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// Copyright (C) 2019-2022 Aleo Systems Inc.
// This file is part of the snarkVM library.
// The snarkVM library 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.
// The snarkVM library 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 the snarkVM library. If not, see <https://www.gnu.org/licenses/>.
use super::*;
impl<N: Network, A: circuit::Aleo<Network = N>> Registers<N, A> {
/// Assigns the given literal to the given register, assuming the register is not already assigned.
///
/// # Errors
/// This method will halt if the given register is a register member.
/// This method will halt if the given register is an input register.
/// This method will halt if the register is already used.
#[inline]
pub fn store_literal(&mut self, stack: &Stack<N>, register: &Register<N>, literal: Literal<N>) -> Result<()> {
self.store(stack, register, Value::Plaintext(Plaintext::from(literal)))
}
/// Assigns the given value to the given register, assuming the register is not already assigned.
///
/// # Errors
/// This method will halt if the given register is a register member.
/// This method will halt if the given register is an input register.
/// This method will halt if the register is already used.
#[inline]
pub fn store(&mut self, stack: &Stack<N>, register: &Register<N>, stack_value: Value<N>) -> Result<()> {
match register {
Register::Locator(locator) => {
// Ensure the register assignments are monotonically increasing.
let expected_locator = self.console_registers.len() as u64;
ensure!(expected_locator == *locator, "Out-of-order write operation at '{register}'");
// Ensure the register does not already exist.
ensure!(
!self.console_registers.contains_key(locator),
"Cannot write to occupied register '{register}'"
);
// Ensure the register type is valid.
match self.register_types.get_type(stack, register) {
// Ensure the stack value matches the register type.
Ok(register_type) => stack.matches_register_type(&stack_value, ®ister_type)?,
// Ensure the register is defined.
Err(error) => bail!("Register '{register}' is missing a type definition: {error}"),
};
// Store the stack value.
match self.console_registers.insert(*locator, stack_value) {
// Ensure the register has not been previously stored.
Some(..) => bail!("Attempted to write to register '{register}' again"),
// Return on success.
None => Ok(()),
}
}
// Ensure the register is not a register member.
Register::Member(..) => bail!("Cannot store to a register member: '{register}'"),
}
}
}
impl<N: Network, A: circuit::Aleo<Network = N>> Registers<N, A> {
/// Assigns the given literal to the given register, assuming the register is not already assigned.
///
/// # Errors
/// This method will halt if the given register is a register member.
/// This method will halt if the given register is an input register.
/// This method will halt if the register is already used.
#[inline]
pub fn store_literal_circuit(
&mut self,
stack: &Stack<N>,
register: &Register<N>,
literal: circuit::Literal<A>,
) -> Result<()> {
self.store_circuit(stack, register, circuit::Value::Plaintext(circuit::Plaintext::from(literal)))
}
/// Assigns the given value to the given register, assuming the register is not already assigned.
///
/// # Errors
/// This method will halt if the given register is a register member.
/// This method will halt if the given register is an input register.
/// This method will halt if the register is already used.
#[inline]
pub fn store_circuit(
&mut self,
stack: &Stack<N>,
register: &Register<N>,
circuit_value: circuit::Value<A>,
) -> Result<()> {
match register {
Register::Locator(locator) => {
// Ensure the register assignments are monotonically increasing.
let expected_locator = self.circuit_registers.len() as u64;
ensure!(expected_locator == *locator, "Out-of-order write operation at '{register}'");
// Ensure the register does not already exist.
ensure!(
!self.circuit_registers.contains_key(locator),
"Cannot write to occupied register '{register}'"
);
// Ensure the register type is valid.
match self.register_types.get_type(stack, register) {
// Ensure the stack value matches the register type.
Ok(register_type) => {
stack.matches_register_type(&circuit::Eject::eject_value(&circuit_value), ®ister_type)?
}
// Ensure the register is defined.
Err(error) => bail!("Register '{register}' is missing a type definition: {error}"),
};
// Store the stack value.
match self.circuit_registers.insert(*locator, circuit_value) {
// Ensure the register has not been previously stored.
Some(..) => bail!("Attempted to write to register '{register}' again"),
// Return on success.
None => Ok(()),
}
}
// Ensure the register is not a register member.
Register::Member(..) => bail!("Cannot store to a register member: '{register}'"),
}
}
}