% Created 2023-11-11 Sat 20:04 % Intended LaTeX compiler: pdflatex \documentclass[11pt]{article} \usepackage[utf8]{inputenc} \usepackage[T1]{fontenc} \usepackage{graphicx} \usepackage{longtable} \usepackage{wrapfig} \usepackage{rotating} \usepackage[normalem]{ulem} \usepackage{amsmath} \usepackage{amssymb} \usepackage{capt-of} \usepackage{hyperref} \notindent \notag \usepackage{amsmath} \usepackage[a4paper,margin=1in,portrait]{geometry} \author{Elizabeth Hunt (A02364151)} \date{\today} \title{HW 08} \hypersetup{ pdfauthor={Elizabeth Hunt (A02364151)}, pdftitle={HW 08}, pdfkeywords={}, pdfsubject={}, pdfcreator={Emacs 29.1 (Org mode 9.7-pre)}, pdflang={English}} \begin{document} \maketitle \setlength\parindent{0pt} \section{Problem One} \label{sec:org7aa3a78} Let \(m\) be the number of statements that don't produce an effect on \(Y\) i.e. \(\{ Y \leftarrow Y, X1 \leftarrow X1 + 1, \cdots \}\), \(n\) be the number of statements \(Y \leftarrow Y - 1\), and \(o\) be the number of statements \(Y \leftarrow Y + 1\). A straightline program of length \(k\) must have \(m + n + o = k\) instructions. Then, the terminal snapshot ends with \(Y = o - n + 0m\). Thus, \(Y\) is at a maximum if and only if \(o = k\), thus \(Y = k\), and at a minimum if and only if \(o = n\), thus \(Y = 0\) (we cannot have \(n > o\) as by definition of \(L\), for a valid program \(P\) \(Y\) is a non-negative number). \section{Problem Two} \label{sec:orgb9efdfb} Let \(P\) be a program in \(L\) that computes \(f\). Then \(f\) is partially computable by definition, and is partially computable in \(L++\) trivially since \(L++\) is a "superset" of \(L\). (\(L++ \Leftarrow L\)). Then let \(Q\) be a program in \(L++\) that computes \(f\), \(f\) is partially computable if we can convert \(Q\) into \(L\). For each instruction \(i \in Q\), if \(i\) is in the form \(V \leftarrow k | k \in N\) then we replace \(i\) with the sequence of instructions and unique labels (with the notation \(\cdots{}\) representing a reapeating instruction until the instruction is the following index), else write \(i\) (\(L++ \Rightarrow L\)). \begin{verbatim} 1. [A1] IF V != 0 GOTO B1 2. GOTO C1 3. [B1] V <- V - 1 4. GOTO A1 5. [C1] V <- V + 1 ... V <- V + 1 (5 + k - 1). V <- V + 1 \end{verbatim} And thus any program in \(L++\) is also partially computable. \section{Problem Three} \label{sec:org53e881b} For \(n=0\), \(i(n, x) = f^0(x) = x\) is primitive recursive since it can be represented as a projection function \(u_1^1(x) = x\). If \(f^n\) is primitive recursive, then so is \(f^{n+1}\), as \(f^{n+1}\) is a finite composition \(f(f^n)\). By induction, for any \(n \in N\), \(i(n, x)\) is primitive recursive, and thus computable. \section{Problem Four} \label{sec:orgbc1477c} \subsection{One} \label{sec:org96da465} Let \(m \in N\) represent the number of compositions in a function such that the set containing all \(n\) -ary functions with "composition number" \(m\) are of the form \(f(x_1, \cdots, x_n) = g(f_1(x_1, \cdots, x_n), \cdots, f_j(x_1, \cdots, x_n))\) where each \(f_i\) is in the set of functions with a "composition number" \(\le m - 1\). Except for the case in which \(m = 0\) - the initial functions; which are all of the form \(k\) or \(x_i + k\). Then, let \(F^m | m \in N\) represent the set of all functions of composition number \(m\) or less, and assume that \(\forall f \in F^m\) are of either form \(k\) or \(x_i + k\). Then, \(g \in F^{m+1} | m \in N\)'s elements are \(g(x_1, \cdots, x_n) = f(f_1(x_1, \cdots, x_n), \cdots, f_j(x_1, \cdots, x_n))\) where \(f\) is an initial function, by definition, and each \(f_i | 1 \le i \le j \in F^m\). \begin{enumerate} \item If \(f\) is the Zero function \(g\) is in the form \(k = 0\) \item If \(f\) is the Successor function \(g\) is some \(f_i(\cdots) + 1\) which by assumption is thus \((x_i + k) + 1 \Rightarrow x_i + k\) or \(k + 1 \Rightarrow k\). \item If \(f\) is the Projection function \(g\) is some \(f_i(\cdots)\) which by assumption is \((x_i + k)\) or \(k\). \end{enumerate} Finally, by induction, \(\forall f(x_1, \cdots, x_n) \in\) \texttt{COMP}, \(f\) is thus in the form \(k\) or \(x_i + k | 1 \le i \le n\). \subsection{Two} \label{sec:org74c3eb4} By what we showed in One, \(f(x_1, \cdots, x_n)\) is dependent on a single \(x_i \in {x_1, \cdots, x_n}\) and produces \(r = (x_i + k)\) or \(r = k\). Then \(f(y_1, \cdots, y_n) = (y_i + k) | k\) for the same \(i\). So if for all \(i | 1 \le i \le n\), \(x_i \le y_i\) then \((y_i + k) \ge (x_i + k)\) or \(k = k\). Thus in both cases \(f(y_1, \cdots, y_n) \ge f(x_1, \cdots, x_n)\) and is thus monotonic. \subsection{Three} \label{sec:org8b3878c} Yes. Firstly, every \(f \in\) \texttt{COMP} is primitive recursive, just without the recursion, so it is a subset of the set of all primitive recursive functions. Consider the (proven in class) primitive recursive function \(f(x_1, x_2) = x_1 * x_2\), and the equivalent \(g \in\) \texttt{COMP}. \(g(x_1, x_2)\) is equivalent to \(x_1 + k\), \(x_2 + k\), or \(k\). Then there all elements of \(\{f(x_1, x_2 + 1), f(x_1 + 1, x_2), f(x_1, x_2)\} | x_1, x_2 > 1\) cannot be present in \(\{g(x_1, x_2 + 1), g(x_1 + 1, x_2), g(x_1, x_2)\}\) for the same \(x_1, x_2\) due to the dependence relation, which is a contradiction to \(f\) and \(g\) being equivalent. \subsection{Four} \label{sec:orgcea60eb} Yes. By the fact that all primitive recursive functions are computable, \texttt{COMP} being a set of primitive recursive functions from Three, is a subset of computable functions. However, we also showed in Three that there exists a computable (primitive recursive) function which is not in \texttt{COMP}, so \texttt{COMP} is not equivalent to the set of all computable functions. \section{Problem Five} \label{sec:orgab79ce2} \begin{enumerate} \item Let \(a(x_1, x_2) = x_1 + x_2\) and \(m(x_1, x_2) = x_1 * x_2\) which are primitive recursive by proofs in class. \item Let \(t(x_1)\) be the composition of the successor function \(s\) 10 times on the zero function \(z\) function: \(t(x_1) = s(s(\cdots(n(x_1))))\), and is primitive recursive. \item Let \(v(x_1)\) be \(v(x_1) = a(x_1, a(x_1, a(x_1, a(x_1, u_1^1(x_1)))))\), which is primitive recursive. \item Let \(w(x_1)\) be \(w(x_1) = a(t(x_1), v(x_1))\), which is primitive recursive. \item Let \(y(x_1)\) be \(y(x_1) = m(m(x_1, x_1), s(s(n(x_1))))\), which is primitive recursive. \item Then \(f(x_1)\) is \(a(w(x_1), y(x_1))\), which is primitive recursive. \end{enumerate} \end{document}