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#include <assert.h>
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include "alloc.h"
#include "analyzer.h"
#include "common.h"
#include "errors.h"
#include "parser.h"
#include "strview.h"
#include "types.h"
/* A hashmap mapping symbol names to their indicies in the AST */
typedef struct symtab {
struct symtab *child[4];
struct strview key;
idx_t_ val;
} symtab;
/* A dynamic array of scopes */
struct scopes {
struct scope *buf;
size_t len, cap;
};
/* Analyzer context; keeps track of the state of static analysis */
struct azctx {
/* An arena allocator */
arena *a;
/* The return type of the function being analyzed */
struct type fnret;
/* The name of the symbol being declared. This is necessary to allow
for ‘X :: X’ to be treated as shadowing and not a circular
definition */
struct strview decl;
/* If we need to check for return statements. Only true for the
outer body-block of a function that returns a value. */
bool chkrets;
/* The index of the current scope in the scopes array */
idx_t_ si;
};
static void analyzeast(struct scope *, struct type *, struct ast,
struct lexemes, arena *)
__attribute__((nonnull));
/* Perform a pass over the entire AST and return an array of symbol
tables, one for each scope in the program */
static struct scope *gensymtabs(struct ast, struct lexemes, arena *)
__attribute__((returns_nonnull, nonnull));
/* Find all the unordered symbols in the scope delimited by the inclusive
indicies BEG and END in the AST, and accumulate them into a symbol
table appended to the symbol table list. UP is the index of the
previous scopes symbol table in the symbol table list. */
static void find_unordered_syms(struct scopes *, struct ast, struct lexemes,
idx_t_ up, idx_t_ beg, idx_t_ end, arena *)
__attribute__((nonnull));
typedef idx_t_ analyzer(struct azctx, struct scope *, struct type *, struct ast,
struct lexemes, idx_t_)
__attribute__((nonnull));
static analyzer analyzeblk, analyzedecl, analyzeexpr, analyzefn, analyzestmt;
static const struct type *typegrab(struct ast, struct lexemes, idx_t_)
__attribute__((returns_nonnull));
static bool typecompat(struct type, struct type);
static bool returns(struct ast, idx_t_);
/* Index the symbol table M with the key SV, returning a pointer to the
value. If no entry exists and A is non-null, a pointer to a newly
allocated (and zeroed) value is returned, NULL otherwise. */
static idx_t_ *symtab_insert(symtab **m, struct strview sv, arena *a)
__attribute__((nonnull(1)));
/* Defined in primitives.gperf */
const struct type *typelookup(const uchar *, size_t)
__attribute__((nonnull));
void
analyzeprog(struct ast ast, struct lexemes toks, arena *a, struct type **types,
struct scope **scps)
{
*types = bufalloc(NULL, ast.len, sizeof(**types));
memset(*types, 0, ast.len * sizeof(**types));
*scps = gensymtabs(ast, toks, a);
analyzeast(*scps, *types, ast, toks, a);
}
struct scope *
gensymtabs(struct ast ast, struct lexemes toks, arena *a)
{
struct scopes scps = {.cap = 32};
scps.buf = bufalloc(NULL, scps.cap, sizeof(*scps.buf));
find_unordered_syms(&scps, ast, toks, 0, 0, ast.len - 1, a);
return scps.buf;
}
void
find_unordered_syms(struct scopes *scps, struct ast ast, struct lexemes toks,
idx_t_ up, idx_t_ beg, idx_t_ end, arena *a)
{
if (scps->len == scps->cap) {
scps->cap *= 2;
scps->buf = bufalloc(scps->buf, scps->cap, sizeof(*scps->buf));
}
struct scope *scp = scps->buf + scps->len++;
*scp = (struct scope){
.i = beg,
.up = up,
.map = NULL,
};
for (idx_t_ i = beg; likely(i <= end); i++) {
bool globl_var = ast.kinds[i] <= _AST_DECLS_END && beg == 0;
bool const_var = (ast.kinds[i] | 1) == ASTPCDECL;
if (globl_var || const_var) {
struct strview sv = toks.strs[ast.lexemes[i]];
idx_t_ *p = symtab_insert(&scp->map, sv, a);
if (*p != 0) {
err("analyzer: Symbol ‘%.*s’ declared multiple times",
SV_PRI_ARGS(sv));
}
*p = i;
} else if (ast.kinds[i] == ASTBLK) {
struct pair p = ast.kids[i];
find_unordered_syms(scps, ast, toks, beg, p.lhs, p.rhs, a);
i = p.rhs;
}
}
}
const struct type *
typegrab(struct ast ast, struct lexemes toks, idx_t_ i)
{
struct strview sv = toks.strs[ast.lexemes[i]];
const struct type *tp = typelookup(sv.p, sv.len);
if (tp == NULL)
err("analyzer: Unknown type ‘%.*s’", (int)sv.len, sv.p);
return tp;
}
void
analyzeast(struct scope *scps, struct type *types, struct ast ast,
struct lexemes toks, arena *a)
{
struct azctx ctx = {.a = a};
for (idx_t_ i = 0; likely(i < ast.len); i = fwdnode(ast, i)) {
assert(ast.kinds[i] <= _AST_DECLS_END);
analyzedecl(ctx, scps, types, ast, toks, i);
}
}
idx_t_
analyzedecl(struct azctx ctx, struct scope *scps, struct type *types,
struct ast ast, struct lexemes toks, idx_t_ i)
{
struct strview sv = toks.strs[ast.lexemes[i]];
if (ctx.si > 0 && (ast.kinds[i] | 1) == ASTPDECL) {
idx_t_ *ip = symtab_insert(&scps[ctx.si].map, sv, ctx.a);
if (*ip == 0)
*ip = i;
else {
err("analyzer: Variable ‘%.*s’ declared multiple times",
SV_PRI_ARGS(sv));
}
}
types[i].kind = TYPE_CHECKING;
struct pair p = ast.kids[i];
struct type ltype, rtype;
ltype.kind = TYPE_UNSET;
assert(p.lhs != AST_EMPTY || p.rhs != AST_EMPTY);
idx_t_ ni;
if (p.lhs != AST_EMPTY)
ltype = *typegrab(ast, toks, p.lhs);
if (p.rhs != AST_EMPTY) {
ctx.decl = sv;
ni = analyzeexpr(ctx, scps, types, ast, toks, p.rhs);
rtype = types[p.rhs];
} else
ni = fwdnode(ast, i);
if (ltype.kind == TYPE_UNSET)
ltype = rtype;
else if (!typecompat(ltype, rtype))
err("analyzer: Type mismatch");
types[i] = ltype;
return ni;
}
idx_t_
analyzestmt(struct azctx ctx, struct scope *scps, struct type *types,
struct ast ast, struct lexemes toks, idx_t_ i)
{
switch (ast.kinds[i]) {
case ASTDECL:
case ASTCDECL:
return analyzedecl(ctx, scps, types, ast, toks, i);
case ASTRET: {
idx_t_ expr = ast.kids[i].rhs;
if (expr == AST_EMPTY) {
if (ctx.fnret.kind != TYPE_UNSET)
err("analyzer: Missing return value");
return i + 1;
} else if (ctx.fnret.kind == TYPE_UNSET)
err("analyzer: Function has no return value");
idx_t_ ni = analyzeexpr(ctx, scps, types, ast, toks, ast.kids[i].rhs);
if (!typecompat(ctx.fnret, types[ast.kids[i].rhs]))
err("analyzer: Return type mismatch");
return ni;
}
default:
__builtin_unreachable();
}
}
idx_t_
analyzeexpr(struct azctx ctx, struct scope *scps, struct type *types,
struct ast ast, struct lexemes toks, idx_t_ i)
{
switch (ast.kinds[i]) {
case ASTNUMLIT:
types[i].kind = TYPE_NUM;
types[i].size = 0;
types[i].issigned = true;
return i + 1;
case ASTIDENT: {
struct strview sv = toks.strs[ast.lexemes[i]];
/* Variable shadowing */
if (strview_eq(sv, ctx.decl) && ctx.si > 0)
ctx.si--;
for (idx_t_ lvl = ctx.si;;) {
struct scope scp = scps[lvl];
idx_t_ *ip = symtab_insert(&scp.map, sv, NULL);
if (ip == NULL) {
if (lvl == 0)
break;
lvl = scp.up;
} else {
switch (types[*ip].kind) {
case TYPE_UNSET:
ctx.si = lvl;
analyzedecl(ctx, scps, types, ast, toks, *ip);
break;
case TYPE_CHECKING:
err("analyzer: Circular definition of ‘%.*s’", SV_PRI_ARGS(sv));
}
types[i] = types[*ip];
return i + 1;
}
}
err("analyzer: Unknown symbol ‘%.*s’", SV_PRI_ARGS(sv));
}
case ASTFN:
return analyzefn(ctx, scps, types, ast, toks, i);
default:
__builtin_unreachable();
}
}
idx_t_
analyzefn(struct azctx ctx, struct scope *scps, struct type *types,
struct ast ast, struct lexemes toks, idx_t_ i)
{
struct type t = {.kind = TYPE_FN};
struct pair p = ast.kids[i];
idx_t_ proto = p.lhs;
if (ast.kids[proto].rhs != AST_EMPTY) {
t.ret = typegrab(ast, toks, ast.kids[proto].rhs);
ctx.fnret = *t.ret;
ctx.chkrets = true;
} else
ctx.fnret.kind = TYPE_UNSET;
types[i] = t;
return analyzeblk(ctx, scps, types, ast, toks, p.rhs);
}
idx_t_
analyzeblk(struct azctx ctx, struct scope *scps, struct type *types,
struct ast ast, struct lexemes toks, idx_t_ i)
{
struct pair p = ast.kids[i];
while (scps[ctx.si].i != p.lhs)
ctx.si++;
bool chkrets = ctx.chkrets, hasret = false;
ctx.chkrets = false;
for (i = p.lhs; i <= p.rhs;) {
if (chkrets && returns(ast, i))
hasret = true;
i = analyzestmt(ctx, scps, types, ast, toks, i);
}
if (chkrets && !hasret)
err("analyzer: Function doesn’t return on all paths");
return i;
}
bool
returns(struct ast ast, idx_t_ i)
{
switch (ast.kinds[i]) {
case ASTDECL:
case ASTPDECL:
case ASTCDECL:
case ASTPCDECL:
return false;
case ASTRET:
return true;
}
__builtin_unreachable();
}
bool
typecompat(struct type lhs, struct type rhs)
{
/* Function types are compatible if they have the same parameter- and
return types */
if (lhs.kind == TYPE_FN && rhs.kind == TYPE_FN)
return lhs.paramcnt == rhs.paramcnt && lhs.ret == rhs.ret;
if (lhs.kind == TYPE_FN || rhs.kind == TYPE_FN)
return false;
/* At this point we only have numeric types left */
/* Untyped numeric types are compatible with all numeric types */
if (lhs.size == 0 || rhs.size == 0)
return true;
/* Two typed numeric types are only compatible if they have the same size
and sign and are either both integral or both floats */
return lhs.issigned == rhs.issigned && lhs.isfloat == rhs.isfloat
&& lhs.size == rhs.size;
}
idx_t_ *
symtab_insert(symtab **m, struct strview k, arena *a)
{
for (uint64_t h = strview_hash(k); *m; h <<= 2) {
if (strview_eq(k, (*m)->key))
return &(*m)->val;
m = &(*m)->child[h >> 62];
}
if (a == NULL)
return NULL;
*m = arena_new(a, symtab, 1);
(*m)->key = k;
return &(*m)->val;
}
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