doc/modular_congruence_multiplication_proof.tex - third_party/github/google/emboss - Git at Google

 %This proof is used in Emboss to propagate alignment restrictions through
 %multiplication: if a and b are non-constant integers, their product can still
 %have a known alignment.
 %
 %Forgive me on the details and formatting, math majors, I never completed my
 %math degree.  --bolms
 %
 %Thanks to Aaron Webster for helping me format this as an actual proof.
 \documentclass{article}
 \usepackage[utf8]{inputenc}
 \usepackage[english]{babel}
 \usepackage{amssymb,amsmath,amsthm}
 \title{Modular Congruence of the Product of Two Values with Known Modular Congruences}
 \author{Emboss Authors}
 \date{2017}

 \begin{document}
 \maketitle

 \newtheorem{theorem}{Theorem}

 %(Draft)
 %TODO(webstera): Try to simplify this proof.

 \begin{theorem}
 Given

 \begin{align*}
   &{a} \equiv {r} \pmod{{m}} \\
   &{b} \equiv {s} \pmod{{n}} \\
   &{a}, {r}, {m}, {b}, {s}, {n} \in \mathbb{Z}
 \end{align*}

 then

 \begin{align*}
   &{a}{b} \equiv {r}{s} \pmod{G\left(\dfrac{{m}}{G\left({m}, {r}\right)},
 \dfrac{{n}}{G\left({n}, {s}\right)}\right) \cdot G\left({m}, {r}\right) \cdot
 G\left({n}, {s}\right)}
 \end{align*}

 where $G$ is the greatest common divisor function.
 \end{theorem}

 \begin{proof}
 \begin{align}
   \text{Let }{q} &= G\left({m}, {r}\right) \label{eq:qdef} \\
              {p} &= G\left({n}, {s}\right) \label{eq:pdef} \\
              {z} &= G\left(\dfrac{{m}}{{q}}, \dfrac{{n}}{{p}}\right) =
                     G\left(\dfrac{{m}}{G\left({m}, {r}\right)},
                     \dfrac{{n}}{G\left({n}, {s}\right)}\right) \label{eq:zdef}
 \end{align}

 by the definition of modular congruence:
 \begin{align}
   &\exists {x} \in \mathbb{Z} : {a} = {m}{x} + {r} \\
   &\exists {y} \in \mathbb{Z} : {b} = {n}{y} + {s}
 \end{align}

 multiplying $\dfrac{{q}}{{q}}$ and distributing $\dfrac{1}{{q}}$:
 \begin{align}
   &{a} = {q}\left(\dfrac{{m}{x}}{q} + \dfrac{{r}}{q}\right)
 \end{align}

 by the definition of ${q}$ in \eqref{eq:qdef}:
 \begin{align}
   &\dfrac{{m}{x}}{q}, \dfrac{{r}}{q} \in \mathbb{Z} \label{eq:rqinz}
 \end{align}

 multiplying $\dfrac{{p}}{{p}}$ and distributing $\dfrac{1}{{p}}$:
 \begin{align}
   &{b} = {p}\left(\dfrac{{n}{y}}{{p}} + \dfrac{{s}}{{p}}\right)
 \end{align}

 by the definition of ${p}$ in \eqref{eq:pdef}:
 \begin{align}
   &\dfrac{{n}{y}}{{p}}, \dfrac{{s}}{{p}} \in \mathbb{Z} \label{eq:spinz}
 \end{align}

 multiplying $\dfrac{{z}}{{z}}$:
 \begin{align}
   &{a} = {q}\left({z} \cdot \dfrac{{m}{x}}{{q}{z}} + \dfrac{{r}}{{q}}\right) \label{eq:aeqq}
 \end{align}

 by the definition of ${z}$ in \eqref{eq:zdef}:
 \begin{align}
   &\dfrac{{m}{x}}{{q}{z}} \in \mathbb{Z} \label{eq:mxqzinz}
 \end{align}

 multiplying $\dfrac{{z}}{{z}}$:
 \begin{align}
   &{b} = {p}\left({z} \cdot \dfrac{{n}{y}}{{p}{z}} + \dfrac{{s}}{{p}}\right) \label{eq:beqp}
 \end{align}

 by the definition of ${z}$ in \eqref{eq:zdef}:
 \begin{align}
   &\dfrac{{n}{y}}{{p}{z}} \in \mathbb{Z} \label{eq:nypzinz}
 \end{align}

 \eqref{eq:aeqq} and \eqref{eq:beqp}:
 \begin{align}
   &{a}{b} = {q}{p}\left({z} \cdot \dfrac{{m}{x}}{{q}{z}} +
     \dfrac{{r}}{{q}}\right)\left({z} \cdot \dfrac{{n}{y}}{{p}{z}} +
     \dfrac{{s}}{{p}}\right) \label{eq:abeqqp}
 \end{align}

 partially distributing \eqref{eq:abeqqp}:
 \begin{align}
   &{a}{b} = {q}{p}\left({z}^2 \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
     \dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{r}}{{q}} \cdot
     \dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
     \dfrac{{s}}{{p}} + \dfrac{{r}}{{q}} \cdot \dfrac{{s}}{{p}}\right) \label{eq:abeqqpexp}
 \end{align}

 extracting the $\dfrac{{r}{s}}{{q}{p}}$ term from \eqref{eq:abeqqpexp} and cancelling $\dfrac{{q}{p}}{{q}{p}}$:
 \begin{align}
   &{a}{b} = {q}{p}\left({z}^2 \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
     \dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{r}}{{q}} \cdot
     \dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
     \dfrac{{s}}{{p}}\right) + {r}{s} \label{eq:abeqqpextr}
 \end{align}

 factoring ${z}$ from \eqref{eq:abeqqpextr}:
 \begin{align}
   &{a}{b} = {q}{p}{z}\left({z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
     \dfrac{{n}{y}}{{p}{z}} + \dfrac{{r}}{{q}} \cdot \dfrac{{n}{y}}{{p}{z}} +
     \dfrac{{m}{x}}{{q}{z}} \cdot \dfrac{{s}}{{p}}\right) + {r}{s}
 \end{align}

 because ${z}, \dfrac{{r}}{q}, \dfrac{{s}}{{p}}, \dfrac{{m}{x}}{{q}{z}},
   \dfrac{{n}{y}}{{p}{z}} \in \mathbb{Z}$, per \eqref{eq:zdef}, \eqref{eq:rqinz}, \eqref{eq:spinz}, \eqref{eq:mxqzinz}, \eqref{eq:nypzinz}:
 \begin{align}
   &{z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot \dfrac{{n}{y}}{{p}{z}} +
     \dfrac{{r}}{{q}} \cdot \dfrac{{n}{y}}{{p}{z}} + \dfrac{{m}{x}}{{q}{z}} \cdot
     \dfrac{{s}}{{p}} \in \mathbb{Z}
 \end{align}

 by the definition of modulus:
 \begin{align}
   &{a}{b} \equiv {r}{s} \pmod{{q}{p}{z}}
 \end{align}

 by the definitions of ${q}$, ${p}$, and ${z}$ in \eqref{eq:qdef}, \eqref{eq:pdef}, and \eqref{eq:zdef}:
 \begin{align}
   &{a}{b} \equiv {r}{s} \pmod{G\left(\dfrac{{m}}{G\left({m}, {r}\right)},
     \dfrac{{n}}{G\left({n}, {s}\right)}\right) \cdot G\left({m}, {r}\right)
     \cdot G\left({n}, {s}\right)}
 \end{align}

 \end{proof}
 \end{document}
	%This proof is used in Emboss to propagate alignment restrictions through
	%multiplication: if a and b are non-constant integers, their product can still
	%have a known alignment.
	%
	%Forgive me on the details and formatting, math majors, I never completed my
	%math degree. --bolms
	%
	%Thanks to Aaron Webster for helping me format this as an actual proof.
	\documentclass{article}
	\usepackage[utf8]{inputenc}
	\usepackage[english]{babel}
	\usepackage{amssymb,amsmath,amsthm}
	\title{Modular Congruence of the Product of Two Values with Known Modular Congruences}
	\author{Emboss Authors}
	\date{2017}

	\begin{document}
	\maketitle

	\newtheorem{theorem}{Theorem}

	%(Draft)
	%TODO(webstera): Try to simplify this proof.

	\begin{theorem}
	Given

	\begin{align*}
	&{a} \equiv {r} \pmod{{m}} \\
	&{b} \equiv {s} \pmod{{n}} \\
	&{a}, {r}, {m}, {b}, {s}, {n} \in \mathbb{Z}
	\end{align*}

	then

	\begin{align*}
	&{a}{b} \equiv {r}{s} \pmod{G\left(\dfrac{{m}}{G\left({m}, {r}\right)},
	\dfrac{{n}}{G\left({n}, {s}\right)}\right) \cdot G\left({m}, {r}\right) \cdot
	G\left({n}, {s}\right)}
	\end{align*}

	where $G$ is the greatest common divisor function.
	\end{theorem}

	\begin{proof}
	\begin{align}
	\text{Let }{q} &= G\left({m}, {r}\right) \label{eq:qdef} \\
	{p} &= G\left({n}, {s}\right) \label{eq:pdef} \\
	{z} &= G\left(\dfrac{{m}}{{q}}, \dfrac{{n}}{{p}}\right) =
	G\left(\dfrac{{m}}{G\left({m}, {r}\right)},
	\dfrac{{n}}{G\left({n}, {s}\right)}\right) \label{eq:zdef}
	\end{align}

	by the definition of modular congruence:
	\begin{align}
	&\exists {x} \in \mathbb{Z} : {a} = {m}{x} + {r} \\
	&\exists {y} \in \mathbb{Z} : {b} = {n}{y} + {s}
	\end{align}

	multiplying $\dfrac{{q}}{{q}}$ and distributing $\dfrac{1}{{q}}$:
	\begin{align}
	&{a} = {q}\left(\dfrac{{m}{x}}{q} + \dfrac{{r}}{q}\right)
	\end{align}

	by the definition of ${q}$ in \eqref{eq:qdef}:
	\begin{align}
	&\dfrac{{m}{x}}{q}, \dfrac{{r}}{q} \in \mathbb{Z} \label{eq:rqinz}
	\end{align}

	multiplying $\dfrac{{p}}{{p}}$ and distributing $\dfrac{1}{{p}}$:
	\begin{align}
	&{b} = {p}\left(\dfrac{{n}{y}}{{p}} + \dfrac{{s}}{{p}}\right)
	\end{align}

	by the definition of ${p}$ in \eqref{eq:pdef}:
	\begin{align}
	&\dfrac{{n}{y}}{{p}}, \dfrac{{s}}{{p}} \in \mathbb{Z} \label{eq:spinz}
	\end{align}

	multiplying $\dfrac{{z}}{{z}}$:
	\begin{align}
	&{a} = {q}\left({z} \cdot \dfrac{{m}{x}}{{q}{z}} + \dfrac{{r}}{{q}}\right) \label{eq:aeqq}
	\end{align}

	by the definition of ${z}$ in \eqref{eq:zdef}:
	\begin{align}
	&\dfrac{{m}{x}}{{q}{z}} \in \mathbb{Z} \label{eq:mxqzinz}
	\end{align}

	multiplying $\dfrac{{z}}{{z}}$:
	\begin{align}
	&{b} = {p}\left({z} \cdot \dfrac{{n}{y}}{{p}{z}} + \dfrac{{s}}{{p}}\right) \label{eq:beqp}
	\end{align}

	by the definition of ${z}$ in \eqref{eq:zdef}:
	\begin{align}
	&\dfrac{{n}{y}}{{p}{z}} \in \mathbb{Z} \label{eq:nypzinz}
	\end{align}

	\eqref{eq:aeqq} and \eqref{eq:beqp}:
	\begin{align}
	&{a}{b} = {q}{p}\left({z} \cdot \dfrac{{m}{x}}{{q}{z}} +
	\dfrac{{r}}{{q}}\right)\left({z} \cdot \dfrac{{n}{y}}{{p}{z}} +
	\dfrac{{s}}{{p}}\right) \label{eq:abeqqp}
	\end{align}

	partially distributing \eqref{eq:abeqqp}:
	\begin{align}
	&{a}{b} = {q}{p}\left({z}^2 \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
	\dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{r}}{{q}} \cdot
	\dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
	\dfrac{{s}}{{p}} + \dfrac{{r}}{{q}} \cdot \dfrac{{s}}{{p}}\right) \label{eq:abeqqpexp}
	\end{align}

	extracting the $\dfrac{{r}{s}}{{q}{p}}$ term from \eqref{eq:abeqqpexp} and cancelling $\dfrac{{q}{p}}{{q}{p}}$:
	\begin{align}
	&{a}{b} = {q}{p}\left({z}^2 \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
	\dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{r}}{{q}} \cdot
	\dfrac{{n}{y}}{{p}{z}} + {z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
	\dfrac{{s}}{{p}}\right) + {r}{s} \label{eq:abeqqpextr}
	\end{align}

	factoring ${z}$ from \eqref{eq:abeqqpextr}:
	\begin{align}
	&{a}{b} = {q}{p}{z}\left({z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot
	\dfrac{{n}{y}}{{p}{z}} + \dfrac{{r}}{{q}} \cdot \dfrac{{n}{y}}{{p}{z}} +
	\dfrac{{m}{x}}{{q}{z}} \cdot \dfrac{{s}}{{p}}\right) + {r}{s}
	\end{align}

	because ${z}, \dfrac{{r}}{q}, \dfrac{{s}}{{p}}, \dfrac{{m}{x}}{{q}{z}},
	\dfrac{{n}{y}}{{p}{z}} \in \mathbb{Z}$, per \eqref{eq:zdef}, \eqref{eq:rqinz}, \eqref{eq:spinz}, \eqref{eq:mxqzinz}, \eqref{eq:nypzinz}:
	\begin{align}
	&{z} \cdot \dfrac{{m}{x}}{{q}{z}} \cdot \dfrac{{n}{y}}{{p}{z}} +
	\dfrac{{r}}{{q}} \cdot \dfrac{{n}{y}}{{p}{z}} + \dfrac{{m}{x}}{{q}{z}} \cdot
	\dfrac{{s}}{{p}} \in \mathbb{Z}
	\end{align}

	by the definition of modulus:
	\begin{align}
	&{a}{b} \equiv {r}{s} \pmod{{q}{p}{z}}
	\end{align}

	by the definitions of ${q}$, ${p}$, and ${z}$ in \eqref{eq:qdef}, \eqref{eq:pdef}, and \eqref{eq:zdef}:
	\begin{align}
	&{a}{b} \equiv {r}{s} \pmod{G\left(\dfrac{{m}}{G\left({m}, {r}\right)},
	\dfrac{{n}}{G\left({n}, {s}\right)}\right) \cdot G\left({m}, {r}\right)
	\cdot G\left({n}, {s}\right)}
	\end{align}

	\end{proof}
	\end{document}