionKind, statement: Statement)
{
let mut statements = self.statements.borrow_mut();
let section = statements.entry(section_kind).or_insert(vec![]);
section.push(statement);
}
pub(crate) fn check_that_only_input_and_output_predicates_are_used(&self)
-> Result<(), crate::Error>
{
let predicate_declarations = self.predicate_declarations.borrow();
let input_predicate_declarations = self.input_predicate_declarations.borrow();
let output_predicate_declarations = self.output_predicate_declarations.borrow();
if output_predicate_declarations.is_empty()
{
return Ok(());
}
// Check that only input and output predicates are used in the specification
for predicate_declaration in predicate_declarations.iter()
{
if input_predicate_declarations.contains(predicate_declaration)
|| output_predicate_declarations.contains(predicate_declaration)
// TODO: refactor
// Auxiliary predicates may occur anywhere
|| predicate_declaration.name.starts_with("p__")
&& predicate_declaration.name.ends_with("__")
{
continue;
}
for (_, statements) in self.statements.borrow().iter()
{
for statement in statements
{
match statement.kind
{
crate::problem::StatementKind::CompletedDefinition(_)
| crate::problem::StatementKind::IntegrityConstraint => continue,
_ => (),
}
if crate::formula_contains_predicate(&statement.formula, predicate_declaration)
{
return Err(crate::Error::new_predicate_should_not_occur_in_specification(
std::rc::Rc::clone(predicate_declaration)));
}
}
}
}
Ok(())
}
pub(crate) fn restrict_to_output_predicates(&mut self) -> Result<(), crate::Error>
{
let predicate_declarations = self.predicate_declarations.borrow();
let input_predicate_declarations = self.input_predicate_declarations.borrow();
let output_predicate_declarations = self.output_predicate_declarations.borrow();
// If no output statements were provided, show all predicates by default
if output_predicate_declarations.is_empty()
{
return Ok(());
}
let hidden_predicate_declarations =
predicate_declarations.iter().filter(|x| !output_predicate_declarations.contains(*x)
&& !input_predicate_declarations.contains(*x)
&& !(x.name.starts_with("p__") && x.name.ends_with("__")));
let mut statements = self.statements.borrow_mut();
for hidden_predicate_declaration in hidden_predicate_declarations
{
let matches_completed_definition =
|(_, statement): &(_, &Statement)| match statement.kind
{
StatementKind::CompletedDefinition(ref predicate_declaration) =>
predicate_declaration == hidden_predicate_declaration,
_ => false,
};
let completed_definitions = match statements.get_mut(&SectionKind::CompletedDefinitions)
{
Some(completed_definitions) => completed_definitions,
None => return Ok(()),
};
let completed_definition = match completed_definitions.iter().enumerate()
.find(matches_completed_definition)
{
Some((completed_definition_index, _)) =>
completed_definitions.remove(completed_definition_index).formula,
None => return Err(crate::Error::new_no_completed_definition_found(
std::rc::Rc::clone(hidden_predicate_declaration))),
};
drop(completed_definitions);
for (_, statements) in statements.iter_mut()
{
for statement in statements.iter_mut()
{
crate::utils::replace_predicate_in_formula_with_completed_definition(
&mut statement.formula, &completed_definition, self)?;
}
}
}
Ok(())
}
fn print_step_title(&self, step_title: &str, color: &termcolor::ColorSpec)
{
let longest_possible_key = " Finished";
self.shell.borrow_mut().print(
&format!("{:>step_title_width$} ", step_title,
step_title_width = longest_possible_key.chars().count()),
color);
}
pub fn prove(&self, proof_direction: ProofDirection) -> Result<(), crate::Error>
{
if proof_direction == ProofDirection::Forward
|| proof_direction == ProofDirection::Both
{
self.print_step_title("Started",
termcolor::ColorSpec::new().set_bold(true).set_fg(Some(termcolor::Color::Green)));
self.shell.borrow_mut().println(&"verification of assertions from translated program",
&termcolor::ColorSpec::new());
let mut statements = self.statements.borrow_mut();
// Initially reset all proof statuses
for (_, statements) in statements.iter_mut()
{
for statement in statements.iter_mut()
{
match statement.kind
{
StatementKind::Axiom
| StatementKind::Assumption
| StatementKind::CompletedDefinition(_)
| StatementKind::IntegrityConstraint =>
statement.proof_status = ProofStatus::AssumedProven,
StatementKind::Lemma(ProofDirection::Backward) =>
statement.proof_status = ProofStatus::Ignored,
_ => statement.proof_status = ProofStatus::ToProveLater,
}
}
}
drop(statements);
let proof_result = self.prove_unproven_statements()?;
let mut step_title_color = termcolor::ColorSpec::new();
step_title_color.set_bold(true);
match proof_result
{
ProofResult::Proven => step_title_color.set_fg(Some(termcolor::Color::Green)),
ProofResult::NotProven => step_title_color.set_fg(Some(termcolor::Color::Yellow)),
ProofResult::Disproven => step_title_color.set_fg(Some(termcolor::Color::Red)),
};
self.print_step_title("Finished", &step_title_color);
println!("verification of assertions from translated program");
}
if proof_direction == ProofDirection::Both
{
println!("");
}
if proof_direction == ProofDirection::Backward
|| proof_direction == ProofDirection::Both
{
self.print_step_title("Started",
termcolor::ColorSpec::new().set_bold(true).set_fg(Some(termcolor::Color::Green)));
self.shell.borrow_mut().println(&"verification of translated program from assertions",
&termcolor::ColorSpec::new());
let mut statements = self.statements.borrow_mut();
// Initially reset all proof statuses
for (_, statements) in statements.iter_mut()
{
for statement in statements.iter_mut()
{
match statement.kind
{
StatementKind::Axiom
| StatementKind::Assumption
| StatementKind::Assertion =>
statement.proof_status = ProofStatus::AssumedProven,
StatementKind::Lemma(ProofDirection::Forward) =>
statement.proof_status = ProofStatus::Ignored,
_ => statement.proof_status = ProofStatus::ToProveLater,
}
}
}
drop(statements);
let proof_result = self.prove_unproven_statements()?;
let mut step_title_color = termcolor::ColorSpec::new();
step_title_color.set_bold(true);
match proof_result
{
ProofResult::Proven => step_title_color.set_fg(Some(termcolor::Color::Green)),
ProofResult::NotProven => step_title_color.set_fg(Some(termcolor::Color::Yellow)),
ProofResult::Disproven => step_title_color.set_fg(Some(termcolor::Color::Red)),
};
self.print_step_title("Finished", &step_title_color);
println!("verification of translated program from assertions");
}
Ok(())
}
fn next_unproven_statement_do_mut<F, G>(&self, mut functor: F) -> Option<G>
where
F: FnMut(&mut Statement) -> G,
{
// TODO: properly ensure that statements are proven in the right order
for section in self.statements.borrow_mut().iter_mut()
{
for statement in section.1.iter_mut()
{
if statement.proof_status == ProofStatus::ToProveNow
|| statement.proof_status == ProofStatus::ToProveLater
{
return Some(functor(statement));
}
}
}
None
}
fn prove_unproven_statements(&self) -> Result<ProofResult, crate::Error>
{
let display_statement = |statement: &Statement|
{
let step_title = match statement.proof_status
{
ProofStatus::AssumedProven => format!("Added"),
ProofStatus::Proven => format!("Verified"),
ProofStatus::NotProven
| ProofStatus::Disproven
| ProofStatus::ToProveNow => format!("Verifying"),
ProofStatus::ToProveLater => format!("Skipped"),
ProofStatus::Ignored => format!("Ignored"),
};
let mut step_title_color = termcolor::ColorSpec::new();
step_title_color.set_bold(true);
match statement.proof_status
{
ProofStatus::AssumedProven
| ProofStatus::Proven => step_title_color.set_fg(Some(termcolor::Color::Green)),
ProofStatus::NotProven => step_title_color.set_fg(Some(termcolor::Color::Yellow)),
ProofStatus::Disproven => step_title_color.set_fg(Some(termcolor::Color::Red)),
_ => step_title_color.set_fg(Some(termcolor::Color::Cyan)),
};
self.print_step_title(&step_title, &step_title_color);
self.shell.borrow_mut().print(&format!("{}: ", statement.kind),
&termcolor::ColorSpec::new());
let format_context = FormatContext
{
program_variable_declaration_ids:
std::cell::RefCell::new(VariableDeclarationIDs::new()),
integer_variable_declaration_ids:
std::cell::RefCell::new(VariableDeclarationIDs::new()),
input_constant_declaration_domains: &self.input_constant_declaration_domains.borrow(),
variable_declaration_domains: &self.variable_declaration_domains.borrow(),
};
print!("{}", foliage::format::display_formula(&statement.formula, &format_context));
};
// Show all statements that are assumed to be proven
for (_, statements) in self.statements.borrow_mut().iter_mut()
{
for statement in statements.iter_mut()
.filter(|statement| statement.proof_status == ProofStatus::AssumedProven)
{
display_statement(statement);
println!("");
}
}
loop
{
match self.next_unproven_statement_do_mut(
|statement|
{
statement.proof_status = ProofStatus::ToProveNow;
print!("\x1b[s");
display_statement(statement);
print!("\x1b[u");
use std::io::Write as _;
std::io::stdout().flush();
})
{
Some(_) => (),
// If there are no more unproven statements left, were done
None => break,
}
let mut tptp_problem_to_prove_next_statement = "".to_string();
self.write_tptp_problem_to_prove_next_statement(
&mut tptp_problem_to_prove_next_statement)
.map_err(|error| crate::Error::new_write_tptp_program(error))?;
log::trace!("TPTP program:\n{}", &tptp_problem_to_prove_next_statement);
// TODO: make configurable again
let (proof_result, proof_time_seconds) =
run_vampire(&tptp_problem_to_prove_next_statement,
Some(&["--mode", "casc", "--cores", "8", "--time_limit", "300"]))?;
match self.next_unproven_statement_do_mut(
|statement|
{
statement.proof_status = match proof_result
{
ProofResult::Proven => ProofStatus::Proven,
ProofResult::NotProven => ProofStatus::NotProven,
ProofResult::Disproven => ProofStatus::Disproven,
};
self.shell.borrow_mut().erase_line();
display_statement(statement);
match proof_result
{
ProofResult::Proven => (),
ProofResult::NotProven => print!(" (not proven)"),
ProofResult::Disproven => print!(" (disproven)"),
}
if let Some(proof_time_seconds) = proof_time_seconds
{
self.shell.borrow_mut().print(&format!(" in {} seconds", proof_time_seconds),
termcolor::ColorSpec::new().set_fg(Some(termcolor::Color::Black)).set_intense(true));
}
})
{
Some(_) => (),
None => unreachable!(),
}
self.shell.borrow_mut().println(&"", &termcolor::ColorSpec::new());
if proof_result != ProofResult::Proven
{
return Ok(proof_result);
}
}
Ok(ProofResult::Proven)
}
fn write_tptp_problem_to_prove_next_statement(&self, formatter: &mut String) -> std::fmt::Result
{
use std::fmt::Write as _;
let format_context = FormatContext
{
program_variable_declaration_ids:
std::cell::RefCell::new(VariableDeclarationIDs::new()),
integer_variable_declaration_ids:
std::cell::RefCell::new(VariableDeclarationIDs::new()),
input_constant_declaration_domains: &self.input_constant_declaration_domains.borrow(),
variable_declaration_domains: &self.variable_declaration_domains.borrow(),
};
let write_title = |formatter: &mut String, title, section_separator| -> std::fmt::Result
{
write!(formatter, "{}{}", section_separator, "%".repeat(72))?;
write!(formatter, "\n% {}", title)?;
writeln!(formatter, "\n{}", "%".repeat(72))
};
let mut section_separator = "";
write_title(formatter, "anthem types", section_separator)?;
section_separator = "\n";
let tptp_preamble_anthem_types
= include_str!("output/tptp/preamble_types.tptp").trim_end();
writeln!(formatter, "{}", tptp_preamble_anthem_types)?;
write_title(formatter, "anthem axioms", section_separator)?;
let tptp_preamble_anthem_types
= include_str!("output/tptp/preamble_axioms.tptp").trim_end();
writeln!(formatter, "{}", tptp_preamble_anthem_types)?;
if !self.predicate_declarations.borrow().is_empty()
|| !self.function_declarations.borrow().is_empty()
{
write_title(formatter, "types", section_separator)?;
if !self.predicate_declarations.borrow().is_empty()
{
writeln!(formatter, "% predicate types")?;
}
for predicate_declaration in self.predicate_declarations.borrow().iter()
.filter(|x| !(x.name.starts_with("p__") || x.name.ends_with("__")))
{
writeln!(formatter, "tff(type, type, {}).",
crate::output::tptp::display_predicate_declaration(predicate_declaration))?;
}
if !self.function_declarations.borrow().is_empty()
{
writeln!(formatter, "% function types")?;
}
for function_declaration in self.function_declarations.borrow().iter()
.filter(|x| !(x.name.starts_with("f__") || x.name.ends_with("__")))
{
writeln!(formatter, "tff(type, type, {}).",
crate::output::tptp::display_function_declaration(function_declaration,
&format_context))?;
}
}
let function_declarations = self.function_declarations.borrow();
let symbolic_constants = function_declarations.iter().filter(
|x| !self.input_constant_declaration_domains.borrow().contains_key(*x));
let mut last_symbolic_constant: Option<std::rc::Rc<foliage::FunctionDeclaration>> = None;
// TODO: put in axioms section
for (i, symbolic_constant) in symbolic_constants.enumerate()
{
// Order axioms are only necessary with two or more symbolic constants
if i == 1
{
writeln!(formatter, "% axioms for order of symbolic constants")?;
}
if symbolic_constant.arity > 0
{
// TODO: refactor
unimplemented!("n-ary function declarations arent supported");
}
if let Some(last_symbolic_constant) = last_symbolic_constant
{
writeln!(formatter, "tff(symbolic_constant_order, axiom, p__less__({}, {})).",
last_symbolic_constant.name, symbolic_constant.name)?;
}
last_symbolic_constant = Some(std::rc::Rc::clone(symbolic_constant));
}
for (section_kind, statements) in self.statements.borrow().iter()
{
if statements.is_empty()
{
continue;
}
let title = match section_kind
{
SectionKind::CompletedDefinitions => "completed definitions",
SectionKind::IntegrityConstraints => "integrity constraints",
SectionKind::Axioms => "axioms",
SectionKind::Assumptions => "assumptions",
SectionKind::Lemmas => "lemmas",
SectionKind::Assertions => "assertions",
};
write_title(formatter, title, section_separator)?;
section_separator = "\n";
let mut i = 0;
for statement in statements.iter()
{
if let StatementKind::CompletedDefinition(_) = statement.kind
{
writeln!(formatter, "% {}", statement.kind)?;
}
let name = match &statement.name
{
// TODO: refactor
Some(name) => name.clone(),
None =>
{
i += 1;
format!("statement_{}", i)
},
};
let statement_type = match statement.proof_status
{
ProofStatus::AssumedProven
| ProofStatus::Proven => "axiom",
ProofStatus::NotProven
| ProofStatus::Disproven => unreachable!(),
ProofStatus::ToProveNow => "conjecture",
// Skip statements that will be proven later
ProofStatus::ToProveLater => continue,
// Skip statements that are not part of this proof
ProofStatus::Ignored => continue,
};
// TODO: add proper statement type
writeln!(formatter, "tff({}, {}, {}).", name, statement_type,
crate::output::tptp::display_formula(&statement.formula, &format_context))?;
}
}
Ok(())
}
}
impl foliage::FindOrCreateFunctionDeclaration for Problem
{
fn find_or_create_function_declaration(&self, name: &str, arity: usize)
-> std::rc::Rc<foliage::FunctionDeclaration>
{
let mut function_declarations = self.function_declarations.borrow_mut();
match function_declarations.iter().find(|x| x.name == name && x.arity == arity)
{
Some(declaration) => std::rc::Rc::clone(&declaration),
None =>
{
let declaration = foliage::FunctionDeclaration
{
name: name.to_string(),
arity,
};
let declaration = std::rc::Rc::new(declaration);
function_declarations.insert(std::rc::Rc::clone(&declaration));
log::debug!("new function declaration: {}/{}", name, arity);
declaration
},
}
}
}
impl foliage::FindOrCreatePredicateDeclaration for Problem
{
fn find_or_create_predicate_declaration(&self, name: &str, arity: usize)
-> std::rc::Rc<foliage::PredicateDeclaration>
{
let mut predicate_declarations = self.predicate_declarations.borrow_mut();
match predicate_declarations.iter().find(|x| x.name == name && x.arity == arity)
{
Some(declaration) => std::rc::Rc::clone(&declaration),
None =>
{
let declaration = foliage::PredicateDeclaration
{
name: name.to_string(),
arity,
};
let declaration = std::rc::Rc::new(declaration);
predicate_declarations.insert(std::rc::Rc::clone(&declaration));
log::debug!("new predicate declaration: {}/{}", name, arity);
declaration
},
}
}
}
impl crate::traits::AssignVariableDeclarationDomain for Problem
{
fn assign_variable_declaration_domain(&self,
variable_declaration: &std::rc::Rc<foliage::VariableDeclaration>, domain: crate::Domain)
{
let mut variable_declaration_domains = self.variable_declaration_domains.borrow_mut();
match variable_declaration_domains.get(variable_declaration)
{
Some(current_domain) => assert_eq!(*current_domain, domain,
"inconsistent variable declaration domain"),
None =>
{
variable_declaration_domains
.insert(std::rc::Rc::clone(variable_declaration).into(), domain);
},
}
}
}
impl crate::traits::VariableDeclarationDomain for Problem
{
fn variable_declaration_domain(&self,
variable_declaration: &std::rc::Rc<foliage::VariableDeclaration>)
-> Option<crate::Domain>
{
self.variable_declaration_domains.borrow().iter().find_map(
|(x, domain)|
match x == variable_declaration
{
true => Some(*domain),
false => None,
})
}
}
impl<'a, 'b> FormatContext<'a, 'b>
{
fn variable_declaration_id(&self,
variable_declaration: &std::rc::Rc<foliage::VariableDeclaration>)
-> usize
{
let mut variable_declaration_ids = match self.variable_declaration_domains
.get(variable_declaration)
{
Some(crate::Domain::Program) => self.program_variable_declaration_ids.borrow_mut(),
Some(crate::Domain::Integer) => self.integer_variable_declaration_ids.borrow_mut(),
None => unreachable!("all variables should be declared at this point"),
};
match variable_declaration_ids.get(variable_declaration)
{
Some(id) => *id,
None =>
{
let id = variable_declaration_ids.len();
variable_declaration_ids.insert(std::rc::Rc::clone(variable_declaration).into(), id);
id
},
}
}
}
impl<'a, 'b> crate::traits::InputConstantDeclarationDomain for FormatContext<'a, 'b>
{
fn input_constant_declaration_domain(&self,
declaration: &std::rc::Rc<foliage::FunctionDeclaration>) -> crate::Domain
{
// Assume the program domain if not specified otherwise
self.input_constant_declaration_domains.get(declaration).map(|x| *x)
.unwrap_or(crate::Domain::Program)
}
}
impl<'a, 'b> crate::traits::VariableDeclarationDomain for FormatContext<'a, 'b>
{
fn variable_declaration_domain(&self,
variable_declaration: &std::rc::Rc<foliage::VariableDeclaration>)
-> Option<crate::Domain>
{
self.variable_declaration_domains.get(variable_declaration)
.map(|x| *x)
}
}
impl<'a, 'b> crate::traits::VariableDeclarationID for FormatContext<'a, 'b>
{
fn variable_declaration_id(&self,
variable_declaration: &std::rc::Rc<foliage::VariableDeclaration>)
-> usize
{
use crate::traits::VariableDeclarationDomain;
let mut variable_declaration_ids = match self.variable_declaration_domain(
variable_declaration)
{
Some(crate::Domain::Program) => self.program_variable_declaration_ids.borrow_mut(),
Some(crate::Domain::Integer) => self.integer_variable_declaration_ids.borrow_mut(),
None => panic!("all variables should be declared at this point"),
};
match variable_declaration_ids.get(variable_declaration)
{
Some(id) =>
{
*id
}
None =>
{
let id = variable_declaration_ids.len();
variable_declaration_ids.insert(std::rc::Rc::clone(variable_declaration).into(), id);
id
},
}
}
}
impl<'a, 'b> foliage::format::Format for FormatContext<'a, 'b>
{
fn display_variable_declaration(&self, formatter: &mut std::fmt::Formatter,
variable_declaration: &std::rc::Rc<foliage::VariableDeclaration>)
-> std::fmt::Result
{
let id = self.variable_declaration_id(variable_declaration);
let domain = self.variable_declaration_domains.get(variable_declaration)
.expect("unspecified variable domain");
let prefix = match domain
{
crate::Domain::Integer => "N",
crate::Domain::Program => "X",
};
write!(formatter, "{}{}", prefix, id + 1)
}
}
fn run_vampire<I, S>(input: &str, arguments: Option<I>)
-> Result<(ProofResult, Option<f32>), crate::Error>
where
I: IntoIterator<Item = S>, S: AsRef<std::ffi::OsStr>,
{
let mut vampire = std::process::Command::new("vampire");
let vampire = match arguments
{
Some(arguments) => vampire.args(arguments),
None => &mut vampire,
};
let mut vampire = vampire
.stdin(std::process::Stdio::piped())
.stdout(std::process::Stdio::piped())
.stderr(std::process::Stdio::piped())
.spawn()
.map_err(|error| crate::Error::new_run_vampire(error))?;
{
use std::io::Write as _;
let vampire_stdin = vampire.stdin.as_mut().unwrap();
vampire_stdin.write_all(input.as_bytes())
.map_err(|error| crate::Error::new_run_vampire(error))?;
}
let output = vampire.wait_with_output()
.map_err(|error| crate::Error::new_run_vampire(error))?;
let stdout = std::str::from_utf8(&output.stdout)
.map_err(|error| crate::Error::new_run_vampire(error))?;
let stderr = std::str::from_utf8(&output.stderr)
.map_err(|error| crate::Error::new_run_vampire(error))?;
if !output.status.success()
{
let proof_not_found_regex = regex::Regex::new(r"% \(\d+\)Proof not found in time").unwrap();
if proof_not_found_regex.is_match(stdout)
{
return Ok((ProofResult::NotProven, None));
}
return Err(crate::Error::new_prove_program(output.status.code(), stdout.to_string(),
stderr.to_string()));
}
let proof_time_regex = regex::Regex::new(r"% \(\d+\)Success in time (\d+(?:\.\d+)?) s").unwrap();
let proof_time = proof_time_regex.captures(stdout)
.map(|captures| captures.get(1).unwrap().as_str().parse::<f32>().ok())
.unwrap_or(None);
let refutation_regex = regex::Regex::new(r"% \(\d+\)Termination reason: Refutation").unwrap();
if refutation_regex.is_match(stdout)
{
return Ok((ProofResult::Proven, proof_time));
}
// TODO: support disproven result
Err(crate::Error::new_parse_vampire_output(stdout.to_string(), stderr.to_string()))
}
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