Ur/Web: doc/manual.tex annotate

annotate doc/manual.tex @ 1085:ae885ad70d83

Updating the manual

author	Adam Chlipala <adamc@hcoop.net>
date	Thu, 24 Dec 2009 09:56:09 -0500
parents	93315ac00394
children	99aebdf30257

rev	line source
adamc@524	1 \documentclass{article}
adamc@554	2 \usepackage{fullpage,amsmath,amssymb,proof,url}
adamc@524	3
adamc@524	4 \newcommand{\cd}[1]{\texttt{#1}}
adamc@524	5 \newcommand{\mt}[1]{\mathsf{#1}}
adamc@524	6
adamc@524	7 \newcommand{\rc}{+ \hspace{-.075in} + \;}
adamc@527	8 \newcommand{\rcut}{\; \texttt{--} \;}
adamc@527	9 \newcommand{\rcutM}{\; \texttt{---} \;}
adamc@524	10
adamc@524	11 \begin{document}
adamc@524	12
adamc@524	13 \title{The Ur/Web Manual}
adamc@524	14 \author{Adam Chlipala}
adamc@524	15
adamc@524	16 \maketitle
adamc@524	17
adamc@540	18 \tableofcontents
adamc@540	19
adamc@554	20
adamc@554	21 \section{Introduction}
adamc@554	22
adamc@554	23 \emph{Ur} is a programming language designed to introduce richer type system features into functional programming in the tradition of ML and Haskell. Ur is functional, pure, statically-typed, and strict. Ur supports a powerful kind of \emph{metaprogramming} based on \emph{row types}.
adamc@554	24
adamc@554	25 \emph{Ur/Web} is Ur plus a special standard library and associated rules for parsing and optimization. Ur/Web supports construction of dynamic web applications backed by SQL databases. The signature of the standard library is such that well-typed Ur/Web programs ``don't go wrong'' in a very broad sense. Not only do they not crash during particular page generations, but they also may not:
adamc@554	26
adamc@554	27 \begin{itemize}
adamc@554	28 \item Suffer from any kinds of code-injection attacks
adamc@554	29 \item Return invalid HTML
adamc@554	30 \item Contain dead intra-application links
adamc@554	31 \item Have mismatches between HTML forms and the fields expected by their handlers
adamc@652	32 \item Include client-side code that makes incorrect assumptions about the ``AJAX''-style services that the remote web server provides
adamc@554	33 \item Attempt invalid SQL queries
adamc@652	34 \item Use improper marshaling or unmarshaling in communication with SQL databases or between browsers and web servers
adamc@554	35 \end{itemize}
adamc@554	36
adamc@554	37 This type safety is just the foundation of the Ur/Web methodology. It is also possible to use metaprogramming to build significant application pieces by analysis of type structure. For instance, the demo includes an ML-style functor for building an admin interface for an arbitrary SQL table. The type system guarantees that the admin interface sub-application that comes out will always be free of the above-listed bugs, no matter which well-typed table description is given as input.
adamc@554	38
adamc@652	39 The Ur/Web compiler also produces very efficient object code that does not use garbage collection. These compiled programs will often be even more efficient than what most programmers would bother to write in C. The compiler also generates JavaScript versions of client-side code, with no need to write those parts of applications in a different language.
adamc@554	40
adamc@554	41 \medskip
adamc@554	42
adamc@554	43 The official web site for Ur is:
adamc@554	44 \begin{center}
adamc@554	45 \url{http://www.impredicative.com/ur/}
adamc@554	46 \end{center}
adamc@554	47
adamc@555	48
adamc@555	49 \section{Installation}
adamc@555	50
adamc@555	51 If you are lucky, then the following standard command sequence will suffice for installation, in a directory to which you have unpacked the latest distribution tarball.
adamc@555	52
adamc@555	53 \begin{verbatim}
adamc@555	54 ./configure
adamc@555	55 make
adamc@555	56 sudo make install
adamc@555	57 \end{verbatim}
adamc@555	58
adamc@896	59 Some other packages must be installed for the above to work. At a minimum, you need a standard UNIX shell, with standard UNIX tools like sed and GCC in your execution path; MLton, the whole-program optimizing compiler for Standard ML; and the mhash C library. As of this writing, in the ``testing'' version of Debian Linux, this command will install the more uncommon of these dependencies:
adamc@896	60 \begin{verbatim}
adamc@896	61 apt-get install mlton libmhash-dev
adamc@896	62 \end{verbatim}
adamc@555	63
adamc@896	64 To build programs that access SQL databases, you also need one of these client libraries for supported backends.
adamc@555	65 \begin{verbatim}
adamc@896	66 apt-get install libpq-dev libmysqlclient15-dev libsqlite3-dev
adamc@555	67 \end{verbatim}
adamc@555	68
adamc@555	69 It is also possible to access the modules of the Ur/Web compiler interactively, within Standard ML of New Jersey. To install the prerequisites in Debian testing:
adamc@555	70 \begin{verbatim}
adamc@555	71 apt-get install smlnj libsmlnj-smlnj ml-yacc ml-lpt
adamc@555	72 \end{verbatim}
adamc@555	73
adamc@555	74 To begin an interactive session with the Ur compiler modules, run \texttt{make smlnj}, and then, from within an \texttt{sml} session, run \texttt{CM.make "src/urweb.cm";}. The \texttt{Compiler} module is the main entry point.
adamc@555	75
adamc@896	76 To run an SQL-backed application with a backend besides SQLite, you will probably want to install one of these servers.
adamc@555	77
adamc@555	78 \begin{verbatim}
adamc@896	79 apt-get install postgresql-8.3 mysql-server-5.0
adamc@555	80 \end{verbatim}
adamc@555	81
adamc@555	82 To use the Emacs mode, you must have a modern Emacs installed. We assume that you already know how to do this, if you're in the business of looking for an Emacs mode. The demo generation facility of the compiler will also call out to Emacs to syntax-highlight code, and that process depends on the \texttt{htmlize} module, which can be installed in Debian testing via:
adamc@555	83
adamc@555	84 \begin{verbatim}
adamc@555	85 apt-get install emacs-goodies-el
adamc@555	86 \end{verbatim}
adamc@555	87
adamc@555	88 Even with the right packages installed, configuration and building might fail to work. After you run \texttt{./configure}, you will see the values of some named environment variables printed. You may need to adjust these values to get proper installation for your system. To change a value, store your preferred alternative in the corresponding UNIX environment variable, before running \texttt{./configure}. For instance, here is how to change the list of extra arguments that the Ur/Web compiler will pass to GCC on every invocation.
adamc@555	89
adamc@555	90 \begin{verbatim}
adamc@555	91 GCCARGS=-fnested-functions ./configure
adamc@555	92 \end{verbatim}
adamc@555	93
adamc@555	94 Some OSX users have reported needing to use this particular GCCARGS value.
adamc@555	95
adamc@555	96 The Emacs mode can be set to autoload by adding the following to your \texttt{.emacs} file.
adamc@555	97
adamc@555	98 \begin{verbatim}
adamc@555	99 (add-to-list 'load-path "/usr/local/share/emacs/site-lisp/urweb-mode")
adamc@555	100 (load "urweb-mode-startup")
adamc@555	101 \end{verbatim}
adamc@555	102
adamc@555	103 Change the path in the first line if you chose a different Emacs installation path during configuration.
adamc@555	104
adamc@555	105
adamc@556	106 \section{Command-Line Compiler}
adamc@556	107
adamc@556	108 \subsection{Project Files}
adamc@556	109
adamc@556	110 The basic inputs to the \texttt{urweb} compiler are project files, which have the extension \texttt{.urp}. Here is a sample \texttt{.urp} file.
adamc@556	111
adamc@556	112 \begin{verbatim}
adamc@556	113 database dbname=test
adamc@556	114 sql crud1.sql
adamc@556	115
adamc@556	116 crud
adamc@556	117 crud1
adamc@556	118 \end{verbatim}
adamc@556	119
adamc@556	120 The \texttt{database} line gives the database information string to pass to libpq. In this case, the string only says to connect to a local database named \texttt{test}.
adamc@556	121
adamc@556	122 The \texttt{sql} line asks for an SQL source file to be generated, giving the commands to run to create the tables and sequences that this application expects to find. After building this \texttt{.urp} file, the following commands could be used to initialize the database, assuming that the current UNIX user exists as a Postgres user with database creation privileges:
adamc@556	123
adamc@556	124 \begin{verbatim}
adamc@556	125 createdb test
adamc@556	126 psql -f crud1.sql test
adamc@556	127 \end{verbatim}
adamc@556	128
adamc@556	129 A blank line always separates the named directives from a list of modules to include in the project; if there are no named directives, a blank line must begin the file.
adamc@556	130
adamc@556	131 For each entry \texttt{M} in the module list, the file \texttt{M.urs} is included in the project if it exists, and the file \texttt{M.ur} must exist and is always included.
adamc@556	132
adamc@783	133 Here is the complete list of directive forms. ``FFI'' stands for ``foreign function interface,'' Ur's facility for interaction between Ur programs and C and JavaScript libraries.
adamc@783	134 \begin{itemize}
adamc@783	135 \item \texttt{[allow\|deny] [url\|mime] PATTERN} registers a rule governing which URLs or MIME types are allowed in this application. The first such rule to match a URL or MIME type determines the verdict. If \texttt{PATTERN} ends in \texttt{*}, it is interpreted as a prefix rule. Otherwise, a string must match it exactly.
adamc@783	136 \item \texttt{clientOnly Module.ident} registers an FFI function or transaction that may only be run in client browsers.
adamc@783	137 \item \texttt{clientToServer Module.ident} adds FFI type \texttt{Module.ident} to the list of types that are OK to marshal from clients to servers. Values like XML trees and SQL queries are hard to marshal without introducing expensive validity checks, so it's easier to ensure that the server never trusts clients to send such values. The file \texttt{include/urweb.h} shows examples of the C support functions that are required of any type that may be marshalled. These include \texttt{attrify}, \texttt{urlify}, and \texttt{unurlify} functions.
adamc@783	138 \item \texttt{database DBSTRING} sets the string to pass to libpq to open a database connection.
adamc@783	139 \item \texttt{debug} saves some intermediate C files, which is mostly useful to help in debugging the compiler itself.
adamc@783	140 \item \texttt{effectful Module.ident} registers an FFI function or transaction as having side effects. The optimizer avoids removing, moving, or duplicating calls to such functions. Every effectful FFI function must be registered, or the optimizer may make invalid transformations.
adamc@783	141 \item \texttt{exe FILENAME} sets the filename to which to write the output executable. The default for file \texttt{P.urp} is \texttt{P.exe}.
adamc@783	142 \item \texttt{ffi FILENAME} reads the file \texttt{FILENAME.urs} to determine the interface to a new FFI module. The name of the module is calculated from \texttt{FILENAME} in the same way as for normal source files. See the files \texttt{include/urweb.h} and \texttt{src/c/urweb.c} for examples of C headers and implementations for FFI modules. In general, every type or value \texttt{Module.ident} becomes \texttt{uw\_Module\_ident} in C.
adamc@873	143 \item \texttt{header FILENAME} adds \texttt{FILENAME} to the list of files to be \texttt{\#include}d in C sources. This is most useful for interfacing with new FFI modules.
adamc@783	144 \item \texttt{jsFunc Module.ident=name} gives the JavaScript name of an FFI value.
adamc@783	145 \item \texttt{library FILENAME} parses \texttt{FILENAME.urp} and merges its contents with the rest of the current file's contents.
adamc@783	146 \item \texttt{link FILENAME} adds \texttt{FILENAME} to the list of files to be passed to the GCC linker at the end of compilation. This is most useful for importing extra libraries needed by new FFI modules.
adamc@852	147 \item \texttt{path NAME=VALUE} creates a mapping from \texttt{NAME} to \texttt{VALUE}. This mapping may be used at the beginnings of filesystem paths given to various other configuration directives. A path like \texttt{\$NAME/rest} is expanded to \texttt{VALUE/rest}. There is an initial mapping from the empty name (for paths like \texttt{\$/list}) to the directory where the Ur/Web standard library is installed. If you accept the default \texttt{configure} options, this directory is \texttt{/usr/local/lib/urweb/ur}.
adamc@783	148 \item \texttt{prefix PREFIX} sets the prefix included before every URI within the generated application. The default is \texttt{/}.
adamc@783	149 \item \texttt{profile} generates an executable that may be used with gprof.
adamc@783	150 \item \texttt{rewrite KIND FROM TO} gives a rule for rewriting canonical module paths. For instance, the canonical path of a page may be \texttt{Mod1.Mod2.mypage}, while you would rather the page were accessed via a URL containing only \texttt{page}. The directive \texttt{rewrite url Mod1/Mod2/mypage page} would accomplish that. The possible values of \texttt{KIND} determine which kinds of objects are affected. The kind \texttt{all} matches any object, and \texttt{url} matches page URLs. The kinds \texttt{table}, \texttt{sequence}, and \texttt{view} match those sorts of SQL entities, and \texttt{relation} matches any of those three. \texttt{cookie} matches HTTP cookies, and \texttt{style} matches CSS class names. If \texttt{FROM} ends in \texttt{/*}, it is interpreted as a prefix matching rule, and rewriting occurs by replacing only the appropriate prefix of a path with \texttt{TO}. While the actual external names of relations and styles have parts separated by underscores instead of slashes, all rewrite rules must be written in terms of slashes.
adamc@783	151 \item \texttt{script URL} adds \texttt{URL} to the list of extra JavaScript files to be included at the beginning of any page that uses JavaScript. This is most useful for importing JavaScript versions of functions found in new FFI modules.
adamc@783	152 \item \texttt{serverOnly Module.ident} registers an FFI function or transaction that may only be run on the server.
adamc@783	153 \item \texttt{sql FILENAME} sets where to write an SQL file with the commands to create the expected database schema. The default is not to create such a file.
adamc@783	154 \item \texttt{timeout N} sets to \texttt{N} seconds the amount of time that the generated server will wait after the last contact from a client before determining that that client has exited the application. Clients that remain active will take the timeout setting into account in determining how often to ping the server, so it only makes sense to set a high timeout to cope with browser and network delays and failures. Higher timeouts can lead to more unnecessary client information taking up memory on the server. The timeout goes unused by any page that doesn't involve the \texttt{recv} function, since the server only needs to store per-client information for clients that receive asynchronous messages.
adamc@783	155 \end{itemize}
adamc@701	156
adamc@701	157
adamc@557	158 \subsection{Building an Application}
adamc@557	159
adamc@557	160 To compile project \texttt{P.urp}, simply run
adamc@557	161 \begin{verbatim}
adamc@557	162 urweb P
adamc@557	163 \end{verbatim}
adamc@558	164 The output executable is a standalone web server. Run it with the command-line argument \texttt{-h} to see which options it takes. If the project file lists a database, the web server will attempt to connect to that database on startup.
adamc@557	165
adamc@557	166 To time how long the different compiler phases run, without generating an executable, run
adamc@557	167 \begin{verbatim}
adamc@557	168 urweb -timing P
adamc@557	169 \end{verbatim}
adamc@557	170
adamc@896	171 Some other command-line parameters are accepted:
adamc@896	172 \begin{itemize}
adamc@896	173 \item \texttt{-db <DBSTRING>}: Set database connection information, using the format expected by Postgres's \texttt{PQconnectdb()}, which is \texttt{name1=value1 ... nameN=valueN}. The same format is also parsed and used to discover connection parameters for MySQL and SQLite. The only significant settings for MySQL are \texttt{host}, \texttt{hostaddr}, \texttt{port}, \texttt{dbname}, \texttt{user}, and \texttt{password}. The only significant setting for SQLite is \texttt{dbname}, which is interpreted as the filesystem path to the database. Additionally, when using SQLite, a database string may be just a file path.
adamc@896	174
adamc@896	175 \item \texttt{-dbms [postgres\|mysql\|sqlite]}: Sets the database backend to use.
adamc@896	176 \begin{itemize}
adamc@896	177 \item \texttt{postgres}: This is PostgreSQL, the default. Among the supported engines, Postgres best matches the design philosophy behind Ur, with a focus on consistent views of data, even in the face of much concurrency. Different database engines have different quirks of SQL syntax. Ur/Web tends to use Postgres idioms where there are choices to be made, though the compiler translates SQL as needed to support other backends.
adamc@896	178
adamc@896	179 A command sequence like this can initialize a Postgres database, using a file \texttt{app.sql} generated by the compiler:
adamc@896	180 \begin{verbatim}
adamc@896	181 createdb app
adamc@896	182 psql -f app.sql app
adamc@896	183 \end{verbatim}
adamc@896	184
adamc@896	185 \item \texttt{mysql}: This is MySQL, another popular relational database engine that uses persistent server processes. Ur/Web needs transactions to function properly. Many installations of MySQL use non-transactional storage engines by default. Ur/Web generates table definitions that try to use MySQL's InnoDB engine, which supports transactions. You can edit the first line of a generated \texttt{.sql} file to change this behavior, but it really is true that Ur/Web applications will exhibit bizarre behavior if you choose an engine that ignores transaction commands.
adamc@896	186
adamc@896	187 A command sequence like this can initialize a MySQL database:
adamc@896	188 \begin{verbatim}
adamc@896	189 echo "CREATE DATABASE app" \| mysql
adamc@896	190 mysql -D app <app.sql
adamc@896	191 \end{verbatim}
adamc@896	192
adamc@896	193 \item \texttt{sqlite}: This is SQLite, a simple filesystem-based transactional database engine. With this backend, Ur/Web applications can run without any additional server processes. The other engines are generally preferred for large-workload performance and full admin feature sets, while SQLite is popular for its low resource footprint and ease of set-up.
adamc@896	194
adamc@896	195 A command like this can initialize an SQLite database:
adamc@896	196 \begin{verbatim}
adamc@896	197 sqlite3 path/to/database/file <app.sql
adamc@896	198 \end{verbatim}
adamc@896	199 \end{itemize}
adamc@896	200
adamc@896	201 \item \texttt{-output FILENAME}: Set where the application executable is written.
adamc@896	202
adamc@896	203 \item \texttt{-protocol [http\|cgi\|fastcgi]}: Set the protocol that the generated application speaks.
adamc@896	204 \begin{itemize}
adamc@896	205 \item \texttt{http}: This is the default. It is for building standalone web servers that can be accessed by web browsers directly.
adamc@896	206
adamc@896	207 \item \texttt{cgi}: This is the classic protocol that web servers use to generate dynamic content by spawning new processes. While Ur/Web programs may in general use message-passing with the \texttt{send} and \texttt{recv} functions, that functionality is not yet supported in CGI, since CGI needs a fresh process for each request, and message-passing needs to use persistent sockets to deliver messages.
adamc@896	208
adamc@896	209 Since Ur/Web treats paths in an unusual way, a configuration line like this one can be used to configure an application that was built with URL prefix \texttt{/Hello}:
adamc@896	210 \begin{verbatim}
adamc@896	211 ScriptAlias /Hello /path/to/hello.exe
adamc@896	212 \end{verbatim}
adamc@896	213
adamc@896	214 \item \texttt{fastcgi}: This is a newer protocol inspired by CGI, wherein web servers can start and reuse persistent external processes to generate dynamic content. Ur/Web doesn't implement the whole protocol, but Ur/Web's support has been tested to work with the \texttt{mod\_fastcgi}s of Apache and lighttpd.
adamc@896	215
adamc@896	216 To configure a FastCGI program with Apache, one could combine the above \texttt{ScriptAlias} line with a line like this:
adamc@896	217 \begin{verbatim}
adamc@896	218 FastCgiServer /path/to/hello.exe -idle-timeout 99999
adamc@896	219 \end{verbatim}
adamc@896	220 The idle timeout is only important for applications that use message-passing. Client connections may go long periods without receiving messages, and Apache tries to be helpful and garbage collect them in such cases. To prevent that behavior, we specify how long a connection must be idle to be collected.
adamc@896	221
adamc@896	222 Here is some lighttpd configuration for the same application.
adamc@896	223 \begin{verbatim}
adamc@896	224 fastcgi.server = (
adamc@896	225 "/Hello/" =>
adamc@896	226 (( "bin-path" => "/path/to/hello.exe",
adamc@896	227 "socket" => "/tmp/hello",
adamc@896	228 "check-local" => "disable",
adamc@896	229 "docroot" => "/",
adamc@896	230 "max-procs" => "1"
adamc@896	231 ))
adamc@896	232 )
adamc@896	233 \end{verbatim}
adamc@896	234 The least obvious requirement is setting \texttt{max-procs} to 1, so that lighttpd doesn't try to multiplex requests across multiple external processes. This is required for message-passing applications, where a single database of client connections is maintained within a multi-threaded server process. Multiple processes may, however, be used safely with applications that don't use message-passing.
adamc@896	235
adamc@896	236 A FastCGI process reads the environment variable \texttt{URWEB\_NUM\_THREADS} to determine how many threads to spawn for handling client requests. The default is 1.
adamc@896	237 \end{itemize}
adamc@896	238
adamc@896	239 \item \texttt{-sql FILENAME}: Set where a database set-up SQL script is written.
adamc@896	240 \end{itemize}
adamc@896	241
adamc@556	242
adamc@529	243 \section{Ur Syntax}
adamc@529	244
adamc@784	245 In this section, we describe the syntax of Ur, deferring to a later section discussion of most of the syntax specific to SQL and XML. The sole exceptions are the declaration forms for relations, cookies, and styles.
adamc@524	246
adamc@524	247 \subsection{Lexical Conventions}
adamc@524	248
adamc@524	249 We give the Ur language definition in \LaTeX $\;$ math mode, since that is prettier than monospaced ASCII. The corresponding ASCII syntax can be read off directly. Here is the key for mapping math symbols to ASCII character sequences.
adamc@524	250
adamc@524	251 \begin{center}
adamc@524	252 \begin{tabular}{rl}
adamc@524	253 \textbf{\LaTeX} & \textbf{ASCII} \\
adamc@524	254 $\to$ & \cd{->} \\
adamc@652	255 $\longrightarrow$ & \cd{-->} \\
adamc@524	256 $\times$ & \cd{*} \\
adamc@524	257 $\lambda$ & \cd{fn} \\
adamc@524	258 $\Rightarrow$ & \cd{=>} \\
adamc@652	259 $\Longrightarrow$ & \cd{==>} \\
adamc@529	260 $\neq$ & \cd{<>} \\
adamc@529	261 $\leq$ & \cd{<=} \\
adamc@529	262 $\geq$ & \cd{>=} \\
adamc@524	263 \\
adamc@524	264 $x$ & Normal textual identifier, not beginning with an uppercase letter \\
adamc@525	265 $X$ & Normal textual identifier, beginning with an uppercase letter \\
adamc@524	266 \end{tabular}
adamc@524	267 \end{center}
adamc@524	268
adamc@525	269 We often write syntax like $e^$ to indicate zero or more copies of $e$, $e^+$ to indicate one or more copies, and $e,^$ and $e,^+$ to indicate multiple copies separated by commas. Another separator may be used in place of a comma. The $e$ term may be surrounded by parentheses to indicate grouping; those parentheses should not be included in the actual ASCII.
adamc@524	270
adamc@873	271 We write $\ell$ for literals of the primitive types, for the most part following C conventions. There are $\mt{int}$, $\mt{float}$, $\mt{char}$, and $\mt{string}$ literals. Character literals follow the SML convention instead of the C convention, written like \texttt{\#"a"} instead of \texttt{'a'}.
adamc@526	272
adamc@527	273 This version of the manual doesn't include operator precedences; see \texttt{src/urweb.grm} for that.
adamc@527	274
adamc@552	275 \subsection{\label{core}Core Syntax}
adamc@524	276
adamc@524	277 \emph{Kinds} classify types and other compile-time-only entities. Each kind in the grammar is listed with a description of the sort of data it classifies.
adamc@524	278 $$\begin{array}{rrcll}
adamc@524	279 \textrm{Kinds} & \kappa &::=& \mt{Type} & \textrm{proper types} \\
adamc@525	280 &&& \mt{Unit} & \textrm{the trivial constructor} \\
adamc@525	281 &&& \mt{Name} & \textrm{field names} \\
adamc@525	282 &&& \kappa \to \kappa & \textrm{type-level functions} \\
adamc@525	283 &&& \{\kappa\} & \textrm{type-level records} \\
adamc@525	284 &&& (\kappa\times^+) & \textrm{type-level tuples} \\
adamc@652	285 &&& X & \textrm{variable} \\
adamc@652	286 &&& X \longrightarrow k & \textrm{kind-polymorphic type-level function} \\
adamc@529	287 &&& \_\_ & \textrm{wildcard} \\
adamc@525	288 &&& (\kappa) & \textrm{explicit precedence} \\
adamc@524	289 \end{array}$$
adamc@524	290
adamc@524	291 Ur supports several different notions of functions that take types as arguments. These arguments can be either implicit, causing them to be inferred at use sites; or explicit, forcing them to be specified manually at use sites. There is a common explicitness annotation convention applied at the definitions of and in the types of such functions.
adamc@524	292 $$\begin{array}{rrcll}
adamc@524	293 \textrm{Explicitness} & ? &::=& :: & \textrm{explicit} \\
adamc@558	294 &&& ::: & \textrm{implicit}
adamc@524	295 \end{array}$$
adamc@524	296
adamc@524	297 \emph{Constructors} are the main class of compile-time-only data. They include proper types and are classified by kinds.
adamc@524	298 $$\begin{array}{rrcll}
adamc@524	299 \textrm{Constructors} & c, \tau &::=& (c) :: \kappa & \textrm{kind annotation} \\
adamc@530	300 &&& \hat{x} & \textrm{constructor variable} \\
adamc@524	301 \\
adamc@525	302 &&& \tau \to \tau & \textrm{function type} \\
adamc@525	303 &&& x \; ? \; \kappa \to \tau & \textrm{polymorphic function type} \\
adamc@652	304 &&& X \longrightarrow \tau & \textrm{kind-polymorphic function type} \\
adamc@525	305 &&& \$ c & \textrm{record type} \\
adamc@524	306 \\
adamc@525	307 &&& c \; c & \textrm{type-level function application} \\
adamc@530	308 &&& \lambda x \; :: \; \kappa \Rightarrow c & \textrm{type-level function abstraction} \\
adamc@524	309 \\
adamc@652	310 &&& X \Longrightarrow c & \textrm{type-level kind-polymorphic function abstraction} \\
adamc@655	311 &&& c [\kappa] & \textrm{type-level kind-polymorphic function application} \\
adamc@652	312 \\
adamc@525	313 &&& () & \textrm{type-level unit} \\
adamc@525	314 &&& \#X & \textrm{field name} \\
adamc@524	315 \\
adamc@525	316 &&& [(c = c)^*] & \textrm{known-length type-level record} \\
adamc@525	317 &&& c \rc c & \textrm{type-level record concatenation} \\
adamc@652	318 &&& \mt{map} & \textrm{type-level record map} \\
adamc@524	319 \\
adamc@558	320 &&& (c,^+) & \textrm{type-level tuple} \\
adamc@525	321 &&& c.n & \textrm{type-level tuple projection ($n \in \mathbb N^+$)} \\
adamc@524	322 \\
adamc@652	323 &&& [c \sim c] \Rightarrow \tau & \textrm{guarded type} \\
adamc@524	324 \\
adamc@529	325 &&& \_ :: \kappa & \textrm{wildcard} \\
adamc@525	326 &&& (c) & \textrm{explicit precedence} \\
adamc@530	327 \\
adamc@530	328 \textrm{Qualified uncapitalized variables} & \hat{x} &::=& x & \textrm{not from a module} \\
adamc@530	329 &&& M.x & \textrm{projection from a module} \\
adamc@525	330 \end{array}$$
adamc@525	331
adamc@655	332 We include both abstraction and application for kind polymorphism, but applications are only inferred internally; they may not be written explicitly in source programs.
adamc@655	333
adamc@525	334 Modules of the module system are described by \emph{signatures}.
adamc@525	335 $$\begin{array}{rrcll}
adamc@525	336 \textrm{Signatures} & S &::=& \mt{sig} \; s^* \; \mt{end} & \textrm{constant} \\
adamc@525	337 &&& X & \textrm{variable} \\
adamc@525	338 &&& \mt{functor}(X : S) : S & \textrm{functor} \\
adamc@529	339 &&& S \; \mt{where} \; \mt{con} \; x = c & \textrm{concretizing an abstract constructor} \\
adamc@525	340 &&& M.X & \textrm{projection from a module} \\
adamc@525	341 \\
adamc@525	342 \textrm{Signature items} & s &::=& \mt{con} \; x :: \kappa & \textrm{abstract constructor} \\
adamc@525	343 &&& \mt{con} \; x :: \kappa = c & \textrm{concrete constructor} \\
adamc@528	344 &&& \mt{datatype} \; x \; x^* = dc\mid^+ & \textrm{algebraic datatype definition} \\
adamc@529	345 &&& \mt{datatype} \; x = \mt{datatype} \; M.x & \textrm{algebraic datatype import} \\
adamc@525	346 &&& \mt{val} \; x : \tau & \textrm{value} \\
adamc@525	347 &&& \mt{structure} \; X : S & \textrm{sub-module} \\
adamc@525	348 &&& \mt{signature} \; X = S & \textrm{sub-signature} \\
adamc@525	349 &&& \mt{include} \; S & \textrm{signature inclusion} \\
adamc@525	350 &&& \mt{constraint} \; c \sim c & \textrm{record disjointness constraint} \\
adamc@654	351 &&& \mt{class} \; x :: \kappa & \textrm{abstract constructor class} \\
adamc@654	352 &&& \mt{class} \; x :: \kappa = c & \textrm{concrete constructor class} \\
adamc@525	353 \\
adamc@525	354 \textrm{Datatype constructors} & dc &::=& X & \textrm{nullary constructor} \\
adamc@525	355 &&& X \; \mt{of} \; \tau & \textrm{unary constructor} \\
adamc@524	356 \end{array}$$
adamc@524	357
adamc@526	358 \emph{Patterns} are used to describe structural conditions on expressions, such that expressions may be tested against patterns, generating assignments to pattern variables if successful.
adamc@526	359 $$\begin{array}{rrcll}
adamc@526	360 \textrm{Patterns} & p &::=& \_ & \textrm{wildcard} \\
adamc@526	361 &&& x & \textrm{variable} \\
adamc@526	362 &&& \ell & \textrm{constant} \\
adamc@526	363 &&& \hat{X} & \textrm{nullary constructor} \\
adamc@526	364 &&& \hat{X} \; p & \textrm{unary constructor} \\
adamc@526	365 &&& \{(x = p,)^*\} & \textrm{rigid record pattern} \\
adamc@526	366 &&& \{(x = p,)^+, \ldots\} & \textrm{flexible record pattern} \\
adamc@852	367 &&& p : \tau & \textrm{type annotation} \\
adamc@527	368 &&& (p) & \textrm{explicit precedence} \\
adamc@526	369 \\
adamc@529	370 \textrm{Qualified capitalized variables} & \hat{X} &::=& X & \textrm{not from a module} \\
adamc@526	371 &&& M.X & \textrm{projection from a module} \\
adamc@526	372 \end{array}$$
adamc@526	373
adamc@527	374 \emph{Expressions} are the main run-time entities, corresponding to both ``expressions'' and ``statements'' in mainstream imperative languages.
adamc@527	375 $$\begin{array}{rrcll}
adamc@527	376 \textrm{Expressions} & e &::=& e : \tau & \textrm{type annotation} \\
adamc@529	377 &&& \hat{x} & \textrm{variable} \\
adamc@529	378 &&& \hat{X} & \textrm{datatype constructor} \\
adamc@527	379 &&& \ell & \textrm{constant} \\
adamc@527	380 \\
adamc@527	381 &&& e \; e & \textrm{function application} \\
adamc@527	382 &&& \lambda x : \tau \Rightarrow e & \textrm{function abstraction} \\
adamc@527	383 &&& e [c] & \textrm{polymorphic function application} \\
adamc@852	384 &&& \lambda [x \; ? \; \kappa] \Rightarrow e & \textrm{polymorphic function abstraction} \\
adamc@655	385 &&& e [\kappa] & \textrm{kind-polymorphic function application} \\
adamc@652	386 &&& X \Longrightarrow e & \textrm{kind-polymorphic function abstraction} \\
adamc@527	387 \\
adamc@527	388 &&& \{(c = e,)^*\} & \textrm{known-length record} \\
adamc@527	389 &&& e.c & \textrm{record field projection} \\
adamc@527	390 &&& e \rc e & \textrm{record concatenation} \\
adamc@527	391 &&& e \rcut c & \textrm{removal of a single record field} \\
adamc@527	392 &&& e \rcutM c & \textrm{removal of multiple record fields} \\
adamc@527	393 \\
adamc@527	394 &&& \mt{let} \; ed^* \; \mt{in} \; e \; \mt{end} & \textrm{local definitions} \\
adamc@527	395 \\
adamc@527	396 &&& \mt{case} \; e \; \mt{of} \; (p \Rightarrow e\|)^+ & \textrm{pattern matching} \\
adamc@527	397 \\
adamc@654	398 &&& \lambda [c \sim c] \Rightarrow e & \textrm{guarded expression abstraction} \\
adamc@654	399 &&& e \; ! & \textrm{guarded expression application} \\
adamc@527	400 \\
adamc@527	401 &&& \_ & \textrm{wildcard} \\
adamc@527	402 &&& (e) & \textrm{explicit precedence} \\
adamc@527	403 \\
adamc@527	404 \textrm{Local declarations} & ed &::=& \cd{val} \; x : \tau = e & \textrm{non-recursive value} \\
adamc@527	405 &&& \cd{val} \; \cd{rec} \; (x : \tau = e \; \cd{and})^+ & \textrm{mutually-recursive values} \\
adamc@527	406 \end{array}$$
adamc@527	407
adamc@655	408 As with constructors, we include both abstraction and application for kind polymorphism, but applications are only inferred internally.
adamc@655	409
adamc@528	410 \emph{Declarations} primarily bring new symbols into context.
adamc@528	411 $$\begin{array}{rrcll}
adamc@528	412 \textrm{Declarations} & d &::=& \mt{con} \; x :: \kappa = c & \textrm{constructor synonym} \\
adamc@528	413 &&& \mt{datatype} \; x \; x^* = dc\mid^+ & \textrm{algebraic datatype definition} \\
adamc@529	414 &&& \mt{datatype} \; x = \mt{datatype} \; M.x & \textrm{algebraic datatype import} \\
adamc@528	415 &&& \mt{val} \; x : \tau = e & \textrm{value} \\
adamc@528	416 &&& \mt{val} \; \cd{rec} \; (x : \tau = e \; \mt{and})^+ & \textrm{mutually-recursive values} \\
adamc@528	417 &&& \mt{structure} \; X : S = M & \textrm{module definition} \\
adamc@528	418 &&& \mt{signature} \; X = S & \textrm{signature definition} \\
adamc@528	419 &&& \mt{open} \; M & \textrm{module inclusion} \\
adamc@528	420 &&& \mt{constraint} \; c \sim c & \textrm{record disjointness constraint} \\
adamc@528	421 &&& \mt{open} \; \mt{constraints} \; M & \textrm{inclusion of just the constraints from a module} \\
adamc@528	422 &&& \mt{table} \; x : c & \textrm{SQL table} \\
adamc@784	423 &&& \mt{view} \; x : c & \textrm{SQL view} \\
adamc@528	424 &&& \mt{sequence} \; x & \textrm{SQL sequence} \\
adamc@535	425 &&& \mt{cookie} \; x : \tau & \textrm{HTTP cookie} \\
adamc@784	426 &&& \mt{style} \; x : \tau & \textrm{CSS class} \\
adamc@654	427 &&& \mt{class} \; x :: \kappa = c & \textrm{concrete constructor class} \\
adamc@1085	428 &&& \mt{task} \; e = e & \textrm{recurring task} \\
adamc@528	429 \\
adamc@529	430 \textrm{Modules} & M &::=& \mt{struct} \; d^* \; \mt{end} & \textrm{constant} \\
adamc@529	431 &&& X & \textrm{variable} \\
adamc@529	432 &&& M.X & \textrm{projection} \\
adamc@529	433 &&& M(M) & \textrm{functor application} \\
adamc@529	434 &&& \mt{functor}(X : S) : S = M & \textrm{functor abstraction} \\
adamc@528	435 \end{array}$$
adamc@528	436
adamc@528	437 There are two kinds of Ur files. A file named $M\texttt{.ur}$ is an \emph{implementation file}, and it should contain a sequence of declarations $d^$. A file named $M\texttt{.urs}$ is an \emph{interface file}; it must always have a matching $M\texttt{.ur}$ and should contain a sequence of signature items $s^$. When both files are present, the overall effect is the same as a monolithic declaration $\mt{structure} \; M : \mt{sig} \; s^* \; \mt{end} = \mt{struct} \; d^* \; \mt{end}$. When no interface file is included, the overall effect is similar, with a signature for module $M$ being inferred rather than just checked against an interface.
adamc@527	438
adamc@784	439 We omit some extra possibilities in $\mt{table}$ syntax, deferring them to Section \ref{tables}.
adamc@784	440
adamc@529	441 \subsection{Shorthands}
adamc@529	442
adamc@529	443 There are a variety of derived syntactic forms that elaborate into the core syntax from the last subsection. We will present the additional forms roughly following the order in which we presented the constructs that they elaborate into.
adamc@529	444
adamc@529	445 In many contexts where record fields are expected, like in a projection $e.c$, a constant field may be written as simply $X$, rather than $\#X$.
adamc@529	446
adamc@529	447 A record type may be written $\{(c = c,)^\}$, which elaborates to $\$[(c = c,)^]$.
adamc@529	448
adamc@533	449 The notation $[c_1, \ldots, c_n]$ is shorthand for $[c_1 = (), \ldots, c_n = ()]$.
adamc@533	450
adamc@529	451 A tuple type $(\tau_1, \ldots, \tau_n)$ expands to a record type $\{1 = \tau_1, \ldots, n = \tau_n\}$, with natural numbers as field names. A tuple pattern $(p_1, \ldots, p_n)$ expands to a rigid record pattern $\{1 = p_1, \ldots, n = p_n\}$. Positive natural numbers may be used in most places where field names would be allowed.
adamc@529	452
adamc@852	453 In general, several adjacent $\lambda$ forms may be combined into one, and kind and type annotations may be omitted, in which case they are implicitly included as wildcards. More formally, for constructor-level abstractions, we can define a new non-terminal $b ::= x \mid (x :: \kappa) \mid X$ and allow composite abstractions of the form $\lambda b^+ \Rightarrow c$, elaborating into the obvious sequence of one core $\lambda$ per element of $b^+$.
adamc@529	454
adamc@529	455 For any signature item or declaration that defines some entity to be equal to $A$ with classification annotation $B$ (e.g., $\mt{val} \; x : B = A$), $B$ and the preceding colon (or similar punctuation) may be omitted, in which case it is filled in as a wildcard.
adamc@529	456
adamc@529	457 A signature item or declaration $\mt{type} \; x$ or $\mt{type} \; x = \tau$ is elaborated into $\mt{con} \; x :: \mt{Type}$ or $\mt{con} \; x :: \mt{Type} = \tau$, respectively.
adamc@529	458
adamc@654	459 A signature item or declaration $\mt{class} \; x = \lambda y \Rightarrow c$ may be abbreviated $\mt{class} \; x \; y = c$.
adamc@529	460
adamc@654	461 Handling of implicit and explicit constructor arguments may be tweaked with some prefixes to variable references. An expression $@x$ is a version of $x$ where all implicit constructor arguments have been made explicit. An expression $@@x$ achieves the same effect, additionally halting automatic resolution of type class instances and automatic proving of disjointness constraints. The default is that any prefix of a variable's type consisting only of implicit polymorphism, type class instances, and disjointness obligations is resolved automatically, with the variable treated as having the type that starts after the last implicit element, with suitable unification variables substituted. The same syntax works for variables projected out of modules and for capitalized variables (datatype constructors).
adamc@529	462
adamc@852	463 At the expression level, an analogue is available of the composite $\lambda$ form for constructors. We define the language of binders as $b ::= p \mid [x] \mid [x \; ? \; \kappa] \mid X \mid [c \sim c]$. A lone variable $[x]$ stands for an implicit constructor variable of unspecified kind. The standard value-level function binder is recovered as the type-annotated pattern form $x : \tau$. It is a compile-time error to include a pattern $p$ that does not match every value of the appropriate type.
adamc@529	464
adamc@852	465 A local $\mt{val}$ declaration may bind a pattern instead of just a plain variable. As for function arguments, only irrefutable patterns are legal.
adamc@852	466
adamc@852	467 The keyword $\mt{fun}$ is a shorthand for $\mt{val} \; \mt{rec}$ that allows arguments to be specified before the equal sign in the definition of each mutually-recursive function, as in SML. Each curried argument must follow the grammar of the $b$ non-terminal introduced two paragraphs ago. A $\mt{fun}$ declaration is elaborated into a version that adds additional $\lambda$s to the fronts of the righthand sides, as appropriate.
adamc@529	468
adamc@529	469 A signature item $\mt{functor} \; X_1 \; (X_2 : S_1) : S_2$ is elaborated into $\mt{structure} \; X_1 : \mt{functor}(X_2 : S_1) : S_2$. A declaration $\mt{functor} \; X_1 \; (X_2 : S_1) : S_2 = M$ is elaborated into $\mt{structure} \; X_1 : \mt{functor}(X_2 : S_1) : S_2 = \mt{functor}(X_2 : S_1) : S_2 = M$.
adamc@529	470
adamc@852	471 An $\mt{open} \; \mt{constraints}$ declaration is implicitly inserted for the argument of every functor at the beginning of the functor body. For every declaration of the form $\mt{structure} \; X : S = \mt{struct} \ldots \mt{end}$, an $\mt{open} \; \mt{constraints} \; X$ declaration is implicitly inserted immediately afterward.
adamc@852	472
adamc@853	473 A declaration $\mt{table} \; x : \{(c = c,)^\}$ is elaborated into $\mt{table} \; x : [(c = c,)^]$.
adamc@529	474
adamc@529	475 The syntax $\mt{where} \; \mt{type}$ is an alternate form of $\mt{where} \; \mt{con}$.
adamc@529	476
adamc@529	477 The syntax $\mt{if} \; e \; \mt{then} \; e_1 \; \mt{else} \; e_2$ expands to $\mt{case} \; e \; \mt{of} \; \mt{Basis}.\mt{True} \Rightarrow e_1 \mid \mt{Basis}.\mt{False} \Rightarrow e_2$.
adamc@529	478
adamc@529	479 There are infix operator syntaxes for a number of functions defined in the $\mt{Basis}$ module. There is $=$ for $\mt{eq}$, $\neq$ for $\mt{neq}$, $-$ for $\mt{neg}$ (as a prefix operator) and $\mt{minus}$, $+$ for $\mt{plus}$, $\times$ for $\mt{times}$, $/$ for $\mt{div}$, $\%$ for $\mt{mod}$, $<$ for $\mt{lt}$, $\leq$ for $\mt{le}$, $>$ for $\mt{gt}$, and $\geq$ for $\mt{ge}$.
adamc@529	480
adamc@784	481 A signature item $\mt{table} \; x : c$ is shorthand for $\mt{val} \; x : \mt{Basis}.\mt{sql\_table} \; c \; []$. $\mt{view} \; x : c$ is shorthand for $\mt{val} \; x : \mt{Basis}.\mt{sql\_view} \; c$, $\mt{sequence} \; x$ is short for $\mt{val} \; x : \mt{Basis}.\mt{sql\_sequence}$. $\mt{cookie} \; x : \tau$ is shorthand for $\mt{val} \; x : \mt{Basis}.\mt{http\_cookie} \; \tau$, and $\mt{style} \; x$ is shorthand for $\mt{val} \; x : \mt{Basis}.\mt{css\_class}$.
adamc@529	482
adamc@530	483
adamc@530	484 \section{Static Semantics}
adamc@530	485
adamc@530	486 In this section, we give a declarative presentation of Ur's typing rules and related judgments. Inference is the subject of the next section; here, we assume that an oracle has filled in all wildcards with concrete values.
adamc@530	487
adamc@530	488 Since there is significant mutual recursion among the judgments, we introduce them all before beginning to give rules. We use the same variety of contexts throughout this section, implicitly introducing new sorts of context entries as needed.
adamc@530	489 \begin{itemize}
adamc@655	490 \item $\Gamma \vdash \kappa$ expresses kind well-formedness.
adamc@530	491 \item $\Gamma \vdash c :: \kappa$ assigns a kind to a constructor in a context.
adamc@530	492 \item $\Gamma \vdash c \sim c$ proves the disjointness of two record constructors; that is, that they share no field names. We overload the judgment to apply to pairs of field names as well.
adamc@531	493 \item $\Gamma \vdash c \hookrightarrow C$ proves that record constructor $c$ decomposes into set $C$ of field names and record constructors.
adamc@530	494 \item $\Gamma \vdash c \equiv c$ proves the computational equivalence of two constructors. This is often called a \emph{definitional equality} in the world of type theory.
adamc@530	495 \item $\Gamma \vdash e : \tau$ is a standard typing judgment.
adamc@534	496 \item $\Gamma \vdash p \leadsto \Gamma; \tau$ combines typing of patterns with calculation of which new variables they bind.
adamc@537	497 \item $\Gamma \vdash d \leadsto \Gamma$ expresses how a declaration modifies a context. We overload this judgment to apply to sequences of declarations, as well as to signature items and sequences of signature items.
adamc@537	498 \item $\Gamma \vdash S \equiv S$ is the signature equivalence judgment.
adamc@536	499 \item $\Gamma \vdash S \leq S$ is the signature compatibility judgment. We write $\Gamma \vdash S$ as shorthand for $\Gamma \vdash S \leq S$.
adamc@530	500 \item $\Gamma \vdash M : S$ is the module signature checking judgment.
adamc@537	501 \item $\mt{proj}(M, \overline{s}, V)$ is a partial function for projecting a signature item from $\overline{s}$, given the module $M$ that we project from. $V$ may be $\mt{con} \; x$, $\mt{datatype} \; x$, $\mt{val} \; x$, $\mt{signature} \; X$, or $\mt{structure} \; X$. The parameter $M$ is needed because the projected signature item may refer to other items from $\overline{s}$.
adamc@539	502 \item $\mt{selfify}(M, \overline{s})$ adds information to signature items $\overline{s}$ to reflect the fact that we are concerned with the particular module $M$. This function is overloaded to work over individual signature items as well.
adamc@530	503 \end{itemize}
adamc@530	504
adamc@655	505
adamc@655	506 \subsection{Kind Well-Formedness}
adamc@655	507
adamc@655	508 $$\infer{\Gamma \vdash \mt{Type}}{}
adamc@655	509 \quad \infer{\Gamma \vdash \mt{Unit}}{}
adamc@655	510 \quad \infer{\Gamma \vdash \mt{Name}}{}
adamc@655	511 \quad \infer{\Gamma \vdash \kappa_1 \to \kappa_2}{
adamc@655	512 \Gamma \vdash \kappa_1
adamc@655	513 & \Gamma \vdash \kappa_2
adamc@655	514 }
adamc@655	515 \quad \infer{\Gamma \vdash \{\kappa\}}{
adamc@655	516 \Gamma \vdash \kappa
adamc@655	517 }
adamc@655	518 \quad \infer{\Gamma \vdash (\kappa_1 \times \ldots \times \kappa_n)}{
adamc@655	519 \forall i: \Gamma \vdash \kappa_i
adamc@655	520 }$$
adamc@655	521
adamc@655	522 $$\infer{\Gamma \vdash X}{
adamc@655	523 X \in \Gamma
adamc@655	524 }
adamc@655	525 \quad \infer{\Gamma \vdash X \longrightarrow \kappa}{
adamc@655	526 \Gamma, X \vdash \kappa
adamc@655	527 }$$
adamc@655	528
adamc@530	529 \subsection{Kinding}
adamc@530	530
adamc@655	531 We write $[X \mapsto \kappa_1]\kappa_2$ for capture-avoiding substitution of $\kappa_1$ for $X$ in $\kappa_2$.
adamc@655	532
adamc@530	533 $$\infer{\Gamma \vdash (c) :: \kappa :: \kappa}{
adamc@530	534 \Gamma \vdash c :: \kappa
adamc@530	535 }
adamc@530	536 \quad \infer{\Gamma \vdash x :: \kappa}{
adamc@530	537 x :: \kappa \in \Gamma
adamc@530	538 }
adamc@530	539 \quad \infer{\Gamma \vdash x :: \kappa}{
adamc@530	540 x :: \kappa = c \in \Gamma
adamc@530	541 }$$
adamc@530	542
adamc@530	543 $$\infer{\Gamma \vdash M.x :: \kappa}{
adamc@537	544 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	545 & \mt{proj}(M, \overline{s}, \mt{con} \; x) = \kappa
adamc@530	546 }
adamc@530	547 \quad \infer{\Gamma \vdash M.x :: \kappa}{
adamc@537	548 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	549 & \mt{proj}(M, \overline{s}, \mt{con} \; x) = (\kappa, c)
adamc@530	550 }$$
adamc@530	551
adamc@530	552 $$\infer{\Gamma \vdash \tau_1 \to \tau_2 :: \mt{Type}}{
adamc@530	553 \Gamma \vdash \tau_1 :: \mt{Type}
adamc@530	554 & \Gamma \vdash \tau_2 :: \mt{Type}
adamc@530	555 }
adamc@530	556 \quad \infer{\Gamma \vdash x \; ? \: \kappa \to \tau :: \mt{Type}}{
adamc@530	557 \Gamma, x :: \kappa \vdash \tau :: \mt{Type}
adamc@530	558 }
adamc@655	559 \quad \infer{\Gamma \vdash X \longrightarrow \tau :: \mt{Type}}{
adamc@655	560 \Gamma, X \vdash \tau :: \mt{Type}
adamc@655	561 }
adamc@530	562 \quad \infer{\Gamma \vdash \$c :: \mt{Type}}{
adamc@530	563 \Gamma \vdash c :: \{\mt{Type}\}
adamc@530	564 }$$
adamc@530	565
adamc@530	566 $$\infer{\Gamma \vdash c_1 \; c_2 :: \kappa_2}{
adamc@530	567 \Gamma \vdash c_1 :: \kappa_1 \to \kappa_2
adamc@530	568 & \Gamma \vdash c_2 :: \kappa_1
adamc@530	569 }
adamc@530	570 \quad \infer{\Gamma \vdash \lambda x \; :: \; \kappa_1 \Rightarrow c :: \kappa_1 \to \kappa_2}{
adamc@530	571 \Gamma, x :: \kappa_1 \vdash c :: \kappa_2
adamc@530	572 }$$
adamc@530	573
adamc@655	574 $$\infer{\Gamma \vdash c[\kappa'] :: [X \mapsto \kappa']\kappa}{
adamc@655	575 \Gamma \vdash c :: X \to \kappa
adamc@655	576 & \Gamma \vdash \kappa'
adamc@655	577 }
adamc@655	578 \quad \infer{\Gamma \vdash X \Longrightarrow c :: X \to \kappa}{
adamc@655	579 \Gamma, X \vdash c :: \kappa
adamc@655	580 }$$
adamc@655	581
adamc@530	582 $$\infer{\Gamma \vdash () :: \mt{Unit}}{}
adamc@530	583 \quad \infer{\Gamma \vdash \#X :: \mt{Name}}{}$$
adamc@530	584
adamc@530	585 $$\infer{\Gamma \vdash [\overline{c_i = c'_i}] :: \{\kappa\}}{
adamc@530	586 \forall i: \Gamma \vdash c_i : \mt{Name}
adamc@530	587 & \Gamma \vdash c'_i :: \kappa
adamc@530	588 & \forall i \neq j: \Gamma \vdash c_i \sim c_j
adamc@530	589 }
adamc@530	590 \quad \infer{\Gamma \vdash c_1 \rc c_2 :: \{\kappa\}}{
adamc@530	591 \Gamma \vdash c_1 :: \{\kappa\}
adamc@530	592 & \Gamma \vdash c_2 :: \{\kappa\}
adamc@530	593 & \Gamma \vdash c_1 \sim c_2
adamc@530	594 }$$
adamc@530	595
adamc@655	596 $$\infer{\Gamma \vdash \mt{map} :: (\kappa_1 \to \kappa_2) \to \{\kappa_1\} \to \{\kappa_2\}}{}$$
adamc@530	597
adamc@573	598 $$\infer{\Gamma \vdash (\overline c) :: (\kappa_1 \times \ldots \times \kappa_n)}{
adamc@573	599 \forall i: \Gamma \vdash c_i :: \kappa_i
adamc@530	600 }
adamc@573	601 \quad \infer{\Gamma \vdash c.i :: \kappa_i}{
adamc@573	602 \Gamma \vdash c :: (\kappa_1 \times \ldots \times \kappa_n)
adamc@530	603 }$$
adamc@530	604
adamc@655	605 $$\infer{\Gamma \vdash \lambda [c_1 \sim c_2] \Rightarrow \tau :: \mt{Type}}{
adamc@655	606 \Gamma \vdash c_1 :: \{\kappa\}
adamc@530	607 & \Gamma \vdash c_2 :: \{\kappa'\}
adamc@655	608 & \Gamma, c_1 \sim c_2 \vdash \tau :: \mt{Type}
adamc@530	609 }$$
adamc@530	610
adamc@531	611 \subsection{Record Disjointness}
adamc@531	612
adamc@531	613 $$\infer{\Gamma \vdash c_1 \sim c_2}{
adamc@558	614 \Gamma \vdash c_1 \hookrightarrow C_1
adamc@558	615 & \Gamma \vdash c_2 \hookrightarrow C_2
adamc@558	616 & \forall c'_1 \in C_1, c'_2 \in C_2: \Gamma \vdash c'_1 \sim c'_2
adamc@531	617 }
adamc@531	618 \quad \infer{\Gamma \vdash X \sim X'}{
adamc@531	619 X \neq X'
adamc@531	620 }$$
adamc@531	621
adamc@531	622 $$\infer{\Gamma \vdash c_1 \sim c_2}{
adamc@531	623 c'_1 \sim c'_2 \in \Gamma
adamc@558	624 & \Gamma \vdash c'_1 \hookrightarrow C_1
adamc@558	625 & \Gamma \vdash c'_2 \hookrightarrow C_2
adamc@558	626 & c_1 \in C_1
adamc@558	627 & c_2 \in C_2
adamc@531	628 }$$
adamc@531	629
adamc@531	630 $$\infer{\Gamma \vdash c \hookrightarrow \{c\}}{}
adamc@531	631 \quad \infer{\Gamma \vdash [\overline{c = c'}] \hookrightarrow \{\overline{c}\}}{}
adamc@531	632 \quad \infer{\Gamma \vdash c_1 \rc c_2 \hookrightarrow C_1 \cup C_2}{
adamc@531	633 \Gamma \vdash c_1 \hookrightarrow C_1
adamc@531	634 & \Gamma \vdash c_2 \hookrightarrow C_2
adamc@531	635 }
adamc@531	636 \quad \infer{\Gamma \vdash c \hookrightarrow C}{
adamc@531	637 \Gamma \vdash c \equiv c'
adamc@531	638 & \Gamma \vdash c' \hookrightarrow C
adamc@531	639 }
adamc@531	640 \quad \infer{\Gamma \vdash \mt{map} \; f \; c \hookrightarrow C}{
adamc@531	641 \Gamma \vdash c \hookrightarrow C
adamc@531	642 }$$
adamc@531	643
adamc@541	644 \subsection{\label{definitional}Definitional Equality}
adamc@532	645
adamc@655	646 We use $\mathcal C$ to stand for a one-hole context that, when filled, yields a constructor. The notation $\mathcal C[c]$ plugs $c$ into $\mathcal C$. We omit the standard definition of one-hole contexts. We write $[x \mapsto c_1]c_2$ for capture-avoiding substitution of $c_1$ for $x$ in $c_2$, with analogous notation for substituting a kind in a constructor.
adamc@532	647
adamc@532	648 $$\infer{\Gamma \vdash c \equiv c}{}
adamc@532	649 \quad \infer{\Gamma \vdash c_1 \equiv c_2}{
adamc@532	650 \Gamma \vdash c_2 \equiv c_1
adamc@532	651 }
adamc@532	652 \quad \infer{\Gamma \vdash c_1 \equiv c_3}{
adamc@532	653 \Gamma \vdash c_1 \equiv c_2
adamc@532	654 & \Gamma \vdash c_2 \equiv c_3
adamc@532	655 }
adamc@532	656 \quad \infer{\Gamma \vdash \mathcal C[c_1] \equiv \mathcal C[c_2]}{
adamc@532	657 \Gamma \vdash c_1 \equiv c_2
adamc@532	658 }$$
adamc@532	659
adamc@532	660 $$\infer{\Gamma \vdash x \equiv c}{
adamc@532	661 x :: \kappa = c \in \Gamma
adamc@532	662 }
adamc@532	663 \quad \infer{\Gamma \vdash M.x \equiv c}{
adamc@537	664 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	665 & \mt{proj}(M, \overline{s}, \mt{con} \; x) = (\kappa, c)
adamc@532	666 }
adamc@532	667 \quad \infer{\Gamma \vdash (\overline c).i \equiv c_i}{}$$
adamc@532	668
adamc@532	669 $$\infer{\Gamma \vdash (\lambda x :: \kappa \Rightarrow c) \; c' \equiv [x \mapsto c'] c}{}
adamc@655	670 \quad \infer{\Gamma \vdash (X \Longrightarrow c) [\kappa] \equiv [X \mapsto \kappa] c}{}$$
adamc@655	671
adamc@655	672 $$\infer{\Gamma \vdash c_1 \rc c_2 \equiv c_2 \rc c_1}{}
adamc@532	673 \quad \infer{\Gamma \vdash c_1 \rc (c_2 \rc c_3) \equiv (c_1 \rc c_2) \rc c_3}{}$$
adamc@532	674
adamc@532	675 $$\infer{\Gamma \vdash [] \rc c \equiv c}{}
adamc@532	676 \quad \infer{\Gamma \vdash [\overline{c_1 = c'_1}] \rc [\overline{c_2 = c'_2}] \equiv [\overline{c_1 = c'_1}, \overline{c_2 = c'_2}]}{}$$
adamc@532	677
adamc@655	678 $$\infer{\Gamma \vdash \mt{map} \; f \; [] \equiv []}{}
adamc@655	679 \quad \infer{\Gamma \vdash \mt{map} \; f \; ([c_1 = c_2] \rc c) \equiv [c_1 = f \; c_2] \rc \mt{map} \; f \; c}{}$$
adamc@532	680
adamc@532	681 $$\infer{\Gamma \vdash \mt{map} \; (\lambda x \Rightarrow x) \; c \equiv c}{}
adamc@655	682 \quad \infer{\Gamma \vdash \mt{map} \; f \; (\mt{map} \; f' \; c)
adamc@655	683 \equiv \mt{map} \; (\lambda x \Rightarrow f \; (f' \; x)) \; c}{}$$
adamc@532	684
adamc@532	685 $$\infer{\Gamma \vdash \mt{map} \; f \; (c_1 \rc c_2) \equiv \mt{map} \; f \; c_1 \rc \mt{map} \; f \; c_2}{}$$
adamc@531	686
adamc@534	687 \subsection{Expression Typing}
adamc@533	688
adamc@873	689 We assume the existence of a function $T$ assigning types to literal constants. It maps integer constants to $\mt{Basis}.\mt{int}$, float constants to $\mt{Basis}.\mt{float}$, character constants to $\mt{Basis}.\mt{char}$, and string constants to $\mt{Basis}.\mt{string}$.
adamc@533	690
adamc@533	691 We also refer to a function $\mathcal I$, such that $\mathcal I(\tau)$ ``uses an oracle'' to instantiate all constructor function arguments at the beginning of $\tau$ that are marked implicit; i.e., replace $x_1 ::: \kappa_1 \to \ldots \to x_n ::: \kappa_n \to \tau$ with $[x_1 \mapsto c_1]\ldots[x_n \mapsto c_n]\tau$, where the $c_i$s are inferred and $\tau$ does not start like $x ::: \kappa \to \tau'$.
adamc@533	692
adamc@533	693 $$\infer{\Gamma \vdash e : \tau : \tau}{
adamc@533	694 \Gamma \vdash e : \tau
adamc@533	695 }
adamc@533	696 \quad \infer{\Gamma \vdash e : \tau}{
adamc@533	697 \Gamma \vdash e : \tau'
adamc@533	698 & \Gamma \vdash \tau' \equiv \tau
adamc@533	699 }
adamc@533	700 \quad \infer{\Gamma \vdash \ell : T(\ell)}{}$$
adamc@533	701
adamc@533	702 $$\infer{\Gamma \vdash x : \mathcal I(\tau)}{
adamc@533	703 x : \tau \in \Gamma
adamc@533	704 }
adamc@533	705 \quad \infer{\Gamma \vdash M.x : \mathcal I(\tau)}{
adamc@537	706 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	707 & \mt{proj}(M, \overline{s}, \mt{val} \; x) = \tau
adamc@533	708 }
adamc@533	709 \quad \infer{\Gamma \vdash X : \mathcal I(\tau)}{
adamc@533	710 X : \tau \in \Gamma
adamc@533	711 }
adamc@533	712 \quad \infer{\Gamma \vdash M.X : \mathcal I(\tau)}{
adamc@537	713 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	714 & \mt{proj}(M, \overline{s}, \mt{val} \; X) = \tau
adamc@533	715 }$$
adamc@533	716
adamc@533	717 $$\infer{\Gamma \vdash e_1 \; e_2 : \tau_2}{
adamc@533	718 \Gamma \vdash e_1 : \tau_1 \to \tau_2
adamc@533	719 & \Gamma \vdash e_2 : \tau_1
adamc@533	720 }
adamc@533	721 \quad \infer{\Gamma \vdash \lambda x : \tau_1 \Rightarrow e : \tau_1 \to \tau_2}{
adamc@533	722 \Gamma, x : \tau_1 \vdash e : \tau_2
adamc@533	723 }$$
adamc@533	724
adamc@533	725 $$\infer{\Gamma \vdash e [c] : [x \mapsto c]\tau}{
adamc@533	726 \Gamma \vdash e : x :: \kappa \to \tau
adamc@533	727 & \Gamma \vdash c :: \kappa
adamc@533	728 }
adamc@852	729 \quad \infer{\Gamma \vdash \lambda [x \; ? \; \kappa] \Rightarrow e : x \; ? \; \kappa \to \tau}{
adamc@533	730 \Gamma, x :: \kappa \vdash e : \tau
adamc@533	731 }$$
adamc@533	732
adamc@655	733 $$\infer{\Gamma \vdash e [\kappa] : [X \mapsto \kappa]\tau}{
adamc@655	734 \Gamma \vdash e : X \longrightarrow \tau
adamc@655	735 & \Gamma \vdash \kappa
adamc@655	736 }
adamc@655	737 \quad \infer{\Gamma \vdash X \Longrightarrow e : X \longrightarrow \tau}{
adamc@655	738 \Gamma, X \vdash e : \tau
adamc@655	739 }$$
adamc@655	740
adamc@533	741 $$\infer{\Gamma \vdash \{\overline{c = e}\} : \{\overline{c : \tau}\}}{
adamc@533	742 \forall i: \Gamma \vdash c_i :: \mt{Name}
adamc@533	743 & \Gamma \vdash e_i : \tau_i
adamc@533	744 & \forall i \neq j: \Gamma \vdash c_i \sim c_j
adamc@533	745 }
adamc@533	746 \quad \infer{\Gamma \vdash e.c : \tau}{
adamc@533	747 \Gamma \vdash e : \$([c = \tau] \rc c')
adamc@533	748 }
adamc@533	749 \quad \infer{\Gamma \vdash e_1 \rc e_2 : \$(c_1 \rc c_2)}{
adamc@533	750 \Gamma \vdash e_1 : \$c_1
adamc@533	751 & \Gamma \vdash e_2 : \$c_2
adamc@573	752 & \Gamma \vdash c_1 \sim c_2
adamc@533	753 }$$
adamc@533	754
adamc@533	755 $$\infer{\Gamma \vdash e \rcut c : \$c'}{
adamc@533	756 \Gamma \vdash e : \$([c = \tau] \rc c')
adamc@533	757 }
adamc@533	758 \quad \infer{\Gamma \vdash e \rcutM c : \$c'}{
adamc@533	759 \Gamma \vdash e : \$(c \rc c')
adamc@533	760 }$$
adamc@533	761
adamc@533	762 $$\infer{\Gamma \vdash \mt{let} \; \overline{ed} \; \mt{in} \; e \; \mt{end} : \tau}{
adamc@533	763 \Gamma \vdash \overline{ed} \leadsto \Gamma'
adamc@533	764 & \Gamma' \vdash e : \tau
adamc@533	765 }
adamc@533	766 \quad \infer{\Gamma \vdash \mt{case} \; e \; \mt{of} \; \overline{p \Rightarrow e} : \tau}{
adamc@533	767 \forall i: \Gamma \vdash p_i \leadsto \Gamma_i, \tau'
adamc@533	768 & \Gamma_i \vdash e_i : \tau
adamc@533	769 }$$
adamc@533	770
adamc@573	771 $$\infer{\Gamma \vdash \lambda [c_1 \sim c_2] \Rightarrow e : \lambda [c_1 \sim c_2] \Rightarrow \tau}{
adamc@533	772 \Gamma \vdash c_1 :: \{\kappa\}
adamc@655	773 & \Gamma \vdash c_2 :: \{\kappa'\}
adamc@533	774 & \Gamma, c_1 \sim c_2 \vdash e : \tau
adamc@662	775 }
adamc@662	776 \quad \infer{\Gamma \vdash e \; ! : \tau}{
adamc@662	777 \Gamma \vdash e : [c_1 \sim c_2] \Rightarrow \tau
adamc@662	778 & \Gamma \vdash c_1 \sim c_2
adamc@533	779 }$$
adamc@533	780
adamc@534	781 \subsection{Pattern Typing}
adamc@534	782
adamc@534	783 $$\infer{\Gamma \vdash \_ \leadsto \Gamma; \tau}{}
adamc@534	784 \quad \infer{\Gamma \vdash x \leadsto \Gamma, x : \tau; \tau}{}
adamc@534	785 \quad \infer{\Gamma \vdash \ell \leadsto \Gamma; T(\ell)}{}$$
adamc@534	786
adamc@534	787 $$\infer{\Gamma \vdash X \leadsto \Gamma; \overline{[x_i \mapsto \tau'_i]}\tau}{
adamc@534	788 X : \overline{x ::: \mt{Type}} \to \tau \in \Gamma
adamc@534	789 & \textrm{$\tau$ not a function type}
adamc@534	790 }
adamc@534	791 \quad \infer{\Gamma \vdash X \; p \leadsto \Gamma'; \overline{[x_i \mapsto \tau'_i]}\tau}{
adamc@534	792 X : \overline{x ::: \mt{Type}} \to \tau'' \to \tau \in \Gamma
adamc@534	793 & \Gamma \vdash p \leadsto \Gamma'; \overline{[x_i \mapsto \tau'_i]}\tau''
adamc@534	794 }$$
adamc@534	795
adamc@534	796 $$\infer{\Gamma \vdash M.X \leadsto \Gamma; \overline{[x_i \mapsto \tau'_i]}\tau}{
adamc@537	797 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	798 & \mt{proj}(M, \overline{s}, \mt{val} \; X) = \overline{x ::: \mt{Type}} \to \tau
adamc@534	799 & \textrm{$\tau$ not a function type}
adamc@534	800 }$$
adamc@534	801
adamc@534	802 $$\infer{\Gamma \vdash M.X \; p \leadsto \Gamma'; \overline{[x_i \mapsto \tau'_i]}\tau}{
adamc@537	803 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	804 & \mt{proj}(M, \overline{s}, \mt{val} \; X) = \overline{x ::: \mt{Type}} \to \tau'' \to \tau
adamc@534	805 & \Gamma \vdash p \leadsto \Gamma'; \overline{[x_i \mapsto \tau'_i]}\tau''
adamc@534	806 }$$
adamc@534	807
adamc@534	808 $$\infer{\Gamma \vdash \{\overline{x = p}\} \leadsto \Gamma_n; \{\overline{x = \tau}\}}{
adamc@534	809 \Gamma_0 = \Gamma
adamc@534	810 & \forall i: \Gamma_i \vdash p_i \leadsto \Gamma_{i+1}; \tau_i
adamc@534	811 }
adamc@534	812 \quad \infer{\Gamma \vdash \{\overline{x = p}, \ldots\} \leadsto \Gamma_n; \$([\overline{x = \tau}] \rc c)}{
adamc@534	813 \Gamma_0 = \Gamma
adamc@534	814 & \forall i: \Gamma_i \vdash p_i \leadsto \Gamma_{i+1}; \tau_i
adamc@534	815 }$$
adamc@534	816
adamc@852	817 $$\infer{\Gamma \vdash p : \tau \leadsto \Gamma'; \tau}{
adamc@852	818 \Gamma \vdash p \leadsto \Gamma'; \tau'
adamc@852	819 & \Gamma \vdash \tau' \equiv \tau
adamc@852	820 }$$
adamc@852	821
adamc@535	822 \subsection{Declaration Typing}
adamc@535	823
adamc@535	824 We use an auxiliary judgment $\overline{y}; x; \Gamma \vdash \overline{dc} \leadsto \Gamma'$, expressing the enrichment of $\Gamma$ with the types of the datatype constructors $\overline{dc}$, when they are known to belong to datatype $x$ with type parameters $\overline{y}$.
adamc@535	825
adamc@655	826 This is the first judgment where we deal with constructor classes, for the $\mt{class}$ declaration form. We will omit their special handling in this formal specification. Section \ref{typeclasses} gives an informal description of how constructor classes influence type inference.
adamc@535	827
adamc@558	828 We presuppose the existence of a function $\mathcal O$, where $\mathcal O(M, \overline{s})$ implements the $\mt{open}$ declaration by producing a context with the appropriate entry for each available component of module $M$ with signature items $\overline{s}$. Where possible, $\mathcal O$ uses ``transparent'' entries (e.g., an abstract type $M.x$ is mapped to $x :: \mt{Type} = M.x$), so that the relationship with $M$ is maintained. A related function $\mathcal O_c$ builds a context containing the disjointness constraints found in $\overline s$.
adamc@537	829 We write $\kappa_1^n \to \kappa$ as a shorthand, where $\kappa_1^0 \to \kappa = \kappa$ and $\kappa_1^{n+1} \to \kappa_2 = \kappa_1 \to (\kappa_1^n \to \kappa_2)$. We write $\mt{len}(\overline{y})$ for the length of vector $\overline{y}$ of variables.
adamc@535	830
adamc@535	831 $$\infer{\Gamma \vdash \cdot \leadsto \Gamma}{}
adamc@535	832 \quad \infer{\Gamma \vdash d, \overline{d} \leadsto \Gamma''}{
adamc@535	833 \Gamma \vdash d \leadsto \Gamma'
adamc@535	834 & \Gamma' \vdash \overline{d} \leadsto \Gamma''
adamc@535	835 }$$
adamc@535	836
adamc@535	837 $$\infer{\Gamma \vdash \mt{con} \; x :: \kappa = c \leadsto \Gamma, x :: \kappa = c}{
adamc@535	838 \Gamma \vdash c :: \kappa
adamc@535	839 }
adamc@535	840 \quad \infer{\Gamma \vdash \mt{datatype} \; x \; \overline{y} = \overline{dc} \leadsto \Gamma'}{
adamc@535	841 \overline{y}; x; \Gamma, x :: \mt{Type}^{\mt{len}(\overline y)} \to \mt{Type} \vdash \overline{dc} \leadsto \Gamma'
adamc@535	842 }$$
adamc@535	843
adamc@535	844 $$\infer{\Gamma \vdash \mt{datatype} \; x = \mt{datatype} \; M.z \leadsto \Gamma'}{
adamc@537	845 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	846 & \mt{proj}(M, \overline{s}, \mt{datatype} \; z) = (\overline{y}, \overline{dc})
adamc@535	847 & \overline{y}; x; \Gamma, x :: \mt{Type}^{\mt{len}(\overline y)} \to \mt{Type} = M.z \vdash \overline{dc} \leadsto \Gamma'
adamc@535	848 }$$
adamc@535	849
adamc@535	850 $$\infer{\Gamma \vdash \mt{val} \; x : \tau = e \leadsto \Gamma, x : \tau}{
adamc@535	851 \Gamma \vdash e : \tau
adamc@535	852 }$$
adamc@535	853
adamc@535	854 $$\infer{\Gamma \vdash \mt{val} \; \mt{rec} \; \overline{x : \tau = e} \leadsto \Gamma, \overline{x : \tau}}{
adamc@535	855 \forall i: \Gamma, \overline{x : \tau} \vdash e_i : \tau_i
adamc@535	856 & \textrm{$e_i$ starts with an expression $\lambda$, optionally preceded by constructor and disjointness $\lambda$s}
adamc@535	857 }$$
adamc@535	858
adamc@535	859 $$\infer{\Gamma \vdash \mt{structure} \; X : S = M \leadsto \Gamma, X : S}{
adamc@535	860 \Gamma \vdash M : S
adamc@558	861 & \textrm{ $M$ not a constant or application}
adamc@535	862 }
adamc@558	863 \quad \infer{\Gamma \vdash \mt{structure} \; X : S = M \leadsto \Gamma, X : \mt{selfify}(X, \overline{s})}{
adamc@558	864 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@539	865 }$$
adamc@539	866
adamc@539	867 $$\infer{\Gamma \vdash \mt{signature} \; X = S \leadsto \Gamma, X = S}{
adamc@535	868 \Gamma \vdash S
adamc@535	869 }$$
adamc@535	870
adamc@537	871 $$\infer{\Gamma \vdash \mt{open} \; M \leadsto \Gamma, \mathcal O(M, \overline{s})}{
adamc@537	872 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@535	873 }$$
adamc@535	874
adamc@535	875 $$\infer{\Gamma \vdash \mt{constraint} \; c_1 \sim c_2 \leadsto \Gamma}{
adamc@535	876 \Gamma \vdash c_1 :: \{\kappa\}
adamc@535	877 & \Gamma \vdash c_2 :: \{\kappa\}
adamc@535	878 & \Gamma \vdash c_1 \sim c_2
adamc@535	879 }
adamc@537	880 \quad \infer{\Gamma \vdash \mt{open} \; \mt{constraints} \; M \leadsto \Gamma, \mathcal O_c(M, \overline{s})}{
adamc@537	881 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@535	882 }$$
adamc@535	883
adamc@784	884 $$\infer{\Gamma \vdash \mt{table} \; x : c \leadsto \Gamma, x : \mt{Basis}.\mt{sql\_table} \; c \; []}{
adamc@535	885 \Gamma \vdash c :: \{\mt{Type}\}
adamc@535	886 }
adamc@784	887 \quad \infer{\Gamma \vdash \mt{view} \; x : c \leadsto \Gamma, x : \mt{Basis}.\mt{sql\_view} \; c}{
adamc@784	888 \Gamma \vdash c :: \{\mt{Type}\}
adamc@784	889 }$$
adamc@784	890
adamc@784	891 $$\infer{\Gamma \vdash \mt{sequence} \; x \leadsto \Gamma, x : \mt{Basis}.\mt{sql\_sequence}}{}$$
adamc@535	892
adamc@535	893 $$\infer{\Gamma \vdash \mt{cookie} \; x : \tau \leadsto \Gamma, x : \mt{Basis}.\mt{http\_cookie} \; \tau}{
adamc@535	894 \Gamma \vdash \tau :: \mt{Type}
adamc@784	895 }
adamc@784	896 \quad \infer{\Gamma \vdash \mt{style} \; x \leadsto \Gamma, x : \mt{Basis}.\mt{css\_class}}{}$$
adamc@535	897
adamc@1085	898 $$\infer{\Gamma \vdash \mt{task} \; e_1 = e_2 \leadsto \Gamma}{
adamc@1085	899 \Gamma \vdash e_1 :: \mt{Basis}.\mt{task\_kind}
adamc@1085	900 & \Gamma \vdash e_2 :: \mt{Basis}.\mt{transaction} \; \{\}
adamc@1085	901 }$$
adamc@1085	902
adamc@784	903 $$\infer{\Gamma \vdash \mt{class} \; x :: \kappa = c \leadsto \Gamma, x :: \kappa = c}{
adamc@784	904 \Gamma \vdash c :: \kappa
adamc@535	905 }$$
adamc@535	906
adamc@535	907 $$\infer{\overline{y}; x; \Gamma \vdash \cdot \leadsto \Gamma}{}
adamc@535	908 \quad \infer{\overline{y}; x; \Gamma \vdash X \mid \overline{dc} \leadsto \Gamma', X : \overline{y ::: \mt{Type}} \to x \; \overline{y}}{
adamc@535	909 \overline{y}; x; \Gamma \vdash \overline{dc} \leadsto \Gamma'
adamc@535	910 }
adamc@535	911 \quad \infer{\overline{y}; x; \Gamma \vdash X \; \mt{of} \; \tau \mid \overline{dc} \leadsto \Gamma', X : \overline{y ::: \mt{Type}} \to \tau \to x \; \overline{y}}{
adamc@535	912 \overline{y}; x; \Gamma \vdash \overline{dc} \leadsto \Gamma'
adamc@535	913 }$$
adamc@535	914
adamc@537	915 \subsection{Signature Item Typing}
adamc@537	916
adamc@537	917 We appeal to a signature item analogue of the $\mathcal O$ function from the last subsection.
adamc@537	918
adamc@537	919 $$\infer{\Gamma \vdash \cdot \leadsto \Gamma}{}
adamc@537	920 \quad \infer{\Gamma \vdash s, \overline{s} \leadsto \Gamma''}{
adamc@537	921 \Gamma \vdash s \leadsto \Gamma'
adamc@537	922 & \Gamma' \vdash \overline{s} \leadsto \Gamma''
adamc@537	923 }$$
adamc@537	924
adamc@537	925 $$\infer{\Gamma \vdash \mt{con} \; x :: \kappa \leadsto \Gamma, x :: \kappa}{}
adamc@537	926 \quad \infer{\Gamma \vdash \mt{con} \; x :: \kappa = c \leadsto \Gamma, x :: \kappa = c}{
adamc@537	927 \Gamma \vdash c :: \kappa
adamc@537	928 }
adamc@537	929 \quad \infer{\Gamma \vdash \mt{datatype} \; x \; \overline{y} = \overline{dc} \leadsto \Gamma'}{
adamc@537	930 \overline{y}; x; \Gamma, x :: \mt{Type}^{\mt{len}(\overline y)} \to \mt{Type} \vdash \overline{dc} \leadsto \Gamma'
adamc@537	931 }$$
adamc@537	932
adamc@537	933 $$\infer{\Gamma \vdash \mt{datatype} \; x = \mt{datatype} \; M.z \leadsto \Gamma'}{
adamc@537	934 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	935 & \mt{proj}(M, \overline{s}, \mt{datatype} \; z) = (\overline{y}, \overline{dc})
adamc@537	936 & \overline{y}; x; \Gamma, x :: \mt{Type}^{\mt{len}(\overline y)} \to \mt{Type} = M.z \vdash \overline{dc} \leadsto \Gamma'
adamc@537	937 }$$
adamc@537	938
adamc@537	939 $$\infer{\Gamma \vdash \mt{val} \; x : \tau \leadsto \Gamma, x : \tau}{
adamc@537	940 \Gamma \vdash \tau :: \mt{Type}
adamc@537	941 }$$
adamc@537	942
adamc@537	943 $$\infer{\Gamma \vdash \mt{structure} \; X : S \leadsto \Gamma, X : S}{
adamc@537	944 \Gamma \vdash S
adamc@537	945 }
adamc@537	946 \quad \infer{\Gamma \vdash \mt{signature} \; X = S \leadsto \Gamma, X = S}{
adamc@537	947 \Gamma \vdash S
adamc@537	948 }$$
adamc@537	949
adamc@537	950 $$\infer{\Gamma \vdash \mt{include} \; S \leadsto \Gamma, \mathcal O(\overline{s})}{
adamc@537	951 \Gamma \vdash S
adamc@537	952 & \Gamma \vdash S \equiv \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	953 }$$
adamc@537	954
adamc@537	955 $$\infer{\Gamma \vdash \mt{constraint} \; c_1 \sim c_2 \leadsto \Gamma, c_1 \sim c_2}{
adamc@537	956 \Gamma \vdash c_1 :: \{\kappa\}
adamc@537	957 & \Gamma \vdash c_2 :: \{\kappa\}
adamc@537	958 }$$
adamc@537	959
adamc@784	960 $$\infer{\Gamma \vdash \mt{class} \; x :: \kappa = c \leadsto \Gamma, x :: \kappa = c}{
adamc@784	961 \Gamma \vdash c :: \kappa
adamc@537	962 }
adamc@784	963 \quad \infer{\Gamma \vdash \mt{class} \; x :: \kappa \leadsto \Gamma, x :: \kappa}{}$$
adamc@537	964
adamc@536	965 \subsection{Signature Compatibility}
adamc@536	966
adamc@558	967 To simplify the judgments in this section, we assume that all signatures are alpha-varied as necessary to avoid including multiple bindings for the same identifier. This is in addition to the usual alpha-variation of locally-bound variables.
adamc@537	968
adamc@537	969 We rely on a judgment $\Gamma \vdash \overline{s} \leq s'$, which expresses the occurrence in signature items $\overline{s}$ of an item compatible with $s'$. We also use a judgment $\Gamma \vdash \overline{dc} \leq \overline{dc}$, which expresses compatibility of datatype definitions.
adamc@537	970
adamc@536	971 $$\infer{\Gamma \vdash S \equiv S}{}
adamc@536	972 \quad \infer{\Gamma \vdash S_1 \equiv S_2}{
adamc@536	973 \Gamma \vdash S_2 \equiv S_1
adamc@536	974 }
adamc@536	975 \quad \infer{\Gamma \vdash X \equiv S}{
adamc@536	976 X = S \in \Gamma
adamc@536	977 }
adamc@536	978 \quad \infer{\Gamma \vdash M.X \equiv S}{
adamc@537	979 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	980 & \mt{proj}(M, \overline{s}, \mt{signature} \; X) = S
adamc@536	981 }$$
adamc@536	982
adamc@536	983 $$\infer{\Gamma \vdash S \; \mt{where} \; \mt{con} \; x = c \equiv \mt{sig} \; \overline{s^1} \; \mt{con} \; x :: \kappa = c \; \overline{s_2} \; \mt{end}}{
adamc@536	984 \Gamma \vdash S \equiv \mt{sig} \; \overline{s^1} \; \mt{con} \; x :: \kappa \; \overline{s_2} \; \mt{end}
adamc@536	985 & \Gamma \vdash c :: \kappa
adamc@537	986 }
adamc@537	987 \quad \infer{\Gamma \vdash \mt{sig} \; \overline{s^1} \; \mt{include} \; S \; \overline{s^2} \; \mt{end} \equiv \mt{sig} \; \overline{s^1} \; \overline{s} \; \overline{s^2} \; \mt{end}}{
adamc@537	988 \Gamma \vdash S \equiv \mt{sig} \; \overline{s} \; \mt{end}
adamc@536	989 }$$
adamc@536	990
adamc@536	991 $$\infer{\Gamma \vdash S_1 \leq S_2}{
adamc@536	992 \Gamma \vdash S_1 \equiv S_2
adamc@536	993 }
adamc@536	994 \quad \infer{\Gamma \vdash \mt{sig} \; \overline{s} \; \mt{end} \leq \mt{sig} \; \mt{end}}{}
adamc@537	995 \quad \infer{\Gamma \vdash \mt{sig} \; \overline{s} \; \mt{end} \leq \mt{sig} \; s' \; \overline{s'} \; \mt{end}}{
adamc@537	996 \Gamma \vdash \overline{s} \leq s'
adamc@537	997 & \Gamma \vdash s' \leadsto \Gamma'
adamc@537	998 & \Gamma' \vdash \mt{sig} \; \overline{s} \; \mt{end} \leq \mt{sig} \; \overline{s'} \; \mt{end}
adamc@537	999 }$$
adamc@537	1000
adamc@537	1001 $$\infer{\Gamma \vdash s \; \overline{s} \leq s'}{
adamc@537	1002 \Gamma \vdash s \leq s'
adamc@537	1003 }
adamc@537	1004 \quad \infer{\Gamma \vdash s \; \overline{s} \leq s'}{
adamc@537	1005 \Gamma \vdash s \leadsto \Gamma'
adamc@537	1006 & \Gamma' \vdash \overline{s} \leq s'
adamc@536	1007 }$$
adamc@536	1008
adamc@536	1009 $$\infer{\Gamma \vdash \mt{functor} (X : S_1) : S_2 \leq \mt{functor} (X : S'_1) : S'_2}{
adamc@536	1010 \Gamma \vdash S'_1 \leq S_1
adamc@536	1011 & \Gamma, X : S'_1 \vdash S_2 \leq S'_2
adamc@536	1012 }$$
adamc@536	1013
adamc@537	1014 $$\infer{\Gamma \vdash \mt{con} \; x :: \kappa \leq \mt{con} \; x :: \kappa}{}
adamc@537	1015 \quad \infer{\Gamma \vdash \mt{con} \; x :: \kappa = c \leq \mt{con} \; x :: \kappa}{}
adamc@558	1016 \quad \infer{\Gamma \vdash \mt{datatype} \; x \; \overline{y} = \overline{dc} \leq \mt{con} \; x :: \mt{Type}^{\mt{len}(\overline y)} \to \mt{Type}}{}$$
adamc@537	1017
adamc@537	1018 $$\infer{\Gamma \vdash \mt{datatype} \; x = \mt{datatype} \; M.z \leq \mt{con} \; x :: \mt{Type}^{\mt{len}(y)} \to \mt{Type}}{
adamc@537	1019 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	1020 & \mt{proj}(M, \overline{s}, \mt{datatype} \; z) = (\overline{y}, \overline{dc})
adamc@537	1021 }$$
adamc@537	1022
adamc@784	1023 $$\infer{\Gamma \vdash \mt{class} \; x :: \kappa \leq \mt{con} \; x :: \kappa}{}
adamc@784	1024 \quad \infer{\Gamma \vdash \mt{class} \; x :: \kappa = c \leq \mt{con} \; x :: \kappa}{}$$
adamc@537	1025
adamc@537	1026 $$\infer{\Gamma \vdash \mt{con} \; x :: \kappa = c_1 \leq \mt{con} \; x :: \mt{\kappa} = c_2}{
adamc@537	1027 \Gamma \vdash c_1 \equiv c_2
adamc@537	1028 }
adamc@784	1029 \quad \infer{\Gamma \vdash \mt{class} \; x :: \kappa = c_1 \leq \mt{con} \; x :: \kappa = c_2}{
adamc@537	1030 \Gamma \vdash c_1 \equiv c_2
adamc@537	1031 }$$
adamc@537	1032
adamc@537	1033 $$\infer{\Gamma \vdash \mt{datatype} \; x \; \overline{y} = \overline{dc} \leq \mt{datatype} \; x \; \overline{y} = \overline{dc'}}{
adamc@537	1034 \Gamma, \overline{y :: \mt{Type}} \vdash \overline{dc} \leq \overline{dc'}
adamc@537	1035 }$$
adamc@537	1036
adamc@537	1037 $$\infer{\Gamma \vdash \mt{datatype} \; x = \mt{datatype} \; M.z \leq \mt{datatype} \; x \; \overline{y} = \overline{dc'}}{
adamc@537	1038 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@537	1039 & \mt{proj}(M, \overline{s}, \mt{datatype} \; z) = (\overline{y}, \overline{dc})
adamc@537	1040 & \Gamma, \overline{y :: \mt{Type}} \vdash \overline{dc} \leq \overline{dc'}
adamc@537	1041 }$$
adamc@537	1042
adamc@537	1043 $$\infer{\Gamma \vdash \cdot \leq \cdot}{}
adamc@537	1044 \quad \infer{\Gamma \vdash X; \overline{dc} \leq X; \overline{dc'}}{
adamc@537	1045 \Gamma \vdash \overline{dc} \leq \overline{dc'}
adamc@537	1046 }
adamc@537	1047 \quad \infer{\Gamma \vdash X \; \mt{of} \; \tau_1; \overline{dc} \leq X \; \mt{of} \; \tau_2; \overline{dc'}}{
adamc@537	1048 \Gamma \vdash \tau_1 \equiv \tau_2
adamc@537	1049 & \Gamma \vdash \overline{dc} \leq \overline{dc'}
adamc@537	1050 }$$
adamc@537	1051
adamc@537	1052 $$\infer{\Gamma \vdash \mt{datatype} \; x = \mt{datatype} \; M.z \leq \mt{datatype} \; x = \mt{datatype} \; M'.z'}{
adamc@537	1053 \Gamma \vdash M.z \equiv M'.z'
adamc@537	1054 }$$
adamc@537	1055
adamc@537	1056 $$\infer{\Gamma \vdash \mt{val} \; x : \tau_1 \leq \mt{val} \; x : \tau_2}{
adamc@537	1057 \Gamma \vdash \tau_1 \equiv \tau_2
adamc@537	1058 }
adamc@537	1059 \quad \infer{\Gamma \vdash \mt{structure} \; X : S_1 \leq \mt{structure} \; X : S_2}{
adamc@537	1060 \Gamma \vdash S_1 \leq S_2
adamc@537	1061 }
adamc@537	1062 \quad \infer{\Gamma \vdash \mt{signature} \; X = S_1 \leq \mt{signature} \; X = S_2}{
adamc@537	1063 \Gamma \vdash S_1 \leq S_2
adamc@537	1064 & \Gamma \vdash S_2 \leq S_1
adamc@537	1065 }$$
adamc@537	1066
adamc@537	1067 $$\infer{\Gamma \vdash \mt{constraint} \; c_1 \sim c_2 \leq \mt{constraint} \; c'_1 \sim c'_2}{
adamc@537	1068 \Gamma \vdash c_1 \equiv c'_1
adamc@537	1069 & \Gamma \vdash c_2 \equiv c'_2
adamc@537	1070 }$$
adamc@537	1071
adamc@655	1072 $$\infer{\Gamma \vdash \mt{class} \; x :: \kappa \leq \mt{class} \; x :: \kappa}{}
adamc@655	1073 \quad \infer{\Gamma \vdash \mt{class} \; x :: \kappa = c \leq \mt{class} \; x :: \kappa}{}
adamc@655	1074 \quad \infer{\Gamma \vdash \mt{class} \; x :: \kappa = c_1 \leq \mt{class} \; x :: \kappa = c_2}{
adamc@537	1075 \Gamma \vdash c_1 \equiv c_2
adamc@537	1076 }$$
adamc@537	1077
adamc@538	1078 \subsection{Module Typing}
adamc@538	1079
adamc@538	1080 We use a helper function $\mt{sigOf}$, which converts declarations and sequences of declarations into their principal signature items and sequences of signature items, respectively.
adamc@538	1081
adamc@538	1082 $$\infer{\Gamma \vdash M : S}{
adamc@538	1083 \Gamma \vdash M : S'
adamc@538	1084 & \Gamma \vdash S' \leq S
adamc@538	1085 }
adamc@538	1086 \quad \infer{\Gamma \vdash \mt{struct} \; \overline{d} \; \mt{end} : \mt{sig} \; \mt{sigOf}(\overline{d}) \; \mt{end}}{
adamc@538	1087 \Gamma \vdash \overline{d} \leadsto \Gamma'
adamc@538	1088 }
adamc@538	1089 \quad \infer{\Gamma \vdash X : S}{
adamc@538	1090 X : S \in \Gamma
adamc@538	1091 }$$
adamc@538	1092
adamc@538	1093 $$\infer{\Gamma \vdash M.X : S}{
adamc@538	1094 \Gamma \vdash M : \mt{sig} \; \overline{s} \; \mt{end}
adamc@538	1095 & \mt{proj}(M, \overline{s}, \mt{structure} \; X) = S
adamc@538	1096 }$$
adamc@538	1097
adamc@538	1098 $$\infer{\Gamma \vdash M_1(M_2) : [X \mapsto M_2]S_2}{
adamc@538	1099 \Gamma \vdash M_1 : \mt{functor}(X : S_1) : S_2
adamc@538	1100 & \Gamma \vdash M_2 : S_1
adamc@538	1101 }
adamc@538	1102 \quad \infer{\Gamma \vdash \mt{functor} (X : S_1) : S_2 = M : \mt{functor} (X : S_1) : S_2}{
adamc@538	1103 \Gamma \vdash S_1
adamc@538	1104 & \Gamma, X : S_1 \vdash S_2
adamc@538	1105 & \Gamma, X : S_1 \vdash M : S_2
adamc@538	1106 }$$
adamc@538	1107
adamc@538	1108 \begin{eqnarray*}
adamc@538	1109 \mt{sigOf}(\cdot) &=& \cdot \\
adamc@538	1110 \mt{sigOf}(s \; \overline{s'}) &=& \mt{sigOf}(s) \; \mt{sigOf}(\overline{s'}) \\
adamc@538	1111 \\
adamc@538	1112 \mt{sigOf}(\mt{con} \; x :: \kappa = c) &=& \mt{con} \; x :: \kappa = c \\
adamc@538	1113 \mt{sigOf}(\mt{datatype} \; x \; \overline{y} = \overline{dc}) &=& \mt{datatype} \; x \; \overline{y} = \overline{dc} \\
adamc@538	1114 \mt{sigOf}(\mt{datatype} \; x = \mt{datatype} \; M.z) &=& \mt{datatype} \; x = \mt{datatype} \; M.z \\
adamc@538	1115 \mt{sigOf}(\mt{val} \; x : \tau = e) &=& \mt{val} \; x : \tau \\
adamc@538	1116 \mt{sigOf}(\mt{val} \; \mt{rec} \; \overline{x : \tau = e}) &=& \overline{\mt{val} \; x : \tau} \\
adamc@538	1117 \mt{sigOf}(\mt{structure} \; X : S = M) &=& \mt{structure} \; X : S \\
adamc@538	1118 \mt{sigOf}(\mt{signature} \; X = S) &=& \mt{signature} \; X = S \\
adamc@538	1119 \mt{sigOf}(\mt{open} \; M) &=& \mt{include} \; S \textrm{ (where $\Gamma \vdash M : S$)} \\
adamc@538	1120 \mt{sigOf}(\mt{constraint} \; c_1 \sim c_2) &=& \mt{constraint} \; c_1 \sim c_2 \\
adamc@538	1121 \mt{sigOf}(\mt{open} \; \mt{constraints} \; M) &=& \cdot \\
adamc@538	1122 \mt{sigOf}(\mt{table} \; x : c) &=& \mt{table} \; x : c \\
adamc@784	1123 \mt{sigOf}(\mt{view} \; x : c) &=& \mt{view} \; x : c \\
adamc@538	1124 \mt{sigOf}(\mt{sequence} \; x) &=& \mt{sequence} \; x \\
adamc@538	1125 \mt{sigOf}(\mt{cookie} \; x : \tau) &=& \mt{cookie} \; x : \tau \\
adamc@784	1126 \mt{sigOf}(\mt{style} \; x) &=& \mt{style} \; x \\
adamc@655	1127 \mt{sigOf}(\mt{class} \; x :: \kappa = c) &=& \mt{class} \; x :: \kappa = c \\
adamc@538	1128 \end{eqnarray*}
adamc@539	1129 \begin{eqnarray*}
adamc@539	1130 \mt{selfify}(M, \cdot) &=& \cdot \\
adamc@558	1131 \mt{selfify}(M, s \; \overline{s'}) &=& \mt{selfify}(M, s) \; \mt{selfify}(M, \overline{s'}) \\
adamc@539	1132 \\
adamc@539	1133 \mt{selfify}(M, \mt{con} \; x :: \kappa) &=& \mt{con} \; x :: \kappa = M.x \\
adamc@539	1134 \mt{selfify}(M, \mt{con} \; x :: \kappa = c) &=& \mt{con} \; x :: \kappa = c \\
adamc@539	1135 \mt{selfify}(M, \mt{datatype} \; x \; \overline{y} = \overline{dc}) &=& \mt{datatype} \; x \; \overline{y} = \mt{datatype} \; M.x \\
adamc@539	1136 \mt{selfify}(M, \mt{datatype} \; x = \mt{datatype} \; M'.z) &=& \mt{datatype} \; x = \mt{datatype} \; M'.z \\
adamc@539	1137 \mt{selfify}(M, \mt{val} \; x : \tau) &=& \mt{val} \; x : \tau \\
adamc@539	1138 \mt{selfify}(M, \mt{structure} \; X : S) &=& \mt{structure} \; X : \mt{selfify}(M.X, \overline{s}) \textrm{ (where $\Gamma \vdash S \equiv \mt{sig} \; \overline{s} \; \mt{end}$)} \\
adamc@539	1139 \mt{selfify}(M, \mt{signature} \; X = S) &=& \mt{signature} \; X = S \\
adamc@539	1140 \mt{selfify}(M, \mt{include} \; S) &=& \mt{include} \; S \\
adamc@539	1141 \mt{selfify}(M, \mt{constraint} \; c_1 \sim c_2) &=& \mt{constraint} \; c_1 \sim c_2 \\
adamc@655	1142 \mt{selfify}(M, \mt{class} \; x :: \kappa) &=& \mt{class} \; x :: \kappa = M.x \\
adamc@655	1143 \mt{selfify}(M, \mt{class} \; x :: \kappa = c) &=& \mt{class} \; x :: \kappa = c \\
adamc@539	1144 \end{eqnarray*}
adamc@539	1145
adamc@540	1146 \subsection{Module Projection}
adamc@540	1147
adamc@540	1148 \begin{eqnarray*}
adamc@540	1149 \mt{proj}(M, \mt{con} \; x :: \kappa \; \overline{s}, \mt{con} \; x) &=& \kappa \\
adamc@540	1150 \mt{proj}(M, \mt{con} \; x :: \kappa = c \; \overline{s}, \mt{con} \; x) &=& (\kappa, c) \\
adamc@540	1151 \mt{proj}(M, \mt{datatype} \; x \; \overline{y} = \overline{dc} \; \overline{s}, \mt{con} \; x) &=& \mt{Type}^{\mt{len}(\overline{y})} \to \mt{Type} \\
adamc@540	1152 \mt{proj}(M, \mt{datatype} \; x = \mt{datatype} \; M'.z \; \overline{s}, \mt{con} \; x) &=& (\mt{Type}^{\mt{len}(\overline{y})} \to \mt{Type}, M'.z) \textrm{ (where $\Gamma \vdash M' : \mt{sig} \; \overline{s'} \; \mt{end}$} \\
adamc@540	1153 && \textrm{and $\mt{proj}(M', \overline{s'}, \mt{datatype} \; z) = (\overline{y}, \overline{dc})$)} \\
adamc@655	1154 \mt{proj}(M, \mt{class} \; x :: \kappa \; \overline{s}, \mt{con} \; x) &=& \kappa \to \mt{Type} \\
adamc@655	1155 \mt{proj}(M, \mt{class} \; x :: \kappa = c \; \overline{s}, \mt{con} \; x) &=& (\kappa \to \mt{Type}, c) \\
adamc@540	1156 \\
adamc@540	1157 \mt{proj}(M, \mt{datatype} \; x \; \overline{y} = \overline{dc} \; \overline{s}, \mt{datatype} \; x) &=& (\overline{y}, \overline{dc}) \\
adamc@540	1158 \mt{proj}(M, \mt{datatype} \; x = \mt{datatype} \; M'.z \; \overline{s}, \mt{con} \; x) &=& \mt{proj}(M', \overline{s'}, \mt{datatype} \; z) \textrm{ (where $\Gamma \vdash M' : \mt{sig} \; \overline{s'} \; \mt{end}$)} \\
adamc@540	1159 \\
adamc@540	1160 \mt{proj}(M, \mt{val} \; x : \tau \; \overline{s}, \mt{val} \; x) &=& \tau \\
adamc@540	1161 \mt{proj}(M, \mt{datatype} \; x \; \overline{y} = \overline{dc} \; \overline{s}, \mt{val} \; X) &=& \overline{y ::: \mt{Type}} \to M.x \; \overline y \textrm{ (where $X \in \overline{dc}$)} \\
adamc@540	1162 \mt{proj}(M, \mt{datatype} \; x \; \overline{y} = \overline{dc} \; \overline{s}, \mt{val} \; X) &=& \overline{y ::: \mt{Type}} \to \tau \to M.x \; \overline y \textrm{ (where $X \; \mt{of} \; \tau \in \overline{dc}$)} \\
adamc@540	1163 \mt{proj}(M, \mt{datatype} \; x = \mt{datatype} \; M'.z, \mt{val} \; X) &=& \overline{y ::: \mt{Type}} \to M.x \; \overline y \textrm{ (where $\Gamma \vdash M' : \mt{sig} \; \overline{s'} \; \mt{end}$} \\
adamc@540	1164 && \textrm{and $\mt{proj}(M', \overline{s'}, \mt{datatype} \; z = (\overline{y}, \overline{dc})$ and $X \in \overline{dc}$)} \\
adamc@540	1165 \mt{proj}(M, \mt{datatype} \; x = \mt{datatype} \; M'.z, \mt{val} \; X) &=& \overline{y ::: \mt{Type}} \to \tau \to M.x \; \overline y \textrm{ (where $\Gamma \vdash M' : \mt{sig} \; \overline{s'} \; \mt{end}$} \\
adamc@558	1166 && \textrm{and $\mt{proj}(M', \overline{s'}, \mt{datatype} \; z = (\overline{y}, \overline{dc})$ and $X \; \mt{of} \; \tau \in \overline{dc}$)} \\
adamc@540	1167 \\
adamc@540	1168 \mt{proj}(M, \mt{structure} \; X : S \; \overline{s}, \mt{structure} \; X) &=& S \\
adamc@540	1169 \\
adamc@540	1170 \mt{proj}(M, \mt{signature} \; X = S \; \overline{s}, \mt{signature} \; X) &=& S \\
adamc@540	1171 \\
adamc@540	1172 \mt{proj}(M, \mt{con} \; x :: \kappa \; \overline{s}, V) &=& [x \mapsto M.x]\mt{proj}(M, \overline{s}, V) \\
adamc@540	1173 \mt{proj}(M, \mt{con} \; x :: \kappa = c \; \overline{s}, V) &=& [x \mapsto M.x]\mt{proj}(M, \overline{s}, V) \\
adamc@540	1174 \mt{proj}(M, \mt{datatype} \; x \; \overline{y} = \overline{dc} \; \overline{s}, V) &=& [x \mapsto M.x]\mt{proj}(M, \overline{s}, V) \\
adamc@540	1175 \mt{proj}(M, \mt{datatype} \; x = \mt{datatype} \; M'.z \; \overline{s}, V) &=& [x \mapsto M.x]\mt{proj}(M, \overline{s}, V) \\
adamc@540	1176 \mt{proj}(M, \mt{val} \; x : \tau \; \overline{s}, V) &=& \mt{proj}(M, \overline{s}, V) \\
adamc@540	1177 \mt{proj}(M, \mt{structure} \; X : S \; \overline{s}, V) &=& [X \mapsto M.X]\mt{proj}(M, \overline{s}, V) \\
adamc@540	1178 \mt{proj}(M, \mt{signature} \; X = S \; \overline{s}, V) &=& [X \mapsto M.X]\mt{proj}(M, \overline{s}, V) \\
adamc@540	1179 \mt{proj}(M, \mt{include} \; S \; \overline{s}, V) &=& \mt{proj}(M, \overline{s'} \; \overline{s}, V) \textrm{ (where $\Gamma \vdash S \equiv \mt{sig} \; \overline{s'} \; \mt{end}$)} \\
adamc@540	1180 \mt{proj}(M, \mt{constraint} \; c_1 \sim c_2 \; \overline{s}, V) &=& \mt{proj}(M, \overline{s}, V) \\
adamc@655	1181 \mt{proj}(M, \mt{class} \; x :: \kappa \; \overline{s}, V) &=& [x \mapsto M.x]\mt{proj}(M, \overline{s}, V) \\
adamc@655	1182 \mt{proj}(M, \mt{class} \; x :: \kappa = c \; \overline{s}, V) &=& [x \mapsto M.x]\mt{proj}(M, \overline{s}, V) \\
adamc@540	1183 \end{eqnarray*}
adamc@540	1184
adamc@541	1185
adamc@541	1186 \section{Type Inference}
adamc@541	1187
adamc@541	1188 The Ur/Web compiler uses \emph{heuristic type inference}, with no claims of completeness with respect to the declarative specification of the last section. The rules in use seem to work well in practice. This section summarizes those rules, to help Ur programmers predict what will work and what won't.
adamc@541	1189
adamc@541	1190 \subsection{Basic Unification}
adamc@541	1191
adamc@560	1192 Type-checkers for languages based on the Hindley-Milner type discipline, like ML and Haskell, take advantage of \emph{principal typing} properties, making complete type inference relatively straightforward. Inference algorithms are traditionally implemented using type unification variables, at various points asserting equalities between types, in the process discovering the values of type variables. The Ur/Web compiler uses the same basic strategy, but the complexity of the type system rules out easy completeness.
adamc@541	1193
adamc@656	1194 Type-checking can require evaluating recursive functional programs, thanks to the type-level $\mt{map}$ operator. When a unification variable appears in such a type, the next step of computation can be undetermined. The value of that variable might be determined later, but this would be ``too late'' for the unification problems generated at the first occurrence. This is the essential source of incompleteness.
adamc@541	1195
adamc@541	1196 Nonetheless, the unification engine tends to do reasonably well. Unlike in ML, polymorphism is never inferred in definitions; it must be indicated explicitly by writing out constructor-level parameters. By writing these and other annotations, the programmer can generally get the type inference engine to do most of the type reconstruction work.
adamc@541	1197
adamc@541	1198 \subsection{Unifying Record Types}
adamc@541	1199
adamc@570	1200 The type inference engine tries to take advantage of the algebraic rules governing type-level records, as shown in Section \ref{definitional}. When two constructors of record kind are unified, they are reduced to normal forms, with like terms crossed off from each normal form until, hopefully, nothing remains. This cannot be complete, with the inclusion of unification variables. The type-checker can help you understand what goes wrong when the process fails, as it outputs the unmatched remainders of the two normal forms.
adamc@541	1201
adamc@656	1202 \subsection{\label{typeclasses}Constructor Classes}
adamc@541	1203
adamc@784	1204 Ur includes a constructor class facility inspired by Haskell's. The current version is experimental, with very general Prolog-like facilities that can lead to compile-time non-termination.
adamc@541	1205
adamc@784	1206 Constructor classes are integrated with the module system. A constructor class of kind $\kappa$ is just a constructor of kind $\kappa$. By marking such a constructor $c$ as a constructor class, the programmer instructs the type inference engine to, in each scope, record all values of types $c \; c_1 \; \ldots \; c_n$ as \emph{instances}. Any function argument whose type is of such a form is treated as implicit, to be determined by examining the current instance database.
adamc@541	1207
adamc@656	1208 The ``dictionary encoding'' often used in Haskell implementations is made explicit in Ur. Constructor class instances are just properly-typed values, and they can also be considered as ``proofs'' of membership in the class. In some cases, it is useful to pass these proofs around explicitly. An underscore written where a proof is expected will also be inferred, if possible, from the current instance database.
adamc@541	1209
adamc@656	1210 Just as for constructors, constructors classes may be exported from modules, and they may be exported as concrete or abstract. Concrete constructor classes have their ``real'' definitions exposed, so that client code may add new instances freely. Abstract constructor classes are useful as ``predicates'' that can be used to enforce invariants, as we will see in some definitions of SQL syntax in the Ur/Web standard library.
adamc@541	1211
adamc@541	1212 \subsection{Reverse-Engineering Record Types}
adamc@541	1213
adamc@656	1214 It's useful to write Ur functions and functors that take record constructors as inputs, but these constructors can grow quite long, even though their values are often implied by other arguments. The compiler uses a simple heuristic to infer the values of unification variables that are mapped over, yielding known results. If the result is empty, we're done; if it's not empty, we replace a single unification variable with a new constructor formed from three new unification variables, as in $[\alpha = \beta] \rc \gamma$. This process can often be repeated to determine a unification variable fully.
adamc@541	1215
adamc@541	1216 \subsection{Implicit Arguments in Functor Applications}
adamc@541	1217
adamc@656	1218 Constructor, constraint, and constructor class witness members of structures may be omitted, when those structures are used in contexts where their assigned signatures imply how to fill in those missing members. This feature combines well with reverse-engineering to allow for uses of complicated meta-programming functors with little more code than would be necessary to invoke an untyped, ad-hoc code generator.
adamc@541	1219
adamc@541	1220
adamc@542	1221 \section{The Ur Standard Library}
adamc@542	1222
adamc@542	1223 The built-in parts of the Ur/Web standard library are described by the signature in \texttt{lib/basis.urs} in the distribution. A module $\mt{Basis}$ ascribing to that signature is available in the initial environment, and every program is implicitly prefixed by $\mt{open} \; \mt{Basis}$.
adamc@542	1224
adamc@542	1225 Additionally, other common functions that are definable within Ur are included in \texttt{lib/top.urs} and \texttt{lib/top.ur}. This $\mt{Top}$ module is also opened implicitly.
adamc@542	1226
adamc@542	1227 The idea behind Ur is to serve as the ideal host for embedded domain-specific languages. For now, however, the ``generic'' functionality is intermixed with Ur/Web-specific functionality, including in these two library modules. We hope that these generic library components have types that speak for themselves. The next section introduces the Ur/Web-specific elements. Here, we only give the type declarations from the beginning of $\mt{Basis}$.
adamc@542	1228 $$\begin{array}{l}
adamc@542	1229 \mt{type} \; \mt{int} \\
adamc@542	1230 \mt{type} \; \mt{float} \\
adamc@873	1231 \mt{type} \; \mt{char} \\
adamc@542	1232 \mt{type} \; \mt{string} \\
adamc@542	1233 \mt{type} \; \mt{time} \\
adamc@785	1234 \mt{type} \; \mt{blob} \\
adamc@542	1235 \\
adamc@542	1236 \mt{type} \; \mt{unit} = \{\} \\
adamc@542	1237 \\
adamc@542	1238 \mt{datatype} \; \mt{bool} = \mt{False} \mid \mt{True} \\
adamc@542	1239 \\
adamc@785	1240 \mt{datatype} \; \mt{option} \; \mt{t} = \mt{None} \mid \mt{Some} \; \mt{of} \; \mt{t} \\
adamc@785	1241 \\
adamc@785	1242 \mt{datatype} \; \mt{list} \; \mt{t} = \mt{Nil} \mid \mt{Cons} \; \mt{of} \; \mt{t} \times \mt{list} \; \mt{t}
adamc@542	1243 \end{array}$$
adamc@542	1244
adamc@785	1245 The only unusual element of this list is the $\mt{blob}$ type, which stands for binary sequences.
adamc@785	1246
adamc@657	1247 Another important generic Ur element comes at the beginning of \texttt{top.urs}.
adamc@657	1248
adamc@657	1249 $$\begin{array}{l}
adamc@657	1250 \mt{con} \; \mt{folder} :: \mt{K} \longrightarrow \{\mt{K}\} \to \mt{Type} \\
adamc@657	1251 \\
adamc@657	1252 \mt{val} \; \mt{fold} : \mt{K} \longrightarrow \mt{tf} :: (\{\mt{K}\} \to \mt{Type}) \\
adamc@657	1253 \hspace{.1in} \to (\mt{nm} :: \mt{Name} \to \mt{v} :: \mt{K} \to \mt{r} :: \{\mt{K}\} \to [[\mt{nm}] \sim \mt{r}] \Rightarrow \\
adamc@657	1254 \hspace{.2in} \mt{tf} \; \mt{r} \to \mt{tf} \; ([\mt{nm} = \mt{v}] \rc \mt{r})) \\
adamc@657	1255 \hspace{.1in} \to \mt{tf} \; [] \\
adamc@657	1256 \hspace{.1in} \to \mt{r} :: \{\mt{K}\} \to \mt{folder} \; \mt{r} \to \mt{tf} \; \mt{r}
adamc@657	1257 \end{array}$$
adamc@657	1258
adamc@657	1259 For a type-level record $\mt{r}$, a $\mt{folder} \; \mt{r}$ encodes a permutation of $\mt{r}$'s elements. The $\mt{fold}$ function can be called on a $\mt{folder}$ to iterate over the elements of $\mt{r}$ in that order. $\mt{fold}$ is parameterized on a type-level function to be used to calculate the type of each intermediate result of folding. After processing a subset $\mt{r'}$ of $\mt{r}$'s entries, the type of the accumulator should be $\mt{tf} \; \mt{r'}$. The next two expression arguments to $\mt{fold}$ are the usual step function and initial accumulator, familiar from fold functions over lists. The final two arguments are the record to fold over and a $\mt{folder}$ for it.
adamc@657	1260
adamc@664	1261 The Ur compiler treats $\mt{folder}$ like a constructor class, using built-in rules to infer $\mt{folder}$s for records with known structure. The order in which field names are mentioned in source code is used as a hint about the permutation that the programmer would like.
adamc@657	1262
adamc@542	1263
adamc@542	1264 \section{The Ur/Web Standard Library}
adamc@542	1265
adamc@658	1266 \subsection{Monads}
adamc@658	1267
adamc@658	1268 The Ur Basis defines the monad constructor class from Haskell.
adamc@658	1269
adamc@658	1270 $$\begin{array}{l}
adamc@658	1271 \mt{class} \; \mt{monad} :: \mt{Type} \to \mt{Type} \\
adamc@658	1272 \mt{val} \; \mt{return} : \mt{m} ::: (\mt{Type} \to \mt{Type}) \to \mt{t} ::: \mt{Type} \\
adamc@658	1273 \hspace{.1in} \to \mt{monad} \; \mt{m} \\
adamc@658	1274 \hspace{.1in} \to \mt{t} \to \mt{m} \; \mt{t} \\
adamc@658	1275 \mt{val} \; \mt{bind} : \mt{m} ::: (\mt{Type} \to \mt{Type}) \to \mt{t1} ::: \mt{Type} \to \mt{t2} ::: \mt{Type} \\
adamc@658	1276 \hspace{.1in} \to \mt{monad} \; \mt{m} \\
adamc@658	1277 \hspace{.1in} \to \mt{m} \; \mt{t1} \to (\mt{t1} \to \mt{m} \; \mt{t2}) \\
adamc@658	1278 \hspace{.1in} \to \mt{m} \; \mt{t2}
adamc@658	1279 \end{array}$$
adamc@658	1280
adamc@542	1281 \subsection{Transactions}
adamc@542	1282
adamc@542	1283 Ur is a pure language; we use Haskell's trick to support controlled side effects. The standard library defines a monad $\mt{transaction}$, meant to stand for actions that may be undone cleanly. By design, no other kinds of actions are supported.
adamc@542	1284 $$\begin{array}{l}
adamc@542	1285 \mt{con} \; \mt{transaction} :: \mt{Type} \to \mt{Type} \\
adamc@658	1286 \mt{val} \; \mt{transaction\_monad} : \mt{monad} \; \mt{transaction}
adamc@542	1287 \end{array}$$
adamc@542	1288
adamc@542	1289 \subsection{HTTP}
adamc@542	1290
adamc@542	1291 There are transactions for reading an HTTP header by name and for getting and setting strongly-typed cookies. Cookies may only be created by the $\mt{cookie}$ declaration form, ensuring that they be named consistently based on module structure.
adamc@542	1292 $$\begin{array}{l}
adamc@786	1293 \mt{val} \; \mt{requestHeader} : \mt{string} \to \mt{transaction} \; (\mt{option} \; \mt{string}) \\
adamc@786	1294 \\
adamc@786	1295 \mt{con} \; \mt{http\_cookie} :: \mt{Type} \to \mt{Type} \\
adamc@786	1296 \mt{val} \; \mt{getCookie} : \mt{t} ::: \mt{Type} \to \mt{http\_cookie} \; \mt{t} \to \mt{transaction} \; (\mt{option} \; \mt{t}) \\
adamc@1050	1297 \mt{val} \; \mt{setCookie} : \mt{t} ::: \mt{Type} \to \mt{http\_cookie} \; \mt{t} \to \{\mt{Value} : \mt{t}, \mt{Expires} : \mt{option} \; \mt{time}, \mt{Secure} : \mt{bool}\} \to \mt{transaction} \; \mt{unit} \\
adamc@1050	1298 \mt{val} \; \mt{clearCookie} : \mt{t} ::: \mt{Type} \to \mt{http\_cookie} \; \mt{t} \to \mt{transaction} \; \mt{unit}
adamc@786	1299 \end{array}$$
adamc@786	1300
adamc@786	1301 There are also an abstract $\mt{url}$ type and functions for converting to it, based on the policy defined by \texttt{[allow\|deny] url} directives in the project file.
adamc@786	1302 $$\begin{array}{l}
adamc@786	1303 \mt{type} \; \mt{url} \\
adamc@786	1304 \mt{val} \; \mt{bless} : \mt{string} \to \mt{url} \\
adamc@786	1305 \mt{val} \; \mt{checkUrl} : \mt{string} \to \mt{option} \; \mt{url}
adamc@786	1306 \end{array}$$
adamc@786	1307 $\mt{bless}$ raises a runtime error if the string passed to it fails the URL policy.
adamc@786	1308
adamc@1085	1309 It is possible to grab the current page's URL or to build a URL for an arbitrary transaction that would also be an acceptable value of a \texttt{link} attribute of the \texttt{a} tag.
adamc@1085	1310 $$\begin{array}{l}
adamc@1085	1311 \mt{val} \; \mt{currentUrl} : \mt{transaction} \; \mt{url} \\
adamc@1085	1312 \mt{val} \; \mt{url} : \mt{transaction} \; \mt{page} \to \mt{url}
adamc@1085	1313 \end{array}$$
adamc@1085	1314
adamc@1085	1315 Page generation may be interrupted at any time with a request to redirect to a particular URL instead.
adamc@1085	1316 $$\begin{array}{l}
adamc@1085	1317 \mt{val} \; \mt{redirect} : \mt{t} ::: \mt{Type} \to \mt{url} \to \mt{transaction} \; \mt{t}
adamc@1085	1318 \end{array}$$
adamc@1085	1319
adamc@786	1320 It's possible for pages to return files of arbitrary MIME types. A file can be input from the user using this data type, along with the $\mt{upload}$ form tag.
adamc@786	1321 $$\begin{array}{l}
adamc@786	1322 \mt{type} \; \mt{file} \\
adamc@786	1323 \mt{val} \; \mt{fileName} : \mt{file} \to \mt{option} \; \mt{string} \\
adamc@786	1324 \mt{val} \; \mt{fileMimeType} : \mt{file} \to \mt{string} \\
adamc@786	1325 \mt{val} \; \mt{fileData} : \mt{file} \to \mt{blob}
adamc@786	1326 \end{array}$$
adamc@786	1327
adamc@786	1328 A blob can be extracted from a file and returned as the page result. There are bless and check functions for MIME types analogous to those for URLs.
adamc@786	1329 $$\begin{array}{l}
adamc@786	1330 \mt{type} \; \mt{mimeType} \\
adamc@786	1331 \mt{val} \; \mt{blessMime} : \mt{string} \to \mt{mimeType} \\
adamc@786	1332 \mt{val} \; \mt{checkMime} : \mt{string} \to \mt{option} \; \mt{mimeType} \\
adamc@786	1333 \mt{val} \; \mt{returnBlob} : \mt{t} ::: \mt{Type} \to \mt{blob} \to \mt{mimeType} \to \mt{transaction} \; \mt{t}
adamc@542	1334 \end{array}$$
adamc@542	1335
adamc@543	1336 \subsection{SQL}
adamc@543	1337
adamc@543	1338 The fundamental unit of interest in the embedding of SQL is tables, described by a type family and creatable only via the $\mt{table}$ declaration form.
adamc@543	1339 $$\begin{array}{l}
adamc@785	1340 \mt{con} \; \mt{sql\_table} :: \{\mt{Type}\} \to \{\{\mt{Unit}\}\} \to \mt{Type}
adamc@785	1341 \end{array}$$
adamc@785	1342 The first argument to this constructor gives the names and types of a table's columns, and the second argument gives the set of valid keys. Keys are the only subsets of the columns that may be referenced as foreign keys. Each key has a name.
adamc@785	1343
adamc@785	1344 We also have the simpler type family of SQL views, which have no keys.
adamc@785	1345 $$\begin{array}{l}
adamc@785	1346 \mt{con} \; \mt{sql\_view} :: \{\mt{Type}\} \to \mt{Type}
adamc@543	1347 \end{array}$$
adamc@543	1348
adamc@785	1349 A multi-parameter type class is used to allow tables and views to be used interchangeably, with a way of extracting the set of columns from each.
adamc@785	1350 $$\begin{array}{l}
adamc@785	1351 \mt{class} \; \mt{fieldsOf} :: \mt{Type} \to \{\mt{Type}\} \to \mt{Type} \\
adamc@785	1352 \mt{val} \; \mt{fieldsOf\_table} : \mt{fs} ::: \{\mt{Type}\} \to \mt{keys} ::: \{\{\mt{Unit}\}\} \to \mt{fieldsOf} \; (\mt{sql\_table} \; \mt{fs} \; \mt{keys}) \; \mt{fs} \\
adamc@785	1353 \mt{val} \; \mt{fieldsOf\_view} : \mt{fs} ::: \{\mt{Type}\} \to \mt{fieldsOf} \; (\mt{sql\_view} \; \mt{fs}) \; \mt{fs}
adamc@785	1354 \end{array}$$
adamc@785	1355
adamc@785	1356 \subsubsection{Table Constraints}
adamc@785	1357
adamc@785	1358 Tables may be declared with constraints, such that database modifications that violate the constraints are blocked. A table may have at most one \texttt{PRIMARY KEY} constraint, which gives the subset of columns that will most often be used to look up individual rows in the table.
adamc@785	1359
adamc@785	1360 $$\begin{array}{l}
adamc@785	1361 \mt{con} \; \mt{primary\_key} :: \{\mt{Type}\} \to \{\{\mt{Unit}\}\} \to \mt{Type} \\
adamc@785	1362 \mt{val} \; \mt{no\_primary\_key} : \mt{fs} ::: \{\mt{Type}\} \to \mt{primary\_key} \; \mt{fs} \; [] \\
adamc@785	1363 \mt{val} \; \mt{primary\_key} : \mt{rest} ::: \{\mt{Type}\} \to \mt{t} ::: \mt{Type} \to \mt{key1} :: \mt{Name} \to \mt{keys} :: \{\mt{Type}\} \\
adamc@785	1364 \hspace{.1in} \to [[\mt{key1}] \sim \mt{keys}] \Rightarrow [[\mt{key1} = \mt{t}] \rc \mt{keys} \sim \mt{rest}] \\
adamc@785	1365 \hspace{.1in} \Rightarrow \$([\mt{key1} = \mt{sql\_injectable\_prim} \; \mt{t}] \rc \mt{map} \; \mt{sql\_injectable\_prim} \; \mt{keys}) \\
adamc@785	1366 \hspace{.1in} \to \mt{primary\_key} \; ([\mt{key1} = \mt{t}] \rc \mt{keys} \rc \mt{rest}) \; [\mt{Pkey} = [\mt{key1}] \rc \mt{map} \; (\lambda \_ \Rightarrow ()) \; \mt{keys}]
adamc@785	1367 \end{array}$$
adamc@785	1368 The type class $\mt{sql\_injectable\_prim}$ characterizes which types are allowed in SQL and are not $\mt{option}$ types. In SQL, a \texttt{PRIMARY KEY} constraint enforces after-the-fact that a column may not contain \texttt{NULL}s, but Ur/Web forces that information to be included in table types from the beginning. Thus, the only effect of this kind of constraint in Ur/Web is to enforce uniqueness of the given key within the table.
adamc@785	1369
adamc@785	1370 A type family stands for sets of named constraints of the remaining varieties.
adamc@785	1371 $$\begin{array}{l}
adamc@785	1372 \mt{con} \; \mt{sql\_constraints} :: \{\mt{Type}\} \to \{\{\mt{Unit}\}\} \to \mt{Type}
adamc@785	1373 \end{array}$$
adamc@785	1374 The first argument gives the column types of the table being constrained, and the second argument maps constraint names to the keys that they define. Constraints that don't define keys are mapped to ``empty keys.''
adamc@785	1375
adamc@785	1376 There is a type family of individual, unnamed constraints.
adamc@785	1377 $$\begin{array}{l}
adamc@785	1378 \mt{con} \; \mt{sql\_constraint} :: \{\mt{Type}\} \to \{\mt{Unit}\} \to \mt{Type}
adamc@785	1379 \end{array}$$
adamc@785	1380 The first argument is the same as above, and the second argument gives the key columns for just this constraint.
adamc@785	1381
adamc@785	1382 We have operations for assembling constraints into constraint sets.
adamc@785	1383 $$\begin{array}{l}
adamc@785	1384 \mt{val} \; \mt{no\_constraint} : \mt{fs} ::: \{\mt{Type}\} \to \mt{sql\_constraints} \; \mt{fs} \; [] \\
adamc@785	1385 \mt{val} \; \mt{one\_constraint} : \mt{fs} ::: \{\mt{Type}\} \to \mt{unique} ::: \{\mt{Unit}\} \to \mt{name} :: \mt{Name} \\
adamc@785	1386 \hspace{.1in} \to \mt{sql\_constraint} \; \mt{fs} \; \mt{unique} \to \mt{sql\_constraints} \; \mt{fs} \; [\mt{name} = \mt{unique}] \\
adamc@785	1387 \mt{val} \; \mt{join\_constraints} : \mt{fs} ::: \{\mt{Type}\} \to \mt{uniques1} ::: \{\{\mt{Unit}\}\} \to \mt{uniques2} ::: \{\{\mt{Unit}\}\} \to [\mt{uniques1} \sim \mt{uniques2}] \\
adamc@785	1388 \hspace{.1in} \Rightarrow \mt{sql\_constraints} \; \mt{fs} \; \mt{uniques1} \to \mt{sql\_constraints} \; \mt{fs} \; \mt{uniques2} \to \mt{sql\_constraints} \; \mt{fs} \; (\mt{uniques1} \rc \mt{uniques2})
adamc@785	1389 \end{array}$$
adamc@785	1390
adamc@785	1391 A \texttt{UNIQUE} constraint forces a set of columns to be a key, which means that no combination of column values may occur more than once in the table. The $\mt{unique1}$ and $\mt{unique}$ arguments are separated out only to ensure that empty \texttt{UNIQUE} constraints are rejected.
adamc@785	1392 $$\begin{array}{l}
adamc@785	1393 \mt{val} \; \mt{unique} : \mt{rest} ::: \{\mt{Type}\} \to \mt{t} ::: \mt{Type} \to \mt{unique1} :: \mt{Name} \to \mt{unique} :: \{\mt{Type}\} \\
adamc@785	1394 \hspace{.1in} \to [[\mt{unique1}] \sim \mt{unique}] \Rightarrow [[\mt{unique1} = \mt{t}] \rc \mt{unique} \sim \mt{rest}] \\
adamc@785	1395 \hspace{.1in} \Rightarrow \mt{sql\_constraint} \; ([\mt{unique1} = \mt{t}] \rc \mt{unique} \rc \mt{rest}) \; ([\mt{unique1}] \rc \mt{map} \; (\lambda \_ \Rightarrow ()) \; \mt{unique})
adamc@785	1396 \end{array}$$
adamc@785	1397
adamc@785	1398 A \texttt{FOREIGN KEY} constraint connects a set of local columns to a local or remote key, enforcing that the local columns always reference an existent row of the foreign key's table. A local column of type $\mt{t}$ may be linked to a foreign column of type $\mt{option} \; \mt{t}$, and vice versa. We formalize that notion with a type class.
adamc@785	1399 $$\begin{array}{l}
adamc@785	1400 \mt{class} \; \mt{linkable} :: \mt{Type} \to \mt{Type} \to \mt{Type} \\
adamc@785	1401 \mt{val} \; \mt{linkable\_same} : \mt{t} ::: \mt{Type} \to \mt{linkable} \; \mt{t} \; \mt{t} \\
adamc@785	1402 \mt{val} \; \mt{linkable\_from\_nullable} : \mt{t} ::: \mt{Type} \to \mt{linkable} \; (\mt{option} \; \mt{t}) \; \mt{t} \\
adamc@785	1403 \mt{val} \; \mt{linkable\_to\_nullable} : \mt{t} ::: \mt{Type} \to \mt{linkable} \; \mt{t} \; (\mt{option} \; \mt{t})
adamc@785	1404 \end{array}$$
adamc@785	1405
adamc@785	1406 The $\mt{matching}$ type family uses $\mt{linkable}$ to define when two keys match up type-wise.
adamc@785	1407 $$\begin{array}{l}
adamc@785	1408 \mt{con} \; \mt{matching} :: \{\mt{Type}\} \to \{\mt{Type}\} \to \mt{Type} \\
adamc@785	1409 \mt{val} \; \mt{mat\_nil} : \mt{matching} \; [] \; [] \\
adamc@785	1410 \mt{val} \; \mt{mat\_cons} : \mt{t1} ::: \mt{Type} \to \mt{rest1} ::: \{\mt{Type}\} \to \mt{t2} ::: \mt{Type} \to \mt{rest2} ::: \{\mt{Type}\} \to \mt{nm1} :: \mt{Name} \to \mt{nm2} :: \mt{Name} \\
adamc@785	1411 \hspace{.1in} \to [[\mt{nm1}] \sim \mt{rest1}] \Rightarrow [[\mt{nm2}] \sim \mt{rest2}] \Rightarrow \mt{linkable} \; \mt{t1} \; \mt{t2} \to \mt{matching} \; \mt{rest1} \; \mt{rest2} \\
adamc@785	1412 \hspace{.1in} \to \mt{matching} \; ([\mt{nm1} = \mt{t1}] \rc \mt{rest1}) \; ([\mt{nm2} = \mt{t2}] \rc \mt{rest2})
adamc@785	1413 \end{array}$$
adamc@785	1414
adamc@785	1415 SQL provides a number of different propagation modes for \texttt{FOREIGN KEY} constraints, governing what happens when a row containing a still-referenced foreign key value is deleted or modified to have a different key value. The argument of a propagation mode's type gives the local key type.
adamc@785	1416 $$\begin{array}{l}
adamc@785	1417 \mt{con} \; \mt{propagation\_mode} :: \{\mt{Type}\} \to \mt{Type} \\
adamc@785	1418 \mt{val} \; \mt{restrict} : \mt{fs} ::: \{\mt{Type}\} \to \mt{propagation\_mode} \; \mt{fs} \\
adamc@785	1419 \mt{val} \; \mt{cascade} : \mt{fs} ::: \{\mt{Type}\} \to \mt{propagation\_mode} \; \mt{fs} \\
adamc@785	1420 \mt{val} \; \mt{no\_action} : \mt{fs} ::: \{\mt{Type}\} \to \mt{propagation\_mode} \; \mt{fs} \\
adamc@785	1421 \mt{val} \; \mt{set\_null} : \mt{fs} ::: \{\mt{Type}\} \to \mt{propagation\_mode} \; (\mt{map} \; \mt{option} \; \mt{fs})
adamc@785	1422 \end{array}$$
adamc@785	1423
adamc@785	1424 Finally, we put these ingredient together to define the \texttt{FOREIGN KEY} constraint function.
adamc@785	1425 $$\begin{array}{l}
adamc@785	1426 \mt{val} \; \mt{foreign\_key} : \mt{mine1} ::: \mt{Name} \to \mt{t} ::: \mt{Type} \to \mt{mine} ::: \{\mt{Type}\} \to \mt{munused} ::: \{\mt{Type}\} \to \mt{foreign} ::: \{\mt{Type}\} \\
adamc@785	1427 \hspace{.1in} \to \mt{funused} ::: \{\mt{Type}\} \to \mt{nm} ::: \mt{Name} \to \mt{uniques} ::: \{\{\mt{Unit}\}\} \\
adamc@785	1428 \hspace{.1in} \to [[\mt{mine1}] \sim \mt{mine}] \Rightarrow [[\mt{mine1} = \mt{t}] \rc \mt{mine} \sim \mt{munused}] \Rightarrow [\mt{foreign} \sim \mt{funused}] \Rightarrow [[\mt{nm}] \sim \mt{uniques}] \\
adamc@785	1429 \hspace{.1in} \Rightarrow \mt{matching} \; ([\mt{mine1} = \mt{t}] \rc \mt{mine}) \; \mt{foreign} \\
adamc@785	1430 \hspace{.1in} \to \mt{sql\_table} \; (\mt{foreign} \rc \mt{funused}) \; ([\mt{nm} = \mt{map} \; (\lambda \_ \Rightarrow ()) \; \mt{foreign}] \rc \mt{uniques}) \\
adamc@785	1431 \hspace{.1in} \to \{\mt{OnDelete} : \mt{propagation\_mode} \; ([\mt{mine1} = \mt{t}] \rc \mt{mine}), \\
adamc@785	1432 \hspace{.2in} \mt{OnUpdate} : \mt{propagation\_mode} \; ([\mt{mine1} = \mt{t}] \rc \mt{mine})\} \\
adamc@785	1433 \hspace{.1in} \to \mt{sql\_constraint} \; ([\mt{mine1} = \mt{t}] \rc \mt{mine} \rc \mt{munused}) \; []
adamc@785	1434 \end{array}$$
adamc@785	1435
adamc@785	1436 The last kind of constraint is a \texttt{CHECK} constraint, which attaches a boolean invariant over a row's contents. It is defined using the $\mt{sql\_exp}$ type family, which we discuss in more detail below.
adamc@785	1437 $$\begin{array}{l}
adamc@785	1438 \mt{val} \; \mt{check} : \mt{fs} ::: \{\mt{Type}\} \to \mt{sql\_exp} \; [] \; [] \; \mt{fs} \; \mt{bool} \to \mt{sql\_constraint} \; \mt{fs} \; []
adamc@785	1439 \end{array}$$
adamc@785	1440
adamc@785	1441 Section \ref{tables} shows the expanded syntax of the $\mt{table}$ declaration and signature item that includes constraints. There is no other way to use constraints with SQL in Ur/Web.
adamc@785	1442
adamc@784	1443
adamc@543	1444 \subsubsection{Queries}
adamc@543	1445
adamc@543	1446 A final query is constructed via the $\mt{sql\_query}$ function. Constructor arguments respectively specify the table fields we select (as records mapping tables to the subsets of their fields that we choose) and the (always named) extra expressions that we select.
adamc@543	1447 $$\begin{array}{l}
adamc@543	1448 \mt{con} \; \mt{sql\_query} :: \{\{\mt{Type}\}\} \to \{\mt{Type}\} \to \mt{Type} \\
adamc@543	1449 \mt{val} \; \mt{sql\_query} : \mt{tables} ::: \{\{\mt{Type}\}\} \\
adamc@543	1450 \hspace{.1in} \to \mt{selectedFields} ::: \{\{\mt{Type}\}\} \\
adamc@543	1451 \hspace{.1in} \to \mt{selectedExps} ::: \{\mt{Type}\} \\
adamc@543	1452 \hspace{.1in} \to \{\mt{Rows} : \mt{sql\_query1} \; \mt{tables} \; \mt{selectedFields} \; \mt{selectedExps}, \\
adamc@543	1453 \hspace{.2in} \mt{OrderBy} : \mt{sql\_order\_by} \; \mt{tables} \; \mt{selectedExps}, \\
adamc@543	1454 \hspace{.2in} \mt{Limit} : \mt{sql\_limit}, \\
adamc@543	1455 \hspace{.2in} \mt{Offset} : \mt{sql\_offset}\} \\
adamc@543	1456 \hspace{.1in} \to \mt{sql\_query} \; \mt{selectedFields} \; \mt{selectedExps}
adamc@543	1457 \end{array}$$
adamc@543	1458
adamc@545	1459 Queries are used by folding over their results inside transactions.
adamc@545	1460 $$\begin{array}{l}
adamc@545	1461 \mt{val} \; \mt{query} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \lambda [\mt{tables} \sim \mt{exps}] \Rightarrow \mt{state} ::: \mt{Type} \to \mt{sql\_query} \; \mt{tables} \; \mt{exps} \\
adamc@658	1462 \hspace{.1in} \to (\$(\mt{exps} \rc \mt{map} \; (\lambda \mt{fields} :: \{\mt{Type}\} \Rightarrow \$\mt{fields}) \; \mt{tables}) \\
adamc@545	1463 \hspace{.2in} \to \mt{state} \to \mt{transaction} \; \mt{state}) \\
adamc@545	1464 \hspace{.1in} \to \mt{state} \to \mt{transaction} \; \mt{state}
adamc@545	1465 \end{array}$$
adamc@545	1466
adamc@543	1467 Most of the complexity of the query encoding is in the type $\mt{sql\_query1}$, which includes simple queries and derived queries based on relational operators. Constructor arguments respectively specify the tables we select from, the subset of fields that we keep from each table for the result rows, and the extra expressions that we select.
adamc@543	1468 $$\begin{array}{l}
adamc@543	1469 \mt{con} \; \mt{sql\_query1} :: \{\{\mt{Type}\}\} \to \{\{\mt{Type}\}\} \to \{\mt{Type}\} \to \mt{Type} \\
adamc@543	1470 \\
adamc@543	1471 \mt{type} \; \mt{sql\_relop} \\
adamc@543	1472 \mt{val} \; \mt{sql\_union} : \mt{sql\_relop} \\
adamc@543	1473 \mt{val} \; \mt{sql\_intersect} : \mt{sql\_relop} \\
adamc@543	1474 \mt{val} \; \mt{sql\_except} : \mt{sql\_relop} \\
adamc@543	1475 \mt{val} \; \mt{sql\_relop} : \mt{tables1} ::: \{\{\mt{Type}\}\} \\
adamc@543	1476 \hspace{.1in} \to \mt{tables2} ::: \{\{\mt{Type}\}\} \\
adamc@543	1477 \hspace{.1in} \to \mt{selectedFields} ::: \{\{\mt{Type}\}\} \\
adamc@543	1478 \hspace{.1in} \to \mt{selectedExps} ::: \{\mt{Type}\} \\
adamc@543	1479 \hspace{.1in} \to \mt{sql\_relop} \\
adamc@543	1480 \hspace{.1in} \to \mt{sql\_query1} \; \mt{tables1} \; \mt{selectedFields} \; \mt{selectedExps} \\
adamc@543	1481 \hspace{.1in} \to \mt{sql\_query1} \; \mt{tables2} \; \mt{selectedFields} \; \mt{selectedExps} \\
adamc@543	1482 \hspace{.1in} \to \mt{sql\_query1} \; \mt{selectedFields} \; \mt{selectedFields} \; \mt{selectedExps}
adamc@543	1483 \end{array}$$
adamc@543	1484
adamc@543	1485 $$\begin{array}{l}
adamc@543	1486 \mt{val} \; \mt{sql\_query1} : \mt{tables} ::: \{\{\mt{Type}\}\} \\
adamc@543	1487 \hspace{.1in} \to \mt{grouped} ::: \{\{\mt{Type}\}\} \\
adamc@543	1488 \hspace{.1in} \to \mt{selectedFields} ::: \{\{\mt{Type}\}\} \\
adamc@543	1489 \hspace{.1in} \to \mt{selectedExps} ::: \{\mt{Type}\} \\
adamc@1085	1490 \hspace{.1in} \to \mt{empties} :: \{\mt{Unit}\} \\
adamc@1085	1491 \hspace{.1in} \to [\mt{empties} \sim \mt{selectedFields}] \\
adamc@1085	1492 \hspace{.1in} \Rightarrow \{\mt{Distinct} : \mt{bool}, \\
adamc@994	1493 \hspace{.2in} \mt{From} : \mt{sql\_from\_items} \; \mt{tables}, \\
adamc@543	1494 \hspace{.2in} \mt{Where} : \mt{sql\_exp} \; \mt{tables} \; [] \; [] \; \mt{bool}, \\
adamc@543	1495 \hspace{.2in} \mt{GroupBy} : \mt{sql\_subset} \; \mt{tables} \; \mt{grouped}, \\
adamc@543	1496 \hspace{.2in} \mt{Having} : \mt{sql\_exp} \; \mt{grouped} \; \mt{tables} \; [] \; \mt{bool}, \\
adamc@1085	1497 \hspace{.2in} \mt{SelectFields} : \mt{sql\_subset} \; \mt{grouped} \; (\mt{map} \; (\lambda \_ \Rightarrow []) \; \mt{empties} \rc \mt{selectedFields}), \\
adamc@658	1498 \hspace{.2in} \mt {SelectExps} : \$(\mt{map} \; (\mt{sql\_exp} \; \mt{grouped} \; \mt{tables} \; []) \; \mt{selectedExps}) \} \\
adamc@543	1499 \hspace{.1in} \to \mt{sql\_query1} \; \mt{tables} \; \mt{selectedFields} \; \mt{selectedExps}
adamc@543	1500 \end{array}$$
adamc@543	1501
adamc@543	1502 To encode projection of subsets of fields in $\mt{SELECT}$ clauses, and to encode $\mt{GROUP} \; \mt{BY}$ clauses, we rely on a type family $\mt{sql\_subset}$, capturing what it means for one record of table fields to be a subset of another. The main constructor $\mt{sql\_subset}$ ``proves subset facts'' by requiring a split of a record into kept and dropped parts. The extra constructor $\mt{sql\_subset\_all}$ is a convenience for keeping all fields of a record.
adamc@543	1503 $$\begin{array}{l}
adamc@543	1504 \mt{con} \; \mt{sql\_subset} :: \{\{\mt{Type}\}\} \to \{\{\mt{Type}\}\} \to \mt{Type} \\
adamc@543	1505 \mt{val} \; \mt{sql\_subset} : \mt{keep\_drop} :: \{(\{\mt{Type}\} \times \{\mt{Type}\})\} \\
adamc@543	1506 \hspace{.1in} \to \mt{sql\_subset} \\
adamc@658	1507 \hspace{.2in} (\mt{map} \; (\lambda \mt{fields} :: (\{\mt{Type}\} \times \{\mt{Type}\}) \Rightarrow \mt{fields}.1 \rc \mt{fields}.2)\; \mt{keep\_drop}) \\
adamc@658	1508 \hspace{.2in} (\mt{map} \; (\lambda \mt{fields} :: (\{\mt{Type}\} \times \{\mt{Type}\}) \Rightarrow \mt{fields}.1) \; \mt{keep\_drop}) \\
adamc@543	1509 \mt{val} \; \mt{sql\_subset\_all} : \mt{tables} :: \{\{\mt{Type}\}\} \to \mt{sql\_subset} \; \mt{tables} \; \mt{tables}
adamc@543	1510 \end{array}$$
adamc@543	1511
adamc@560	1512 SQL expressions are used in several places, including $\mt{SELECT}$, $\mt{WHERE}$, $\mt{HAVING}$, and $\mt{ORDER} \; \mt{BY}$ clauses. They reify a fragment of the standard SQL expression language, while making it possible to inject ``native'' Ur values in some places. The arguments to the $\mt{sql\_exp}$ type family respectively give the unrestricted-availability table fields, the table fields that may only be used in arguments to aggregate functions, the available selected expressions, and the type of the expression.
adamc@543	1513 $$\begin{array}{l}
adamc@543	1514 \mt{con} \; \mt{sql\_exp} :: \{\{\mt{Type}\}\} \to \{\{\mt{Type}\}\} \to \{\mt{Type}\} \to \mt{Type} \to \mt{Type}
adamc@543	1515 \end{array}$$
adamc@543	1516
adamc@543	1517 Any field in scope may be converted to an expression.
adamc@543	1518 $$\begin{array}{l}
adamc@543	1519 \mt{val} \; \mt{sql\_field} : \mt{otherTabs} ::: \{\{\mt{Type}\}\} \to \mt{otherFields} ::: \{\mt{Type}\} \\
adamc@543	1520 \hspace{.1in} \to \mt{fieldType} ::: \mt{Type} \to \mt{agg} ::: \{\{\mt{Type}\}\} \\
adamc@543	1521 \hspace{.1in} \to \mt{exps} ::: \{\mt{Type}\} \\
adamc@543	1522 \hspace{.1in} \to \mt{tab} :: \mt{Name} \to \mt{field} :: \mt{Name} \\
adamc@543	1523 \hspace{.1in} \to \mt{sql\_exp} \; ([\mt{tab} = [\mt{field} = \mt{fieldType}] \rc \mt{otherFields}] \rc \mt{otherTabs}) \; \mt{agg} \; \mt{exps} \; \mt{fieldType}
adamc@543	1524 \end{array}$$
adamc@543	1525
adamc@544	1526 There is an analogous function for referencing named expressions.
adamc@544	1527 $$\begin{array}{l}
adamc@544	1528 \mt{val} \; \mt{sql\_exp} : \mt{tabs} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{t} ::: \mt{Type} \to \mt{rest} ::: \{\mt{Type}\} \to \mt{nm} :: \mt{Name} \\
adamc@544	1529 \hspace{.1in} \to \mt{sql\_exp} \; \mt{tabs} \; \mt{agg} \; ([\mt{nm} = \mt{t}] \rc \mt{rest}) \; \mt{t}
adamc@544	1530 \end{array}$$
adamc@544	1531
adamc@544	1532 Ur values of appropriate types may be injected into SQL expressions.
adamc@544	1533 $$\begin{array}{l}
adamc@786	1534 \mt{class} \; \mt{sql\_injectable\_prim} \\
adamc@786	1535 \mt{val} \; \mt{sql\_bool} : \mt{sql\_injectable\_prim} \; \mt{bool} \\
adamc@786	1536 \mt{val} \; \mt{sql\_int} : \mt{sql\_injectable\_prim} \; \mt{int} \\
adamc@786	1537 \mt{val} \; \mt{sql\_float} : \mt{sql\_injectable\_prim} \; \mt{float} \\
adamc@786	1538 \mt{val} \; \mt{sql\_string} : \mt{sql\_injectable\_prim} \; \mt{string} \\
adamc@786	1539 \mt{val} \; \mt{sql\_time} : \mt{sql\_injectable\_prim} \; \mt{time} \\
adamc@786	1540 \mt{val} \; \mt{sql\_blob} : \mt{sql\_injectable\_prim} \; \mt{blob} \\
adamc@786	1541 \mt{val} \; \mt{sql\_channel} : \mt{t} ::: \mt{Type} \to \mt{sql\_injectable\_prim} \; (\mt{channel} \; \mt{t}) \\
adamc@786	1542 \mt{val} \; \mt{sql\_client} : \mt{sql\_injectable\_prim} \; \mt{client} \\
adamc@786	1543 \\
adamc@544	1544 \mt{class} \; \mt{sql\_injectable} \\
adamc@786	1545 \mt{val} \; \mt{sql\_prim} : \mt{t} ::: \mt{Type} \to \mt{sql\_injectable\_prim} \; \mt{t} \to \mt{sql\_injectable} \; \mt{t} \\
adamc@786	1546 \mt{val} \; \mt{sql\_option\_prim} : \mt{t} ::: \mt{Type} \to \mt{sql\_injectable\_prim} \; \mt{t} \to \mt{sql\_injectable} \; (\mt{option} \; \mt{t}) \\
adamc@786	1547 \\
adamc@544	1548 \mt{val} \; \mt{sql\_inject} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{t} ::: \mt{Type} \to \mt{sql\_injectable} \; \mt{t} \\
adamc@544	1549 \hspace{.1in} \to \mt{t} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{t}
adamc@544	1550 \end{array}$$
adamc@544	1551
adamc@544	1552 We have the SQL nullness test, which is necessary because of the strange SQL semantics of equality in the presence of null values.
adamc@544	1553 $$\begin{array}{l}
adamc@544	1554 \mt{val} \; \mt{sql\_is\_null} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{t} ::: \mt{Type} \\
adamc@544	1555 \hspace{.1in} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; (\mt{option} \; \mt{t}) \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{bool}
adamc@544	1556 \end{array}$$
adamc@544	1557
adamc@559	1558 We have generic nullary, unary, and binary operators.
adamc@544	1559 $$\begin{array}{l}
adamc@544	1560 \mt{con} \; \mt{sql\_nfunc} :: \mt{Type} \to \mt{Type} \\
adamc@544	1561 \mt{val} \; \mt{sql\_current\_timestamp} : \mt{sql\_nfunc} \; \mt{time} \\
adamc@544	1562 \mt{val} \; \mt{sql\_nfunc} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{t} ::: \mt{Type} \\
adamc@544	1563 \hspace{.1in} \to \mt{sql\_nfunc} \; \mt{t} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{t} \\\end{array}$$
adamc@544	1564
adamc@544	1565 $$\begin{array}{l}
adamc@544	1566 \mt{con} \; \mt{sql\_unary} :: \mt{Type} \to \mt{Type} \to \mt{Type} \\
adamc@544	1567 \mt{val} \; \mt{sql\_not} : \mt{sql\_unary} \; \mt{bool} \; \mt{bool} \\
adamc@544	1568 \mt{val} \; \mt{sql\_unary} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{arg} ::: \mt{Type} \to \mt{res} ::: \mt{Type} \\
adamc@544	1569 \hspace{.1in} \to \mt{sql\_unary} \; \mt{arg} \; \mt{res} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{arg} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{res} \\
adamc@544	1570 \end{array}$$
adamc@544	1571
adamc@544	1572 $$\begin{array}{l}
adamc@544	1573 \mt{con} \; \mt{sql\_binary} :: \mt{Type} \to \mt{Type} \to \mt{Type} \to \mt{Type} \\
adamc@544	1574 \mt{val} \; \mt{sql\_and} : \mt{sql\_binary} \; \mt{bool} \; \mt{bool} \; \mt{bool} \\
adamc@544	1575 \mt{val} \; \mt{sql\_or} : \mt{sql\_binary} \; \mt{bool} \; \mt{bool} \; \mt{bool} \\
adamc@544	1576 \mt{val} \; \mt{sql\_binary} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{arg_1} ::: \mt{Type} \to \mt{arg_2} ::: \mt{Type} \to \mt{res} ::: \mt{Type} \\
adamc@544	1577 \hspace{.1in} \to \mt{sql\_binary} \; \mt{arg_1} \; \mt{arg_2} \; \mt{res} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{arg_1} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{arg_2} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{res}
adamc@544	1578 \end{array}$$
adamc@544	1579
adamc@544	1580 $$\begin{array}{l}
adamc@559	1581 \mt{class} \; \mt{sql\_arith} \\
adamc@559	1582 \mt{val} \; \mt{sql\_int\_arith} : \mt{sql\_arith} \; \mt{int} \\
adamc@559	1583 \mt{val} \; \mt{sql\_float\_arith} : \mt{sql\_arith} \; \mt{float} \\
adamc@559	1584 \mt{val} \; \mt{sql\_neg} : \mt{t} ::: \mt{Type} \to \mt{sql\_arith} \; \mt{t} \to \mt{sql\_unary} \; \mt{t} \; \mt{t} \\
adamc@559	1585 \mt{val} \; \mt{sql\_plus} : \mt{t} ::: \mt{Type} \to \mt{sql\_arith} \; \mt{t} \to \mt{sql\_binary} \; \mt{t} \; \mt{t} \; \mt{t} \\
adamc@559	1586 \mt{val} \; \mt{sql\_minus} : \mt{t} ::: \mt{Type} \to \mt{sql\_arith} \; \mt{t} \to \mt{sql\_binary} \; \mt{t} \; \mt{t} \; \mt{t} \\
adamc@559	1587 \mt{val} \; \mt{sql\_times} : \mt{t} ::: \mt{Type} \to \mt{sql\_arith} \; \mt{t} \to \mt{sql\_binary} \; \mt{t} \; \mt{t} \; \mt{t} \\
adamc@559	1588 \mt{val} \; \mt{sql\_div} : \mt{t} ::: \mt{Type} \to \mt{sql\_arith} \; \mt{t} \to \mt{sql\_binary} \; \mt{t} \; \mt{t} \; \mt{t} \\
adamc@559	1589 \mt{val} \; \mt{sql\_mod} : \mt{sql\_binary} \; \mt{int} \; \mt{int} \; \mt{int}
adamc@559	1590 \end{array}$$
adamc@544	1591
adamc@656	1592 Finally, we have aggregate functions. The $\mt{COUNT(\ast)}$ syntax is handled specially, since it takes no real argument. The other aggregate functions are placed into a general type family, using constructor classes to restrict usage to properly-typed arguments. The key aspect of the $\mt{sql\_aggregate}$ function's type is the shift of aggregate-function-only fields into unrestricted fields.
adamc@544	1593 $$\begin{array}{l}
adamc@544	1594 \mt{val} \; \mt{sql\_count} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{int}
adamc@544	1595 \end{array}$$
adamc@544	1596
adamc@544	1597 $$\begin{array}{l}
adamc@544	1598 \mt{con} \; \mt{sql\_aggregate} :: \mt{Type} \to \mt{Type} \\
adamc@544	1599 \mt{val} \; \mt{sql\_aggregate} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{agg} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{t} ::: \mt{Type} \\
adamc@544	1600 \hspace{.1in} \to \mt{sql\_aggregate} \; \mt{t} \to \mt{sql\_exp} \; \mt{agg} \; \mt{agg} \; \mt{exps} \; \mt{t} \to \mt{sql\_exp} \; \mt{tables} \; \mt{agg} \; \mt{exps} \; \mt{t}
adamc@544	1601 \end{array}$$
adamc@544	1602
adamc@544	1603 $$\begin{array}{l}
adamc@544	1604 \mt{class} \; \mt{sql\_summable} \\
adamc@544	1605 \mt{val} \; \mt{sql\_summable\_int} : \mt{sql\_summable} \; \mt{int} \\
adamc@544	1606 \mt{val} \; \mt{sql\_summable\_float} : \mt{sql\_summable} \; \mt{float} \\
adamc@544	1607 \mt{val} \; \mt{sql\_avg} : \mt{t} ::: \mt{Type} \to \mt{sql\_summable} \; \mt{t} \to \mt{sql\_aggregate} \; \mt{t} \\
adamc@544	1608 \mt{val} \; \mt{sql\_sum} : \mt{t} ::: \mt{Type} \to \mt{sql\_summable} \mt{t} \to \mt{sql\_aggregate} \; \mt{t}
adamc@544	1609 \end{array}$$
adamc@544	1610
adamc@544	1611 $$\begin{array}{l}
adamc@544	1612 \mt{class} \; \mt{sql\_maxable} \\
adamc@544	1613 \mt{val} \; \mt{sql\_maxable\_int} : \mt{sql\_maxable} \; \mt{int} \\
adamc@544	1614 \mt{val} \; \mt{sql\_maxable\_float} : \mt{sql\_maxable} \; \mt{float} \\
adamc@544	1615 \mt{val} \; \mt{sql\_maxable\_string} : \mt{sql\_maxable} \; \mt{string} \\
adamc@544	1616 \mt{val} \; \mt{sql\_maxable\_time} : \mt{sql\_maxable} \; \mt{time} \\
adamc@544	1617 \mt{val} \; \mt{sql\_max} : \mt{t} ::: \mt{Type} \to \mt{sql\_maxable} \; \mt{t} \to \mt{sql\_aggregate} \; \mt{t} \\
adamc@544	1618 \mt{val} \; \mt{sql\_min} : \mt{t} ::: \mt{Type} \to \mt{sql\_maxable} \; \mt{t} \to \mt{sql\_aggregate} \; \mt{t}
adamc@544	1619 \end{array}$$
adamc@544	1620
adamc@786	1621 \texttt{FROM} clauses are specified using a type family.
adamc@786	1622 $$\begin{array}{l}
adamc@786	1623 \mt{con} \; \mt{sql\_from\_items} :: \{\{\mt{Type}\}\} \to \mt{Type} \\
adamc@786	1624 \mt{val} \; \mt{sql\_from\_table} : \mt{t} ::: \mt{Type} \to \mt{fs} ::: \{\mt{Type}\} \to \mt{fieldsOf} \; \mt{t} \; \mt{fs} \to \mt{name} :: \mt{Name} \to \mt{t} \to \mt{sql\_from\_items} \; [\mt{name} = \mt{fs}] \\
adamc@786	1625 \mt{val} \; \mt{sql\_from\_comma} : \mt{tabs1} ::: \{\{\mt{Type}\}\} \to \mt{tabs2} ::: \{\{\mt{Type}\}\} \to [\mt{tabs1} \sim \mt{tabs2}] \\
adamc@786	1626 \hspace{.1in} \Rightarrow \mt{sql\_from\_items} \; \mt{tabs1} \to \mt{sql\_from\_items} \; \mt{tabs2} \\
adamc@786	1627 \hspace{.1in} \to \mt{sql\_from\_items} \; (\mt{tabs1} \rc \mt{tabs2}) \\
adamc@786	1628 \mt{val} \; \mt{sql\_inner\_join} : \mt{tabs1} ::: \{\{\mt{Type}\}\} \to \mt{tabs2} ::: \{\{\mt{Type}\}\} \to [\mt{tabs1} \sim \mt{tabs2}] \\
adamc@786	1629 \hspace{.1in} \Rightarrow \mt{sql\_from\_items} \; \mt{tabs1} \to \mt{sql\_from\_items} \; \mt{tabs2} \\
adamc@786	1630 \hspace{.1in} \to \mt{sql\_exp} \; (\mt{tabs1} \rc \mt{tabs2}) \; [] \; [] \; \mt{bool} \\
adamc@786	1631 \hspace{.1in} \to \mt{sql\_from\_items} \; (\mt{tabs1} \rc \mt{tabs2})
adamc@786	1632 \end{array}$$
adamc@786	1633
adamc@786	1634 Besides these basic cases, outer joins are supported, which requires a type class for turning non-$\mt{option}$ columns into $\mt{option}$ columns.
adamc@786	1635 $$\begin{array}{l}
adamc@786	1636 \mt{class} \; \mt{nullify} :: \mt{Type} \to \mt{Type} \to \mt{Type} \\
adamc@786	1637 \mt{val} \; \mt{nullify\_option} : \mt{t} ::: \mt{Type} \to \mt{nullify} \; (\mt{option} \; \mt{t}) \; (\mt{option} \; \mt{t}) \\
adamc@786	1638 \mt{val} \; \mt{nullify\_prim} : \mt{t} ::: \mt{Type} \to \mt{sql\_injectable\_prim} \; \mt{t} \to \mt{nullify} \; \mt{t} \; (\mt{option} \; \mt{t})
adamc@786	1639 \end{array}$$
adamc@786	1640
adamc@786	1641 Left, right, and full outer joins can now be expressed using functions that accept records of $\mt{nullify}$ instances. Here, we give only the type for a left join as an example.
adamc@786	1642
adamc@786	1643 $$\begin{array}{l}
adamc@786	1644 \mt{val} \; \mt{sql\_left\_join} : \mt{tabs1} ::: \{\{\mt{Type}\}\} \to \mt{tabs2} ::: \{\{(\mt{Type} \times \mt{Type})\}\} \to [\mt{tabs1} \sim \mt{tabs2}] \\
adamc@786	1645 \hspace{.1in} \Rightarrow \$(\mt{map} \; (\lambda \mt{r} \Rightarrow \$(\mt{map} \; (\lambda \mt{p} :: (\mt{Type} \times \mt{Type}) \Rightarrow \mt{nullify} \; \mt{p}.1 \; \mt{p}.2) \; \mt{r})) \; \mt{tabs2}) \\
adamc@786	1646 \hspace{.1in} \to \mt{sql\_from\_items} \; \mt{tabs1} \to \mt{sql\_from\_items} \; (\mt{map} \; (\mt{map} \; (\lambda \mt{p} :: (\mt{Type} \times \mt{Type}) \Rightarrow \mt{p}.1)) \; \mt{tabs2}) \\
adamc@786	1647 \hspace{.1in} \to \mt{sql\_exp} \; (\mt{tabs1} \rc \mt{map} \; (\mt{map} \; (\lambda \mt{p} :: (\mt{Type} \times \mt{Type}) \Rightarrow \mt{p}.1)) \; \mt{tabs2}) \; [] \; [] \; \mt{bool} \\
adamc@786	1648 \hspace{.1in} \to \mt{sql\_from\_items} \; (\mt{tabs1} \rc \mt{map} \; (\mt{map} \; (\lambda \mt{p} :: (\mt{Type} \times \mt{Type}) \Rightarrow \mt{p}.2)) \; \mt{tabs2})
adamc@786	1649 \end{array}$$
adamc@786	1650
adamc@544	1651 We wrap up the definition of query syntax with the types used in representing $\mt{ORDER} \; \mt{BY}$, $\mt{LIMIT}$, and $\mt{OFFSET}$ clauses.
adamc@544	1652 $$\begin{array}{l}
adamc@544	1653 \mt{type} \; \mt{sql\_direction} \\
adamc@544	1654 \mt{val} \; \mt{sql\_asc} : \mt{sql\_direction} \\
adamc@544	1655 \mt{val} \; \mt{sql\_desc} : \mt{sql\_direction} \\
adamc@544	1656 \\
adamc@544	1657 \mt{con} \; \mt{sql\_order\_by} :: \{\{\mt{Type}\}\} \to \{\mt{Type}\} \to \mt{Type} \\
adamc@544	1658 \mt{val} \; \mt{sql\_order\_by\_Nil} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{exps} :: \{\mt{Type}\} \to \mt{sql\_order\_by} \; \mt{tables} \; \mt{exps} \\
adamc@544	1659 \mt{val} \; \mt{sql\_order\_by\_Cons} : \mt{tables} ::: \{\{\mt{Type}\}\} \to \mt{exps} ::: \{\mt{Type}\} \to \mt{t} ::: \mt{Type} \\
adamc@544	1660 \hspace{.1in} \to \mt{sql\_exp} \; \mt{tables} \; [] \; \mt{exps} \; \mt{t} \to \mt{sql\_direction} \to \mt{sql\_order\_by} \; \mt{tables} \; \mt{exps} \to \mt{sql\_order\_by} \; \mt{tables} \; \mt{exps} \\
adamc@544	1661 \\
adamc@544	1662 \mt{type} \; \mt{sql\_limit} \\
adamc@544	1663 \mt{val} \; \mt{sql\_no\_limit} : \mt{sql\_limit} \\
adamc@544	1664 \mt{val} \; \mt{sql\_limit} : \mt{int} \to \mt{sql\_limit} \\
adamc@544	1665 \\
adamc@544	1666 \mt{type} \; \mt{sql\_offset} \\
adamc@544	1667 \mt{val} \; \mt{sql\_no\_offset} : \mt{sql\_offset} \\
adamc@544	1668 \mt{val} \; \mt{sql\_offset} : \mt{int} \to \mt{sql\_offset}
adamc@544	1669 \end{array}$$
adamc@544	1670
adamc@545	1671
adamc@545	1672 \subsubsection{DML}
adamc@545	1673
adamc@545	1674 The Ur/Web library also includes an embedding of a fragment of SQL's DML, the Data Manipulation Language, for modifying database tables. Any piece of DML may be executed in a transaction.
adamc@545	1675
adamc@545	1676 $$\begin{array}{l}
adamc@545	1677 \mt{type} \; \mt{dml} \\
adamc@545	1678 \mt{val} \; \mt{dml} : \mt{dml} \to \mt{transaction} \; \mt{unit}
adamc@545	1679 \end{array}$$
adamc@545	1680
adamc@545	1681 Properly-typed records may be used to form $\mt{INSERT}$ commands.
adamc@545	1682 $$\begin{array}{l}
adamc@545	1683 \mt{val} \; \mt{insert} : \mt{fields} ::: \{\mt{Type}\} \to \mt{sql\_table} \; \mt{fields} \\
adamc@658	1684 \hspace{.1in} \to \$(\mt{map} \; (\mt{sql\_exp} \; [] \; [] \; []) \; \mt{fields}) \to \mt{dml}
adamc@545	1685 \end{array}$$
adamc@545	1686
adamc@545	1687 An $\mt{UPDATE}$ command is formed from a choice of which table fields to leave alone and which to change, along with an expression to use to compute the new value of each changed field and a $\mt{WHERE}$ clause.
adamc@545	1688 $$\begin{array}{l}
adamc@545	1689 \mt{val} \; \mt{update} : \mt{unchanged} ::: \{\mt{Type}\} \to \mt{changed} :: \{\mt{Type}\} \to \lambda [\mt{changed} \sim \mt{unchanged}] \\
adamc@658	1690 \hspace{.1in} \Rightarrow \$(\mt{map} \; (\mt{sql\_exp} \; [\mt{T} = \mt{changed} \rc \mt{unchanged}] \; [] \; []) \; \mt{changed}) \\
adamc@545	1691 \hspace{.1in} \to \mt{sql\_table} \; (\mt{changed} \rc \mt{unchanged}) \to \mt{sql\_exp} \; [\mt{T} = \mt{changed} \rc \mt{unchanged}] \; [] \; [] \; \mt{bool} \to \mt{dml}
adamc@545	1692 \end{array}$$
adamc@545	1693
adamc@545	1694 A $\mt{DELETE}$ command is formed from a table and a $\mt{WHERE}$ clause.
adamc@545	1695 $$\begin{array}{l}
adamc@545	1696 \mt{val} \; \mt{delete} : \mt{fields} ::: \{\mt{Type}\} \to \mt{sql\_table} \; \mt{fields} \to \mt{sql\_exp} \; [\mt{T} = \mt{fields}] \; [] \; [] \; \mt{bool} \to \mt{dml}
adamc@545	1697 \end{array}$$
adamc@545	1698
adamc@546	1699 \subsubsection{Sequences}
adamc@546	1700
adamc@546	1701 SQL sequences are counters with concurrency control, often used to assign unique IDs. Ur/Web supports them via a simple interface. The only way to create a sequence is with the $\mt{sequence}$ declaration form.
adamc@546	1702
adamc@546	1703 $$\begin{array}{l}
adamc@546	1704 \mt{type} \; \mt{sql\_sequence} \\
adamc@1085	1705 \mt{val} \; \mt{nextval} : \mt{sql\_sequence} \to \mt{transaction} \; \mt{int} \\
adamc@1085	1706 \mt{val} \; \mt{setval} : \mt{sql\_sequence} \to \mt{int} \to \mt{transaction} \; \mt{unit}
adamc@546	1707 \end{array}$$
adamc@546	1708
adamc@546	1709
adamc@547	1710 \subsection{XML}
adamc@547	1711
adamc@547	1712 Ur/Web's library contains an encoding of XML syntax and semantic constraints. We make no effort to follow the standards governing XML schemas. Rather, XML fragments are viewed more as values of ML datatypes, and we only track which tags are allowed inside which other tags.
adamc@547	1713
adamc@547	1714 The basic XML type family has arguments respectively indicating the \emph{context} of a fragment, the fields that the fragment expects to be bound on entry (and their types), and the fields that the fragment will bind (and their types). Contexts are a record-based ``poor man's subtyping'' encoding, with each possible set of valid tags corresponding to a different context record. The arguments dealing with field binding are only relevant to HTML forms.
adamc@547	1715 $$\begin{array}{l}
adamc@547	1716 \mt{con} \; \mt{xml} :: \{\mt{Unit}\} \to \{\mt{Type}\} \to \{\mt{Type}\} \to \mt{Type}
adamc@547	1717 \end{array}$$
adamc@547	1718
adamc@547	1719 We also have a type family of XML tags, indexed respectively by the record of optional attributes accepted by the tag, the context in which the tag may be placed, the context required of children of the tag, which form fields the tag uses, and which fields the tag defines.
adamc@547	1720 $$\begin{array}{l}
adamc@547	1721 \mt{con} \; \mt{tag} :: \{\mt{Type}\} \to \{\mt{Unit}\} \to \{\mt{Unit}\} \to \{\mt{Type}\} \to \{\mt{Type}\} \to \mt{Type}
adamc@547	1722 \end{array}$$
adamc@547	1723
adamc@547	1724 Literal text may be injected into XML as ``CDATA.''
adamc@547	1725 $$\begin{array}{l}
adamc@547	1726 \mt{val} \; \mt{cdata} : \mt{ctx} ::: \{\mt{Unit}\} \to \mt{use} ::: \{\mt{Type}\} \to \mt{string} \to \mt{xml} \; \mt{ctx} \; \mt{use} \; []
adamc@547	1727 \end{array}$$
adamc@547	1728
adamc@547	1729 There is a function for producing an XML tree with a particular tag at its root.
adamc@547	1730 $$\begin{array}{l}
adamc@547	1731 \mt{val} \; \mt{tag} : \mt{attrsGiven} ::: \{\mt{Type}\} \to \mt{attrsAbsent} ::: \{\mt{Type}\} \to \mt{ctxOuter} ::: \{\mt{Unit}\} \to \mt{ctxInner} ::: \{\mt{Unit}\} \\
adamc@547	1732 \hspace{.1in} \to \mt{useOuter} ::: \{\mt{Type}\} \to \mt{useInner} ::: \{\mt{Type}\} \to \mt{bindOuter} ::: \{\mt{Type}\} \to \mt{bindInner} ::: \{\mt{Type}\} \\
adamc@787	1733 \hspace{.1in} \to \lambda [\mt{attrsGiven} \sim \mt{attrsAbsent}] \; [\mt{useOuter} \sim \mt{useInner}] \; [\mt{bindOuter} \sim \mt{bindInner}] \\
adamc@787	1734 \hspace{.1in} \Rightarrow \mt{option} \; \mt{css\_class} \\
adamc@787	1735 \hspace{.1in} \to \$\mt{attrsGiven} \\
adamc@547	1736 \hspace{.1in} \to \mt{tag} \; (\mt{attrsGiven} \rc \mt{attrsAbsent}) \; \mt{ctxOuter} \; \mt{ctxInner} \; \mt{useOuter} \; \mt{bindOuter} \\
adamc@547	1737 \hspace{.1in} \to \mt{xml} \; \mt{ctxInner} \; \mt{useInner} \; \mt{bindInner} \to \mt{xml} \; \mt{ctxOuter} \; (\mt{useOuter} \rc \mt{useInner}) \; (\mt{bindOuter} \rc \mt{bindInner})
adamc@547	1738 \end{array}$$
adamc@787	1739 Note that any tag may be assigned a CSS class. This is the sole way of making use of the values produced by $\mt{style}$ declarations. Ur/Web itself doesn't deal with the syntax or semantics of style sheets; they can be linked via URLs with \texttt{link} tags. However, Ur/Web does make it easy to calculate upper bounds on usage of CSS classes through program analysis.
adamc@547	1740
adamc@547	1741 Two XML fragments may be concatenated.
adamc@547	1742 $$\begin{array}{l}
adamc@547	1743 \mt{val} \; \mt{join} : \mt{ctx} ::: \{\mt{Unit}\} \to \mt{use_1} ::: \{\mt{Type}\} \to \mt{bind_1} ::: \{\mt{Type}\} \to \mt{bind_2} ::: \{\mt{Type}\} \\
adamc@547	1744 \hspace{.1in} \to \lambda [\mt{use_1} \sim \mt{bind_1}] \; [\mt{bind_1} \sim \mt{bind_2}] \\
adamc@547	1745 \hspace{.1in} \Rightarrow \mt{xml} \; \mt{ctx} \; \mt{use_1} \; \mt{bind_1} \to \mt{xml} \; \mt{ctx} \; (\mt{use_1} \rc \mt{bind_1}) \; \mt{bind_2} \to \mt{xml} \; \mt{ctx} \; \mt{use_1} \; (\mt{bind_1} \rc \mt{bind_2})
adamc@547	1746 \end{array}$$
adamc@547	1747
adamc@547	1748 Finally, any XML fragment may be updated to ``claim'' to use more form fields than it does.
adamc@547	1749 $$\begin{array}{l}
adamc@547	1750 \mt{val} \; \mt{useMore} : \mt{ctx} ::: \{\mt{Unit}\} \to \mt{use_1} ::: \{\mt{Type}\} \to \mt{use_2} ::: \{\mt{Type}\} \to \mt{bind} ::: \{\mt{Type}\} \to \lambda [\mt{use_1} \sim \mt{use_2}] \\
adamc@547	1751 \hspace{.1in} \Rightarrow \mt{xml} \; \mt{ctx} \; \mt{use_1} \; \mt{bind} \to \mt{xml} \; \mt{ctx} \; (\mt{use_1} \rc \mt{use_2}) \; \mt{bind}
adamc@547	1752 \end{array}$$
adamc@547	1753
adamc@547	1754 We will not list here the different HTML tags and related functions from the standard library. They should be easy enough to understand from the code in \texttt{basis.urs}. The set of tags in the library is not yet claimed to be complete for HTML standards.
adamc@547	1755
adamc@547	1756 One last useful function is for aborting any page generation, returning some XML as an error message. This function takes the place of some uses of a general exception mechanism.
adamc@547	1757 $$\begin{array}{l}
adamc@547	1758 \mt{val} \; \mt{error} : \mt{t} ::: \mt{Type} \to \mt{xml} \; [\mt{Body}] \; [] \; [] \to \mt{t}
adamc@547	1759 \end{array}$$
adamc@547	1760
adamc@549	1761
adamc@701	1762 \subsection{Client-Side Programming}
adamc@659	1763
adamc@701	1764 Ur/Web supports running code on web browsers, via automatic compilation to JavaScript.
adamc@701	1765
adamc@701	1766 \subsubsection{The Basics}
adamc@701	1767
adamc@701	1768 Clients can open alert dialog boxes, in the usual annoying JavaScript way.
adamc@701	1769 $$\begin{array}{l}
adamc@701	1770 \mt{val} \; \mt{alert} : \mt{string} \to \mt{transaction} \; \mt{unit}
adamc@701	1771 \end{array}$$
adamc@701	1772
adamc@701	1773 Any transaction may be run in a new thread with the $\mt{spawn}$ function.
adamc@701	1774 $$\begin{array}{l}
adamc@701	1775 \mt{val} \; \mt{spawn} : \mt{transaction} \; \mt{unit} \to \mt{transaction} \; \mt{unit}
adamc@701	1776 \end{array}$$
adamc@701	1777
adamc@701	1778 The current thread can be paused for at least a specified number of milliseconds.
adamc@701	1779 $$\begin{array}{l}
adamc@701	1780 \mt{val} \; \mt{sleep} : \mt{int} \to \mt{transaction} \; \mt{unit}
adamc@701	1781 \end{array}$$
adamc@701	1782
adamc@787	1783 A few functions are available to registers callbacks for particular error events. Respectively, they are triggered on calls to $\mt{error}$, uncaught JavaScript exceptions, failure of remote procedure calls, the severance of the connection serving asynchronous messages, or the occurrence of some other error with that connection. If no handlers are registered for a kind of error, then occurrences of that error are ignored silently.
adamc@787	1784 $$\begin{array}{l}
adamc@787	1785 \mt{val} \; \mt{onError} : (\mt{xbody} \to \mt{transaction} \; \mt{unit}) \to \mt{transaction} \; \mt{unit} \\
adamc@787	1786 \mt{val} \; \mt{onFail} : (\mt{string} \to \mt{transaction} \; \mt{unit}) \to \mt{transaction} \; \mt{unit} \\
adamc@787	1787 \mt{val} \; \mt{onConnectFail} : \mt{transaction} \; \mt{unit} \to \mt{transaction} \; \mt{unit} \\
adamc@787	1788 \mt{val} \; \mt{onDisconnect} : \mt{transaction} \; \mt{unit} \to \mt{transaction} \; \mt{unit} \\
adamc@787	1789 \mt{val} \; \mt{onServerError} : (\mt{string} \to \mt{transaction} \; \mt{unit}) \to \mt{transaction} \; \mt{unit}
adamc@787	1790 \end{array}$$
adamc@787	1791
adamc@701	1792 \subsubsection{Functional-Reactive Page Generation}
adamc@701	1793
adamc@701	1794 Most approaches to ``AJAX''-style coding involve imperative manipulation of the DOM tree representing an HTML document's structure. Ur/Web follows the \emph{functional-reactive} approach instead. Programs may allocate mutable \emph{sources} of arbitrary types, and an HTML page is effectively a pure function over the latest values of the sources. The page is not mutated directly, but rather it changes automatically as the sources are mutated.
adamc@659	1795
adamc@659	1796 $$\begin{array}{l}
adamc@659	1797 \mt{con} \; \mt{source} :: \mt{Type} \to \mt{Type} \\
adamc@659	1798 \mt{val} \; \mt{source} : \mt{t} ::: \mt{Type} \to \mt{t} \to \mt{transaction} \; (\mt{source} \; \mt{t}) \\
adamc@659	1799 \mt{val} \; \mt{set} : \mt{t} ::: \mt{Type} \to \mt{source} \; \mt{t} \to \mt{t} \to \mt{transaction} \; \mt{unit} \\
adamc@659	1800 \mt{val} \; \mt{get} : \mt{t} ::: \mt{Type} \to \mt{source} \; \mt{t} \to \mt{transaction} \; \mt{t}
adamc@659	1801 \end{array}$$
adamc@659	1802
adamc@659	1803 Pure functions over sources are represented in a monad of \emph{signals}.
adamc@659	1804
adamc@659	1805 $$\begin{array}{l}
adamc@659	1806 \mt{con} \; \mt{signal} :: \mt{Type} \to \mt{Type} \\
adamc@659	1807 \mt{val} \; \mt{signal\_monad} : \mt{monad} \; \mt{signal} \\
adamc@659	1808 \mt{val} \; \mt{signal} : \mt{t} ::: \mt{Type} \to \mt{source} \; \mt{t} \to \mt{signal} \; \mt{t}
adamc@659	1809 \end{array}$$
adamc@659	1810
adamc@659	1811 A reactive portion of an HTML page is injected with a $\mt{dyn}$ tag, which has a signal-valued attribute $\mt{Signal}$.
adamc@659	1812
adamc@659	1813 $$\begin{array}{l}
adamc@701	1814 \mt{val} \; \mt{dyn} : \mt{use} ::: \{\mt{Type}\} \to \mt{bind} ::: \{\mt{Type}\} \to \mt{unit} \\
adamc@701	1815 \hspace{.1in} \to \mt{tag} \; [\mt{Signal} = \mt{signal} \; (\mt{xml} \; \mt{body} \; \mt{use} \; \mt{bind})] \; \mt{body} \; [] \; \mt{use} \; \mt{bind}
adamc@659	1816 \end{array}$$
adamc@659	1817
adamc@701	1818 Transactions can be run on the client by including them in attributes like the $\mt{Onclick}$ attribute of $\mt{button}$, and GUI widgets like $\mt{ctextbox}$ have $\mt{Source}$ attributes that can be used to connect them to sources, so that their values can be read by code running because of, e.g., an $\mt{Onclick}$ event.
adamc@701	1819
adamc@914	1820 \subsubsection{Remote Procedure Calls}
adamc@914	1821
adamc@914	1822 Any function call may be made a client-to-server ``remote procedure call'' if the function being called needs no features that are only available to client code. To make a function call an RPC, pass that function call as the argument to $\mt{Basis.rpc}$:
adamc@914	1823
adamc@914	1824 $$\begin{array}{l}
adamc@914	1825 \mt{val} \; \mt{rpc} : \mt{t} ::: \mt{Type} \to \mt{transaction} \; \mt{t} \to \mt{transaction} \; \mt{t}
adamc@914	1826 \end{array}$$
adamc@914	1827
adamc@701	1828 \subsubsection{Asynchronous Message-Passing}
adamc@701	1829
adamc@701	1830 To support asynchronous, ``server push'' delivery of messages to clients, any client that might need to receive an asynchronous message is assigned a unique ID. These IDs may be retrieved both on the client and on the server, during execution of code related to a client.
adamc@701	1831
adamc@701	1832 $$\begin{array}{l}
adamc@701	1833 \mt{type} \; \mt{client} \\
adamc@701	1834 \mt{val} \; \mt{self} : \mt{transaction} \; \mt{client}
adamc@701	1835 \end{array}$$
adamc@701	1836
adamc@701	1837 \emph{Channels} are the means of message-passing. Each channel is created in the context of a client and belongs to that client; no other client may receive the channel's messages. Each channel type includes the type of values that may be sent over the channel. Sending and receiving are asynchronous, in the sense that a client need not be ready to receive a message right away. Rather, sent messages may queue up, waiting to be processed.
adamc@701	1838
adamc@701	1839 $$\begin{array}{l}
adamc@701	1840 \mt{con} \; \mt{channel} :: \mt{Type} \to \mt{Type} \\
adamc@701	1841 \mt{val} \; \mt{channel} : \mt{t} ::: \mt{Type} \to \mt{transaction} \; (\mt{channel} \; \mt{t}) \\
adamc@701	1842 \mt{val} \; \mt{send} : \mt{t} ::: \mt{Type} \to \mt{channel} \; \mt{t} \to \mt{t} \to \mt{transaction} \; \mt{unit} \\
adamc@701	1843 \mt{val} \; \mt{recv} : \mt{t} ::: \mt{Type} \to \mt{channel} \; \mt{t} \to \mt{transaction} \; \mt{t}
adamc@701	1844 \end{array}$$
adamc@701	1845
adamc@701	1846 The $\mt{channel}$ and $\mt{send}$ operations may only be executed on the server, and $\mt{recv}$ may only be executed on a client. Neither clients nor channels may be passed as arguments from clients to server-side functions, so persistent channels can only be maintained by storing them in the database and looking them up using the current client ID or some application-specific value as a key.
adamc@701	1847
adamc@701	1848 Clients and channels live only as long as the web browser page views that they are associated with. When a user surfs away, his client and its channels will be garbage-collected, after that user is not heard from for the timeout period. Garbage collection deletes any database row that contains a client or channel directly. Any reference to one of these types inside an $\mt{option}$ is set to $\mt{None}$ instead. Both kinds of handling have the flavor of weak pointers, and that is a useful way to think about clients and channels in the database.
adamc@701	1849
adamc@659	1850
adamc@549	1851 \section{Ur/Web Syntax Extensions}
adamc@549	1852
adamc@549	1853 Ur/Web features some syntactic shorthands for building values using the functions from the last section. This section sketches the grammar of those extensions. We write spans of syntax inside brackets to indicate that they are optional.
adamc@549	1854
adamc@549	1855 \subsection{SQL}
adamc@549	1856
adamc@786	1857 \subsubsection{\label{tables}Table Declarations}
adamc@786	1858
adamc@788	1859 $\mt{table}$ declarations may include constraints, via these grammar rules.
adamc@788	1860 $$\begin{array}{rrcll}
adamc@788	1861 \textrm{Declarations} & d &::=& \mt{table} \; x : c \; [pk[,]] \; cts \\
adamc@788	1862 \textrm{Primary key constraints} & pk &::=& \mt{PRIMARY} \; \mt{KEY} \; K \\
adamc@788	1863 \textrm{Keys} & K &::=& f \mid (f, (f,)^+) \\
adamc@788	1864 \textrm{Constraint sets} & cts &::=& \mt{CONSTRAINT} f \; ct \mid cts, cts \mid \{\{e\}\} \\
adamc@788	1865 \textrm{Constraints} & ct &::=& \mt{UNIQUE} \; K \mid \mt{CHECK} \; E \\
adamc@788	1866 &&& \mid \mt{FOREIGN} \; \mt{KEY} \; K \; \mt{REFERENCES} \; F \; (K) \; [\mt{ON} \; \mt{DELETE} \; pr] \; [\mt{ON} \; \mt{UPDATE} \; pr] \\
adamc@788	1867 \textrm{Foreign tables} & F &::=& x \mid \{\{e\}\} \\
adamc@788	1868 \textrm{Propagation modes} & pr &::=& \mt{NO} \; \mt{ACTION} \mid \mt{RESTRICT} \mid \mt{CASCADE} \mid \mt{SET} \; \mt{NULL}
adamc@788	1869 \end{array}$$
adamc@788	1870
adamc@788	1871 A signature item $\mt{table} \; \mt{x} : \mt{c}$ is actually elaborated into two signature items: $\mt{con} \; \mt{x\_hidden\_constraints} :: \{\{\mt{Unit}\}\}$ and $\mt{val} \; \mt{x} : \mt{sql\_table} \; \mt{c} \; \mt{x\_hidden\_constraints}$. This is appropriate for common cases where client code doesn't care which keys a table has. It's also possible to include constraints after a $\mt{table}$ signature item, with the same syntax as for $\mt{table}$ declarations. This may look like dependent typing, but it's just a convenience. The constraints are type-checked to determine a constructor $u$ to include in $\mt{val} \; \mt{x} : \mt{sql\_table} \; \mt{c} \; (u \rc \mt{x\_hidden\_constraints})$, and then the expressions are thrown away. Nonetheless, it can be useful for documentation purposes to include table constraint details in signatures. Note that the automatic generation of $\mt{x\_hidden\_constraints}$ leads to a kind of free subtyping with respect to which constraints are defined.
adamc@788	1872
adamc@788	1873
adamc@549	1874 \subsubsection{Queries}
adamc@549	1875
adamc@550	1876 Queries $Q$ are added to the rules for expressions $e$.
adamc@550	1877
adamc@549	1878 $$\begin{array}{rrcll}
adamc@550	1879 \textrm{Queries} & Q &::=& (q \; [\mt{ORDER} \; \mt{BY} \; (E \; [o],)^+] \; [\mt{LIMIT} \; N] \; [\mt{OFFSET} \; N]) \\
adamc@1085	1880 \textrm{Pre-queries} & q &::=& \mt{SELECT} \; [\mt{DISTINCT}] \; P \; \mt{FROM} \; F,^+ \; [\mt{WHERE} \; E] \; [\mt{GROUP} \; \mt{BY} \; p,^+] \; [\mt{HAVING} \; E] \\
adamc@1085	1881 &&& \mid q \; R \; q \mid \{\{\{e\}\}\} \\
adamc@549	1882 \textrm{Relational operators} & R &::=& \mt{UNION} \mid \mt{INTERSECT} \mid \mt{EXCEPT}
adamc@549	1883 \end{array}$$
adamc@549	1884
adamc@549	1885 $$\begin{array}{rrcll}
adamc@549	1886 \textrm{Projections} & P &::=& \ast & \textrm{all columns} \\
adamc@549	1887 &&& p,^+ & \textrm{particular columns} \\
adamc@549	1888 \textrm{Pre-projections} & p &::=& t.f & \textrm{one column from a table} \\
adamc@558	1889 &&& t.\{\{c\}\} & \textrm{a record of columns from a table (of kind $\{\mt{Type}\}$)} \\
adamc@549	1890 \textrm{Table names} & t &::=& x & \textrm{constant table name (automatically capitalized)} \\
adamc@549	1891 &&& X & \textrm{constant table name} \\
adamc@549	1892 &&& \{\{c\}\} & \textrm{computed table name (of kind $\mt{Name}$)} \\
adamc@549	1893 \textrm{Column names} & f &::=& X & \textrm{constant column name} \\
adamc@549	1894 &&& \{c\} & \textrm{computed column name (of kind $\mt{Name}$)} \\
adamc@549	1895 \textrm{Tables} & T &::=& x & \textrm{table variable, named locally by its own capitalization} \\
adamc@549	1896 &&& x \; \mt{AS} \; t & \textrm{table variable, with local name} \\
adamc@549	1897 &&& \{\{e\}\} \; \mt{AS} \; t & \textrm{computed table expression, with local name} \\
adamc@1085	1898 \textrm{$\mt{FROM}$ items} & F &::=& T \mid \{\{e\}\} \mid F \; J \; \mt{JOIN} \; F \; \mt{ON} \; E \\
adamc@1085	1899 &&& \mid F \; \mt{CROSS} \; \mt{JOIN} \ F \\
adamc@1085	1900 \textrm{Joins} & J &::=& [\mt{INNER}] \\
adamc@1085	1901 &&& \mid [\mt{LEFT} \mid \mt{RIGHT} \mid \mt{FULL}] \; [\mt{OUTER}] \\
adamc@549	1902 \textrm{SQL expressions} & E &::=& p & \textrm{column references} \\
adamc@549	1903 &&& X & \textrm{named expression references} \\
adamc@549	1904 &&& \{\{e\}\} & \textrm{injected native Ur expressions} \\
adamc@549	1905 &&& \{e\} & \textrm{computed expressions, probably using $\mt{sql\_exp}$ directly} \\
adamc@549	1906 &&& \mt{TRUE} \mid \mt{FALSE} & \textrm{boolean constants} \\
adamc@549	1907 &&& \ell & \textrm{primitive type literals} \\
adamc@549	1908 &&& \mt{NULL} & \textrm{null value (injection of $\mt{None}$)} \\
adamc@549	1909 &&& E \; \mt{IS} \; \mt{NULL} & \textrm{nullness test} \\
adamc@549	1910 &&& n & \textrm{nullary operators} \\
adamc@549	1911 &&& u \; E & \textrm{unary operators} \\
adamc@549	1912 &&& E \; b \; E & \textrm{binary operators} \\
adamc@549	1913 &&& \mt{COUNT}(\ast) & \textrm{count number of rows} \\
adamc@549	1914 &&& a(E) & \textrm{other aggregate function} \\
adamc@549	1915 &&& (E) & \textrm{explicit precedence} \\
adamc@549	1916 \textrm{Nullary operators} & n &::=& \mt{CURRENT\_TIMESTAMP} \\
adamc@549	1917 \textrm{Unary operators} & u &::=& \mt{NOT} \\
adamc@549	1918 \textrm{Binary operators} & b &::=& \mt{AND} \mid \mt{OR} \mid \neq \mid < \mid \leq \mid > \mid \geq \\
adamc@549	1919 \textrm{Aggregate functions} & a &::=& \mt{AVG} \mid \mt{SUM} \mid \mt{MIN} \mid \mt{MAX} \\
adamc@550	1920 \textrm{Directions} & o &::=& \mt{ASC} \mid \mt{DESC} \\
adamc@549	1921 \textrm{SQL integer} & N &::=& n \mid \{e\} \\
adamc@549	1922 \end{array}$$
adamc@549	1923
adamc@1085	1924 Additionally, an SQL expression may be inserted into normal Ur code with the syntax $(\mt{SQL} \; E)$ or $(\mt{WHERE} \; E)$. Similar shorthands exist for other nonterminals, with the prefix $\mt{FROM}$ for $\mt{FROM}$ items and $\mt{SELECT1}$ for pre-queries.
adamc@549	1925
adamc@550	1926 \subsubsection{DML}
adamc@550	1927
adamc@550	1928 DML commands $D$ are added to the rules for expressions $e$.
adamc@550	1929
adamc@550	1930 $$\begin{array}{rrcll}
adamc@550	1931 \textrm{Commands} & D &::=& (\mt{INSERT} \; \mt{INTO} \; T^E \; (f,^+) \; \mt{VALUES} \; (E,^+)) \\
adamc@550	1932 &&& (\mt{UPDATE} \; T^E \; \mt{SET} \; (f = E,)^+ \; \mt{WHERE} \; E) \\
adamc@550	1933 &&& (\mt{DELETE} \; \mt{FROM} \; T^E \; \mt{WHERE} \; E) \\
adamc@550	1934 \textrm{Table expressions} & T^E &::=& x \mid \{\{e\}\}
adamc@550	1935 \end{array}$$
adamc@550	1936
adamc@550	1937 Inside $\mt{UPDATE}$ and $\mt{DELETE}$ commands, lone variables $X$ are interpreted as references to columns of the implicit table $\mt{T}$, rather than to named expressions.
adamc@549	1938
adamc@551	1939 \subsection{XML}
adamc@551	1940
adamc@551	1941 XML fragments $L$ are added to the rules for expressions $e$.
adamc@551	1942
adamc@551	1943 $$\begin{array}{rrcll}
adamc@551	1944 \textrm{XML fragments} & L &::=& \texttt{<xml/>} \mid \texttt{<xml>}l^*\texttt{</xml>} \\
adamc@551	1945 \textrm{XML pieces} & l &::=& \textrm{text} & \textrm{cdata} \\
adamc@551	1946 &&& \texttt{<}g\texttt{/>} & \textrm{tag with no children} \\
adamc@551	1947 &&& \texttt{<}g\texttt{>}l^*\texttt{</}x\texttt{>} & \textrm{tag with children} \\
adamc@559	1948 &&& \{e\} & \textrm{computed XML fragment} \\
adamc@559	1949 &&& \{[e]\} & \textrm{injection of an Ur expression, via the $\mt{Top}.\mt{txt}$ function} \\
adamc@551	1950 \textrm{Tag} & g &::=& h \; (x = v)^* \\
adamc@551	1951 \textrm{Tag head} & h &::=& x & \textrm{tag name} \\
adamc@551	1952 &&& h\{c\} & \textrm{constructor parameter} \\
adamc@551	1953 \textrm{Attribute value} & v &::=& \ell & \textrm{literal value} \\
adamc@551	1954 &&& \{e\} & \textrm{computed value} \\
adamc@551	1955 \end{array}$$
adamc@551	1956
adamc@552	1957
adamc@553	1958 \section{The Structure of Web Applications}
adamc@553	1959
adamc@553	1960 A web application is built from a series of modules, with one module, the last one appearing in the \texttt{.urp} file, designated as the main module. The signature of the main module determines the URL entry points to the application. Such an entry point should have type $\mt{unit} \to \mt{transaction} \; \mt{page}$, where $\mt{page}$ is a type synonym for top-level HTML pages, defined in $\mt{Basis}$. If such a function is at the top level of main module $M$, it will be accessible at URI \texttt{/M/f}, and so on for more deeply-nested functions, as described in Section \ref{tag} below.
adamc@553	1961
adamc@553	1962 When the standalone web server receives a request for a known page, it calls the function for that page, ``running'' the resulting transaction to produce the page to return to the client. Pages link to other pages with the \texttt{link} attribute of the \texttt{a} HTML tag. A link has type $\mt{transaction} \; \mt{page}$, and the semantics of a link are that this transaction should be run to compute the result page, when the link is followed. Link targets are assigned URL names in the same way as top-level entry points.
adamc@553	1963
adamc@553	1964 HTML forms are handled in a similar way. The $\mt{action}$ attribute of a $\mt{submit}$ form tag takes a value of type $\$\mt{use} \to \mt{transaction} \; \mt{page}$, where $\mt{use}$ is a kind-$\{\mt{Type}\}$ record of the form fields used by this action handler. Action handlers are assigned URL patterns in the same way as above.
adamc@553	1965
adamc@558	1966 For both links and actions, direct arguments and local variables mentioned implicitly via closures are automatically included in serialized form in URLs, in the order in which they appear in the source code.
adamc@553	1967
adamc@660	1968 Ur/Web programs generally mix server- and client-side code in a fairly transparent way. The one important restriction is that mixed client-server code must encapsulate all server-side pieces within named functions. This is because execution of such pieces will be implemented by explicit calls to the remote web server, and it is useful to get the programmer's help in designing the interface to be used. For example, this makes it easier to allow a client running an old version of an application to continue interacting with a server that has been upgraded to a new version, if the programmer took care to keep the interfaces of all of the old remote calls the same. The functions implementing these services are assigned names in the same way as normal web entry points, by using module structure.
adamc@660	1969
adamc@789	1970 \medskip
adamc@789	1971
adamc@789	1972 The HTTP standard suggests that GET requests only be used in ways that generate no side effects. Side effecting operations should use POST requests instead. The Ur/Web compiler enforces this rule strictly, via a simple conservative program analysis. Any page that may have a side effect must be accessed through a form, all of which use POST requests. A page is judged to have a side effect if its code depends syntactically on any of the side-effecting, server-side FFI functions. Links, forms, and most client-side event handlers are not followed during this syntactic traversal, but \texttt{<body onload=\{...\}>} handlers \emph{are} examined, since they run right away and could just as well be considered parts of main page handlers.
adamc@789	1973
adamc@789	1974 Ur/Web includes a kind of automatic protection against cross site request forgery attacks. Whenever any page execution can have side effects and can also read at least one cookie value, all cookie values must be signed cryptographically, to ensure that the user has come to the current page by submitting a form on a real page generated by the proper server. Signing and signature checking are inserted automatically by the compiler. This prevents attacks like phishing schemes where users are directed to counterfeit pages with forms that submit to your application, where a user's cookies might be submitted without his knowledge, causing some undesired side effect.
adamc@789	1975
adamc@553	1976
adamc@897	1977 \section{The Foreign Function Interface}
adamc@897	1978
adamc@897	1979 It is possible to call your own C and JavaScript code from Ur/Web applications, via the foreign function interface (FFI). The starting point for a new binding is a \texttt{.urs} signature file that presents your external library as a single Ur/Web module (with no nested modules). Compilation conventions map the types and values that you use into C and/or JavaScript types and values.
adamc@897	1980
adamc@897	1981 It is most convenient to encapsulate an FFI binding with a new \texttt{.urp} file, which applications can include with the \texttt{library} directive in their own \texttt{.urp} files. A number of directives are likely to show up in the library's project file.
adamc@897	1982
adamc@897	1983 \begin{itemize}
adamc@897	1984 \item \texttt{clientOnly Module.ident} registers a value as being allowed only in client-side code.
adamc@897	1985 \item \texttt{clientToServer Module.ident} declares a type as OK to marshal between clients and servers. By default, abstract FFI types are not allowed to be marshalled, since your library might be maintaining invariants that the simple serialization code doesn't check.
adamc@897	1986 \item \texttt{effectful Module.ident} registers a function that can have side effects. It is important to remember to use this directive for each such function, or else the optimizer might change program semantics.
adamc@897	1987 \item \texttt{ffi FILE.urs} names the file giving your library's signature. You can include multiple such files in a single \texttt{.urp} file, and each file \texttt{mod.urp} defines an FFI module \texttt{Mod}.
adamc@897	1988 \item \texttt{header FILE} requests inclusion of a C header file.
adamc@897	1989 \item \texttt{jsFunc Module.ident=name} gives a mapping from an Ur name for a value to a JavaScript name.
adamc@897	1990 \item \texttt{link FILE} requests that \texttt{FILE} be linked into applications. It should be a C object or library archive file, and you are responsible for generating it with your own build process.
adamc@897	1991 \item \texttt{script URL} requests inclusion of a JavaScript source file within application HTML.
adamc@897	1992 \item \texttt{serverOnly Module.ident} registers a value as being allowed only in server-side code.
adamc@897	1993 \end{itemize}
adamc@897	1994
adamc@897	1995 \subsection{Writing C FFI Code}
adamc@897	1996
adamc@897	1997 A server-side FFI type or value \texttt{Module.ident} must have a corresponding type or value definition \texttt{uw\_Module\_ident} in C code. With the current Ur/Web version, it's not generally possible to work with Ur records or complex datatypes in C code, but most other kinds of types are fair game.
adamc@897	1998
adamc@897	1999 \begin{itemize}
adamc@897	2000 \item Primitive types defined in \texttt{Basis} are themselves using the standard FFI interface, so you may refer to them like \texttt{uw\_Basis\_t}. See \texttt{include/types.h} for their definitions.
adamc@897	2001 \item Enumeration datatypes, which have only constructors that take no arguments, should be defined using C \texttt{enum}s. The type is named as for any other type identifier, and each constructor \texttt{c} gets an enumeration constant named \texttt{uw\_Module\_c}.
adamc@897	2002 \item A datatype \texttt{dt} (such as \texttt{Basis.option}) that has one non-value-carrying constructor \texttt{NC} and one value-carrying constructor \texttt{C} gets special treatment. Where \texttt{T} is the type of \texttt{C}'s argument, and where we represent \texttt{T} as \texttt{t} in C, we represent \texttt{NC} with \texttt{NULL}. The representation of \texttt{C} depends on whether we're sure that we don't need to use \texttt{NULL} to represent \texttt{t} values; this condition holds only for strings and complex datatypes. For such types, \texttt{C v} is represented with the C encoding of \texttt{v}, such that the translation of \texttt{dt} is \texttt{t}. For other types, \texttt{C v} is represented with a pointer to the C encoding of v, such that the translation of \texttt{dt} is \texttt{t*}.
adamc@897	2003 \end{itemize}
adamc@897	2004
adamc@897	2005 The C FFI version of a Ur function with type \texttt{T1 -> ... -> TN -> R} or \texttt{T1 -> ... -> TN -> transaction R} has a C prototype like \texttt{R uw\_Module\_ident(uw\_context, T1, ..., TN)}. Only functions with types of the second form may have side effects. \texttt{uw\_context} is the type of state that persists across handling a client request. Many functions that operate on contexts are prototyped in \texttt{include/urweb.h}. Most should only be used internally by the compiler. A few are useful in general FFI implementation:
adamc@897	2006 \begin{itemize}
adamc@897	2007 \item \begin{verbatim}
adamc@897	2008 void uw_error(uw_context, failure_kind, const char *fmt, ...);
adamc@897	2009 \end{verbatim}
adamc@897	2010 Abort the current request processing, giving a \texttt{printf}-style format string and arguments for generating an error message. The \texttt{failure\_kind} argument can be \texttt{FATAL}, to abort the whole execution; \texttt{BOUNDED\_RETRY}, to try processing the request again from the beginning, but failing if this happens too many times; or \texttt{UNLIMITED\_RETRY}, to repeat processing, with no cap on how many times this can recur.
adamc@897	2011
adamc@897	2012 \item \begin{verbatim}
adamc@897	2013 void uw_push_cleanup(uw_context, void (func)(void ), void *arg);
adamc@897	2014 void uw_pop_cleanup(uw_context);
adamc@897	2015 \end{verbatim}
adamc@897	2016 Manipulate a stack of actions that should be taken if any kind of error condition arises. Calling the ``pop'' function both removes an action from the stack and executes it.
adamc@897	2017
adamc@897	2018 \item \begin{verbatim}
adamc@897	2019 void *uw_malloc(uw_context, size_t);
adamc@897	2020 \end{verbatim}
adamc@897	2021 A version of \texttt{malloc()} that allocates memory inside a context's heap, which is managed with region allocation. Thus, there is no \texttt{uw\_free()}, but you need to be careful not to keep ad-hoc C pointers to this area of memory.
adamc@897	2022
adamc@897	2023 For performance and correctness reasons, it is usually preferable to use \texttt{uw\_malloc()} instead of \texttt{malloc()}. The former manipulates a local heap that can be kept allocated across page requests, while the latter uses global data structures that may face contention during concurrent execution.
adamc@897	2024
adamc@897	2025 \item \begin{verbatim}
adamc@897	2026 typedef void (uw_callback)(void );
adamc@897	2027 void uw_register_transactional(uw_context, void *data, uw_callback commit,
adamc@897	2028 uw_callback rollback, uw_callback free);
adamc@897	2029 \end{verbatim}
adamc@897	2030 All side effects in Ur/Web programs need to be compatible with transactions, such that any set of actions can be undone at any time. Thus, you should not perform actions with non-local side effects directly; instead, register handlers to be called when the current transaction is committed or rolled back. The arguments here give an arbitary piece of data to be passed to callbacks, a function to call on commit, a function to call on rollback, and a function to call afterward in either case to clean up any allocated resources. A rollback handler may be called after the associated commit handler has already been called, if some later part of the commit process fails.
adamc@897	2031
adamc@1085	2032 Any of the callbacks may be \texttt{NULL}. To accommodate some stubbornly non-transactional real-world actions like sending an e-mail message, Ur/Web treats \texttt{NULL} \texttt{rollback} callbacks specially. When a transaction commits, all \texttt{commit} actions that have non-\texttt{NULL} rollback actions are tried before any \texttt{commit} actions that have \texttt{NULL} rollback actions. Thus, if a single execution uses only one non-transactional action, and if that action never fails partway through its execution while still causing an observable side effect, then Ur/Web can maintain the transactional abstraction.
adamc@1085	2033
adamc@1085	2034 \item \begin{verbatim}
adamc@1085	2035 void uw_get_global(uw_context, char name);
adamc@1085	2036 void uw_set_global(uw_context, char name, void data, uw_callback free);
adamc@1085	2037 \end{verbatim}
adamc@1085	2038 Different FFI-based extensions may want to associate their own pieces of data with contexts. The global interface provides a way of doing that, where each extension must come up with its own unique key. The \texttt{free} argument to \texttt{uw\_set\_global()} explains how to deallocate the saved data.
adamc@1085	2039
adamc@897	2040 \end{itemize}
adamc@897	2041
adamc@897	2042 \subsection{Writing JavaScript FFI Code}
adamc@897	2043
adamc@897	2044 JavaScript is dynamically typed, so Ur/Web type definitions imply no JavaScript code. The JavaScript identifier for each FFI function is set with the \texttt{jsFunc} directive. Each identifier can be defined in any JavaScript file that you ask to include with the \texttt{script} directive.
adamc@897	2045
adamc@897	2046 In contrast to C FFI code, JavaScript FFI functions take no extra context argument. Their argument lists are as you would expect from their Ur types. Only functions whose ranges take the form \texttt{transaction T} should have side effects; the JavaScript ``return type'' of such a function is \texttt{T}. Here are the conventions for representing Ur values in JavaScript.
adamc@897	2047
adamc@897	2048 \begin{itemize}
adamc@897	2049 \item Integers, floats, strings, characters, and booleans are represented in the usual JavaScript way.
adamc@985	2050 \item Ur functions are represented in an unspecified way. This means that you should not rely on any details of function representation. Named FFI functions are represented as JavaScript functions with as many arguments as their Ur types specify. To call a non-FFI function \texttt{f} on argument \texttt{x}, run \texttt{execF(f, x)}.
adamc@897	2051 \item An Ur record is represented with a JavaScript record, where Ur field name \texttt{N} translates to JavaScript field name \texttt{\_N}. An exception to this rule is that the empty record is encoded as \texttt{null}.
adamc@897	2052 \item \texttt{option}-like types receive special handling similar to their handling in C. The ``\texttt{None}'' constructor is \texttt{null}, and a use of the ``\texttt{Some}'' constructor on a value \texttt{v} is either \texttt{v}, if the underlying type doesn't need to use \texttt{null}; or \texttt{\{v:v\}} otherwise.
adamc@985	2053 \item Any other datatypes represent a non-value-carrying constructor \texttt{C} as \texttt{"C"} and an application of a constructor \texttt{C} to value \texttt{v} as \texttt{\{n:"C", v:v\}}. This rule only applies to datatypes defined in FFI module signatures; the compiler is free to optimize the representations of other, non-\texttt{option}-like datatypes in arbitrary ways.
adamc@897	2054 \end{itemize}
adamc@897	2055
adamc@897	2056 It is possible to write JavaScript FFI code that interacts with the functional-reactive structure of a document, but this version of the manual doesn't cover the details.
adamc@897	2057
adamc@897	2058
adamc@552	2059 \section{Compiler Phases}
adamc@552	2060
adamc@552	2061 The Ur/Web compiler is unconventional in that it relies on a kind of \emph{heuristic compilation}. Not all valid programs will compile successfully. Informally, programs fail to compile when they are ``too higher order.'' Compiler phases do their best to eliminate different kinds of higher order-ness, but some programs just won't compile. This is a trade-off for producing very efficient executables. Compiled Ur/Web programs use native C representations and require no garbage collection.
adamc@552	2062
adamc@552	2063 In this section, we step through the main phases of compilation, noting what consequences each phase has for effective programming.
adamc@552	2064
adamc@552	2065 \subsection{Parse}
adamc@552	2066
adamc@552	2067 The compiler reads a \texttt{.urp} file, figures out which \texttt{.urs} and \texttt{.ur} files it references, and combines them all into what is conceptually a single sequence of declarations in the core language of Section \ref{core}.
adamc@552	2068
adamc@552	2069 \subsection{Elaborate}
adamc@552	2070
adamc@552	2071 This is where type inference takes place, translating programs into an explicit form with no more wildcards. This phase is the most likely source of compiler error messages.
adamc@552	2072
adamc@552	2073 \subsection{Unnest}
adamc@552	2074
adamc@552	2075 Named local function definitions are moved to the top level, to avoid the need to generate closures.
adamc@552	2076
adamc@552	2077 \subsection{Corify}
adamc@552	2078
adamc@552	2079 Module system features are compiled away, through inlining of functor definitions at application sites. Afterward, most abstraction boundaries are broken, facilitating optimization.
adamc@552	2080
adamc@552	2081 \subsection{Especialize}
adamc@552	2082
adamc@552	2083 Functions are specialized to particular argument patterns. This is an important trick for avoiding the need to maintain any closures at runtime.
adamc@552	2084
adamc@552	2085 \subsection{Untangle}
adamc@552	2086
adamc@552	2087 Remove unnecessary mutual recursion, splitting recursive groups into strongly-connected components.
adamc@552	2088
adamc@552	2089 \subsection{Shake}
adamc@552	2090
adamc@552	2091 Remove all definitions not needed to run the page handlers that are visible in the signature of the last module listed in the \texttt{.urp} file.
adamc@552	2092
adamc@661	2093 \subsection{Rpcify}
adamc@661	2094
adamc@661	2095 Pieces of code are determined to be client-side, server-side, neither, or both, by figuring out which standard library functions might be needed to execute them. Calls to server-side functions (e.g., $\mt{query}$) within mixed client-server code are identified and replaced with explicit remote calls. Some mixed functions may be converted to continuation-passing style to facilitate this transformation.
adamc@661	2096
adamc@661	2097 \subsection{Untangle, Shake}
adamc@661	2098
adamc@661	2099 Repeat these simplifications.
adamc@661	2100
adamc@553	2101 \subsection{\label{tag}Tag}
adamc@552	2102
adamc@552	2103 Assign a URL name to each link and form action. It is important that these links and actions are written as applications of named functions, because such names are used to generate URL patterns. A URL pattern has a name built from the full module path of the named function, followed by the function name, with all pieces separated by slashes. The path of a functor application is based on the name given to the result, rather than the path of the functor itself.
adamc@552	2104
adamc@552	2105 \subsection{Reduce}
adamc@552	2106
adamc@552	2107 Apply definitional equality rules to simplify the program as much as possible. This effectively includes inlining of every non-recursive definition.
adamc@552	2108
adamc@552	2109 \subsection{Unpoly}
adamc@552	2110
adamc@552	2111 This phase specializes polymorphic functions to the specific arguments passed to them in the program. If the program contains real polymorphic recursion, Unpoly will be insufficient to avoid later error messages about too much polymorphism.
adamc@552	2112
adamc@552	2113 \subsection{Specialize}
adamc@552	2114
adamc@558	2115 Replace uses of parameterized datatypes with versions specialized to specific parameters. As for Unpoly, this phase will not be effective enough in the presence of polymorphic recursion or other fancy uses of impredicative polymorphism.
adamc@552	2116
adamc@552	2117 \subsection{Shake}
adamc@552	2118
adamc@558	2119 Here the compiler repeats the earlier Shake phase.
adamc@552	2120
adamc@552	2121 \subsection{Monoize}
adamc@552	2122
adamc@552	2123 Programs are translated to a new intermediate language without polymorphism or non-$\mt{Type}$ constructors. Error messages may pop up here if earlier phases failed to remove such features.
adamc@552	2124
adamc@552	2125 This is the stage at which concrete names are generated for cookies, tables, and sequences. They are named following the same convention as for links and actions, based on module path information saved from earlier stages. Table and sequence names separate path elements with underscores instead of slashes, and they are prefixed by \texttt{uw\_}.
adamc@664	2126
adamc@552	2127 \subsection{MonoOpt}
adamc@552	2128
adamc@552	2129 Simple algebraic laws are applied to simplify the program, focusing especially on efficient imperative generation of HTML pages.
adamc@552	2130
adamc@552	2131 \subsection{MonoUntangle}
adamc@552	2132
adamc@552	2133 Unnecessary mutual recursion is broken up again.
adamc@552	2134
adamc@552	2135 \subsection{MonoReduce}
adamc@552	2136
adamc@552	2137 Equivalents of the definitional equality rules are applied to simplify programs, with inlining again playing a major role.
adamc@552	2138
adamc@552	2139 \subsection{MonoShake, MonoOpt}
adamc@552	2140
adamc@552	2141 Unneeded declarations are removed, and basic optimizations are repeated.
adamc@552	2142
adamc@552	2143 \subsection{Fuse}
adamc@552	2144
adamc@552	2145 The compiler tries to simplify calls to recursive functions whose results are immediately written as page output. The write action is pushed inside the function definitions to avoid allocation of intermediate results.
adamc@552	2146
adamc@552	2147 \subsection{MonoUntangle, MonoShake}
adamc@552	2148
adamc@552	2149 Fuse often creates more opportunities to remove spurious mutual recursion.
adamc@552	2150
adamc@552	2151 \subsection{Pathcheck}
adamc@552	2152
adamc@552	2153 The compiler checks that no link or action name has been used more than once.
adamc@552	2154
adamc@552	2155 \subsection{Cjrize}
adamc@552	2156
adamc@552	2157 The program is translated to what is more or less a subset of C. If any use of functions as data remains at this point, the compiler will complain.
adamc@552	2158
adamc@552	2159 \subsection{C Compilation and Linking}
adamc@552	2160
adamc@552	2161 The output of the last phase is pretty-printed as C source code and passed to GCC.
adamc@552	2162
adamc@552	2163
adamc@524	2164 \end{document}

Mercurial > urweb

annotate doc/manual.tex @ 1085:ae885ad70d83