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# 布局
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arithmetic 子电路的设计包含如下几列。我们重点关注 operand*与 u16*列,
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```rust
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pub struct ArithmeticCircuitConfig<F> {
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// TODO use table to let core lookup
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q_enable: Selector,
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// arithmetic table for lookup starts
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tag: BinaryNumberConfig<Tag, 3>, //todo not use 3
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cnt: Column<Advice>,
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operand0_hi: Column<Advice>,
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operand0_lo: Column<Advice>,
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operand1_hi: Column<Advice>,
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operand1_lo: Column<Advice>,
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operand2_hi: Column<Advice>,
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operand2_lo: Column<Advice>,
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operand3_hi: Column<Advice>,
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operand3_lo: Column<Advice>,
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// arithmetic table for lookup ends
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u16_0: Column<Advice>,
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u16_1: Column<Advice>,
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u16_2: Column<Advice>,
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u16_3: Column<Advice>,
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u16_4: Column<Advice>,
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u16_5: Column<Advice>,
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u16_6: Column<Advice>,
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u16_7: Column<Advice>,
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cnt_is_zero: IsZeroWithRotationConfig<F>,
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}
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pub enum Tag {
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#[default]
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Nil,
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Add,
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Addmod,
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Mul,
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Mulmod,
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Lt,
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Gt,
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Slt,
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Sgt,
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Sub,
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DivMod,
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}
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```
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在这里 tag 我们使用了一个电路小工具“BinaryNumberConfig/BinaryNumberChip”。关于 BinaryNumberChip,详见[here](../code-notes/binary_number_with_real_selector.rs的内容和用法.markdown)。
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## 列的含义
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operand* 用来存放算术中的参数值,如 a+b=c+overflow 指令中的 a,b,c,overflow。u16*用来 lookup 算术中的输出如 c_hi,c_lo 属于 u128 范围。这里我们只需要保证输出值的 lookup 就好。cnt 记录某个具体算术指令的行计数器,从正数开始递减到 0。
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# 约束
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在 arithmetic 子电路中约束可以分为两类。
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通用约束
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- 约束 cnt 除零行外,当前行与下一行差值为 1
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不同 Tag 对应的约束不同
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- Add(在表中使用两行)
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- 如果是 0 行,则 cnt_prev=1,cnt_prev_prev=0
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- c_lo = u16 sum(rotation cur)
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- c_hi = u16 sum(rotation prev)
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- carry hi is bool
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- carry lo is bool
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- c lo + carry lo \* 2^128 = a lo + b lo
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- c hi + carry hi \* 2^128 = a hi + b hi + carry lo
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- Sub_Lt_Gt (a+b=c+overflow\*2^256) (可以使用 select struct)
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- 如果是 0 行,则 cnt_prev=1,cnt_prev_prev=0
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- carry hi is bool
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- carry lo is bool
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- c lo + carry lo \* 2^128 = a lo + b lo
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- c hi + carry hi \* 2^128 = a hi + b hi + carry lo
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- if tag is sub 有 c_lo = u16 sum(rotation cur),c_hi = u16 sum(rotation prev) and carry_hi iszero
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- if tag is lt 则有 carry_hi iszero
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- if tag is gt 则有 carry_hi 1
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- Div_Mod
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- Mul
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- Slt_Sgt
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- Sdiv_Smod
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- Addmod
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- Mulmod
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# 实现 arithmetic 子电路中 Add 例子
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如果我们希望为某一个 tag 实现它的约束,我们需要实现 OperationGadget,然后在 config 方法中实现 tag 对应的约束就好。
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```rust
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pub(crate) trait OperationGadget<F: Field> {
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const NAME: &'static str;
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const TAG: Tag;
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const NUM_ROW: usize;
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fn constraints(
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config: &OperationConfig<F>,
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meta: &mut VirtualCells<F>,
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) -> Vec<(&'static str, Expression<F>)>;
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}
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impl<F: Field> OperationGadget<F> for AddGadget<F> {
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const NAME: &'static str = "Arithmetic Circuit Add";
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const TAG: Tag = Tag::Add;
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const NUM_ROW: usize = 2;
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fn constraints(
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config: &OperationConfig<F>,
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meta: &mut VirtualCells<F>,
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) -> Vec<(&'static str, Expression<F>)> {
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let mut constraints = vec![];
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let a_hi = meta.query_advice(config.operand0_hi, Rotation::cur());
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...
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let carry_lo = meta.query_advice(config.operand3_lo, Rotation::cur());
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let u16_0_for_c_lo = meta.query_advice(config.u16_0, Rotation::cur());
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...
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let u16_7_for_c_lo = meta.query_advice(config.u16_7, Rotation::cur());
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let u16_sum_for_c_lo = expr_from_u16s(&[
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u16_0_for_c_lo,
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...
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u16_7_for_c_lo,
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]);
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let u16_0_for_c_hi = meta.query_advice(config.u16_0, Rotation::prev());
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...
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let u16_7_for_c_hi = meta.query_advice(config.u16_7, Rotation::prev());
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let u16_sum_for_c_hi = expr_from_u16s(&[
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u16_0_for_c_hi,
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...
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u16_7_for_c_hi,
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]);
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constraints.push(("c lo = u16 sum", c_lo.clone() - u16_sum_for_c_lo));
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constraints.push(("c hi = u16 sum", c_hi.clone() - u16_sum_for_c_hi));
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constraints.push((
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"carry hi is bool",
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carry_hi.clone() * (1.expr() - carry_hi.clone()),
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));
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constraints.push((
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"carry lo is bool",
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carry_lo.clone() * (1.expr() - carry_lo.clone()),
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));
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constraints.push((
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"c lo + carry lo * 2^128 = a lo + b lo",
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c_lo + carry_lo.clone() * pow_of_two::<F>(128) - a_lo - b_lo,
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));
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constraints.push((
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"c hi + carry hi * 2^128 = a hi + b hi + carry lo",
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c_hi + carry_hi * pow_of_two::<F>(128) - a_hi - b_hi - carry_lo,
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));
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constraints
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}
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}
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``` |
