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use crate::allocator::{Allocator, NodePtr, SExp};
use crate::cost::Cost;
use crate::reduction::{EvalErr, Reduction, Response};

// lowered from measured 147 per bit. It doesn't seem to take this long in
// practice
const TRAVERSE_BASE_COST: Cost = 40;
const TRAVERSE_COST_PER_ZERO_BYTE: Cost = 4;
const TRAVERSE_COST_PER_BIT: Cost = 4;

// `run_program` has two stacks: the operand stack (of `Node` objects) and the
// operator stack (of Operation)

// return a bitmask with a single bit set, for the most significant set bit in
// the input byte
fn msb_mask(byte: u8) -> u8 {
    let mut byte = (byte | (byte >> 1)) as u32;
    byte |= byte >> 2;
    byte |= byte >> 4;
    debug_assert!((byte + 1) >> 1 <= 0x80);
    ((byte + 1) >> 1) as u8
}

// return the index of the first non-zero byte in buf. If all bytes are 0, the
// length (one past end) will be returned.
const fn first_non_zero(buf: &[u8]) -> usize {
    let mut c: usize = 0;
    while c < buf.len() && buf[c] == 0 {
        c += 1;
    }
    c
}

pub fn traverse_path(allocator: &Allocator, node_index: &[u8], args: NodePtr) -> Response {
    let mut arg_list: NodePtr = args;

    // find first non-zero byte
    let first_bit_byte_index = first_non_zero(node_index);

    let mut cost: Cost = TRAVERSE_BASE_COST
        + (first_bit_byte_index as Cost) * TRAVERSE_COST_PER_ZERO_BYTE
        + TRAVERSE_COST_PER_BIT;

    if first_bit_byte_index >= node_index.len() {
        return Ok(Reduction(cost, allocator.null()));
    }

    // find first non-zero bit (the most significant bit is a sentinel)
    let last_bitmask = msb_mask(node_index[first_bit_byte_index]);

    // follow through the bits, moving left and right
    let mut byte_idx = node_index.len() - 1;
    let mut bitmask = 0x01;
    while byte_idx > first_bit_byte_index || bitmask < last_bitmask {
        let is_bit_set: bool = (node_index[byte_idx] & bitmask) != 0;
        match allocator.sexp(arg_list) {
            SExp::Atom(_) => {
                return Err(EvalErr(arg_list, "path into atom".into()));
            }
            SExp::Pair(left, right) => {
                arg_list = if is_bit_set { right } else { left };
            }
        }
        if bitmask == 0x80 {
            bitmask = 0x01;
            byte_idx -= 1;
        } else {
            bitmask <<= 1;
        }
        cost += TRAVERSE_COST_PER_BIT;
    }
    Ok(Reduction(cost, arg_list))
}

#[test]
fn test_msb_mask() {
    assert_eq!(msb_mask(0x0), 0x0);
    assert_eq!(msb_mask(0x01), 0x01);
    assert_eq!(msb_mask(0x02), 0x02);
    assert_eq!(msb_mask(0x04), 0x04);
    assert_eq!(msb_mask(0x08), 0x08);
    assert_eq!(msb_mask(0x10), 0x10);
    assert_eq!(msb_mask(0x20), 0x20);
    assert_eq!(msb_mask(0x40), 0x40);
    assert_eq!(msb_mask(0x80), 0x80);

    assert_eq!(msb_mask(0x44), 0x40);
    assert_eq!(msb_mask(0x2a), 0x20);
    assert_eq!(msb_mask(0xff), 0x80);
    assert_eq!(msb_mask(0x0f), 0x08);
}

#[test]
fn test_first_non_zero() {
    assert_eq!(first_non_zero(&[]), 0);
    assert_eq!(first_non_zero(&[1]), 0);
    assert_eq!(first_non_zero(&[0]), 1);
    assert_eq!(first_non_zero(&[0, 0, 0, 1, 1, 1]), 3);
    assert_eq!(first_non_zero(&[0, 0, 0, 0, 0, 0]), 6);
    assert_eq!(first_non_zero(&[1, 0, 0, 0, 0, 0]), 0);
}

#[test]
fn test_traverse_path() {
    use crate::allocator::Allocator;

    let mut a = Allocator::new();
    let nul = a.null();
    let n1 = a.new_atom(&[0, 1, 2]).unwrap();
    let n2 = a.new_atom(&[4, 5, 6]).unwrap();

    assert_eq!(traverse_path(&a, &[0], n1).unwrap(), Reduction(48, nul));
    assert_eq!(traverse_path(&a, &[0b1], n1).unwrap(), Reduction(44, n1));
    assert_eq!(traverse_path(&a, &[0b1], n2).unwrap(), Reduction(44, n2));

    // cost for leading zeros
    assert_eq!(
        traverse_path(&a, &[0, 0, 0, 0], n1).unwrap(),
        Reduction(60, nul)
    );

    let n3 = a.new_pair(n1, n2).unwrap();
    assert_eq!(traverse_path(&a, &[0b1], n3).unwrap(), Reduction(44, n3));
    assert_eq!(traverse_path(&a, &[0b10], n3).unwrap(), Reduction(48, n1));
    assert_eq!(traverse_path(&a, &[0b11], n3).unwrap(), Reduction(48, n2));
    assert_eq!(traverse_path(&a, &[0b11], n3).unwrap(), Reduction(48, n2));

    let list = a.new_pair(n1, nul).unwrap();
    let list = a.new_pair(n2, list).unwrap();

    assert_eq!(traverse_path(&a, &[0b10], list).unwrap(), Reduction(48, n2));
    assert_eq!(
        traverse_path(&a, &[0b101], list).unwrap(),
        Reduction(52, n1)
    );
    assert_eq!(
        traverse_path(&a, &[0b111], list).unwrap(),
        Reduction(52, nul)
    );

    // errors
    assert_eq!(
        traverse_path(&a, &[0b1011], list).unwrap_err(),
        EvalErr(nul, "path into atom".to_string())
    );
    assert_eq!(
        traverse_path(&a, &[0b1101], list).unwrap_err(),
        EvalErr(n1, "path into atom".to_string())
    );
    assert_eq!(
        traverse_path(&a, &[0b1001], list).unwrap_err(),
        EvalErr(n1, "path into atom".to_string())
    );
    assert_eq!(
        traverse_path(&a, &[0b1010], list).unwrap_err(),
        EvalErr(n2, "path into atom".to_string())
    );
    assert_eq!(
        traverse_path(&a, &[0b1110], list).unwrap_err(),
        EvalErr(n2, "path into atom".to_string())
    );
}