/* * Copyright (c) 2019 Calvin Rose * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to * deal in the Software without restriction, including without limitation the * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or * sell copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. */ #ifndef JANET_AMALG #include #include #include "util.h" #include "vector.h" #include "util.h" #endif #ifdef JANET_PEG /* * Runtime */ /* opcodes for peg vm */ typedef enum { RULE_LITERAL, /* [len, bytes...] */ RULE_NCHAR, /* [n] */ RULE_NOTNCHAR, /* [n] */ RULE_RANGE, /* [lo | hi << 16 (1 word)] */ RULE_SET, /* [bitmap (8 words)] */ RULE_LOOK, /* [offset, rule] */ RULE_CHOICE, /* [len, rules...] */ RULE_SEQUENCE, /* [len, rules...] */ RULE_IF, /* [rule_a, rule_b (b if a)] */ RULE_IFNOT, /* [rule_a, rule_b (b if not a)] */ RULE_NOT, /* [rule] */ RULE_BETWEEN, /* [lo, hi, rule] */ RULE_GETTAG, /* [searchtag, tag] */ RULE_CAPTURE, /* [rule, tag] */ RULE_POSITION, /* [tag] */ RULE_ARGUMENT, /* [argument-index, tag] */ RULE_CONSTANT, /* [constant, tag] */ RULE_ACCUMULATE, /* [rule, tag] */ RULE_GROUP, /* [rule, tag] */ RULE_REPLACE, /* [rule, constant, tag] */ RULE_MATCHTIME, /* [rule, constant, tag] */ RULE_ERROR, /* [rule] */ RULE_DROP, /* [rule] */ } Opcode; /* Hold captured patterns and match state */ typedef struct { const uint8_t *text_start; const uint8_t *text_end; const uint32_t *bytecode; const Janet *constants; JanetArray *captures; JanetBuffer *scratch; JanetBuffer *tags; const Janet *extrav; int32_t extrac; int32_t depth; enum { PEG_MODE_NORMAL, PEG_MODE_ACCUMULATE } mode; } PegState; /* Allow backtrack with captures. We need * to save state at branches, and then reload * if one branch fails and try a new branch. */ typedef struct { int32_t cap; int32_t scratch; } CapState; /* Save the current capture state */ static CapState cap_save(PegState *s) { CapState cs; cs.scratch = s->scratch->count; cs.cap = s->captures->count; return cs; } /* Load a saved capture state in the case of failure */ static void cap_load(PegState *s, CapState cs) { s->scratch->count = cs.scratch; s->captures->count = cs.cap; s->tags->count = cs.cap; } /* Add a capture */ static void pushcap(PegState *s, Janet capture, uint32_t tag) { if (s->mode == PEG_MODE_ACCUMULATE) { janet_to_string_b(s->scratch, capture); } if (tag || s->mode == PEG_MODE_NORMAL) { janet_array_push(s->captures, capture); janet_buffer_push_u8(s->tags, tag); } } /* Prevent stack overflow */ #define down1(s) do { \ if (0 == --((s)->depth)) janet_panic("peg/match recursed too deeply"); \ } while (0) #define up1(s) ((s)->depth++) /* Evaluate a peg rule * Pre-conditions: s is in a valid state * Post-conditions: If there is a match, returns a pointer to the next text. * All captures on the capture stack are valid. If there is no match, * returns NULL. Extra captures from successful child expressions can be * left on the capture stack. */ static const uint8_t *peg_rule( PegState *s, const uint32_t *rule, const uint8_t *text) { tail: switch (*rule & 0x1F) { default: janet_panic("unexpected opcode"); return NULL; case RULE_LITERAL: { uint32_t len = rule[1]; if (text + len > s->text_end) return NULL; return memcmp(text, rule + 2, len) ? NULL : text + len; } case RULE_NCHAR: { uint32_t n = rule[1]; return (text + n > s->text_end) ? NULL : text + n; } case RULE_NOTNCHAR: { uint32_t n = rule[1]; return (text + n > s->text_end) ? text : NULL; } case RULE_RANGE: { uint8_t lo = rule[1] & 0xFF; uint8_t hi = (rule[1] >> 16) & 0xFF; return (text < s->text_end && text[0] >= lo && text[0] <= hi) ? text + 1 : NULL; } case RULE_SET: { uint32_t word = rule[1 + (text[0] >> 5)]; uint32_t mask = (uint32_t)1 << (text[0] & 0x1F); return (text < s->text_end && (word & mask)) ? text + 1 : NULL; } case RULE_LOOK: { text += ((int32_t *)rule)[1]; if (text < s->text_start || text > s->text_end) return NULL; down1(s); const uint8_t *result = peg_rule(s, s->bytecode + rule[2], text); up1(s); return result ? text : NULL; } case RULE_CHOICE: { uint32_t len = rule[1]; const uint32_t *args = rule + 2; if (len == 0) return NULL; down1(s); CapState cs = cap_save(s); for (uint32_t i = 0; i < len - 1; i++) { const uint8_t *result = peg_rule(s, s->bytecode + args[i], text); if (result) { up1(s); return result; } cap_load(s, cs); } up1(s); rule = s->bytecode + args[len - 1]; goto tail; } case RULE_SEQUENCE: { uint32_t len = rule[1]; const uint32_t *args = rule + 2; if (len == 0) return text; down1(s); for (uint32_t i = 0; text && i < len - 1; i++) text = peg_rule(s, s->bytecode + args[i], text); up1(s); if (!text) return NULL; rule = s->bytecode + args[len - 1]; goto tail; } case RULE_IF: case RULE_IFNOT: { const uint32_t *rule_a = s->bytecode + rule[1]; const uint32_t *rule_b = s->bytecode + rule[2]; down1(s); const uint8_t *result = peg_rule(s, rule_a, text); up1(s); if (rule[0] == RULE_IF ? !result : !!result) return NULL; rule = rule_b; goto tail; } case RULE_NOT: { const uint32_t *rule_a = s->bytecode + rule[1]; down1(s); const uint8_t *result = peg_rule(s, rule_a, text); up1(s); return (result) ? NULL : text; } case RULE_BETWEEN: { uint32_t lo = rule[1]; uint32_t hi = rule[2]; const uint32_t *rule_a = s->bytecode + rule[3]; uint32_t captured = 0; const uint8_t *next_text; CapState cs = cap_save(s); down1(s); while (captured < hi) { CapState cs2 = cap_save(s); next_text = peg_rule(s, rule_a, text); if (!next_text || next_text == text) { cap_load(s, cs2); break; } captured++; text = next_text; } up1(s); if (captured < lo) { cap_load(s, cs); return NULL; } return text; } /* Capturing rules */ case RULE_GETTAG: { uint32_t search = rule[1]; uint32_t tag = rule[2]; for (int32_t i = s->tags->count - 1; i >= 0; i--) { if (s->tags->data[i] == search) { pushcap(s, s->captures->data[i], tag); return text; } } return NULL; } case RULE_POSITION: { pushcap(s, janet_wrap_number((double)(text - s->text_start)), rule[1]); return text; } case RULE_ARGUMENT: { int32_t index = ((int32_t *)rule)[1]; Janet capture = (index >= s->extrac) ? janet_wrap_nil() : s->extrav[index]; pushcap(s, capture, rule[2]); return text; } case RULE_CONSTANT: { pushcap(s, s->constants[rule[1]], rule[2]); return text; } case RULE_CAPTURE: { uint32_t tag = rule[2]; down1(s); const uint8_t *result = peg_rule(s, s->bytecode + rule[1], text); up1(s); if (!result) return NULL; /* Specialized pushcap - avoid intermediate string creation */ if (!tag && s->mode == PEG_MODE_ACCUMULATE) { janet_buffer_push_bytes(s->scratch, text, (int32_t)(result - text)); } else { pushcap(s, janet_stringv(text, (int32_t)(result - text)), tag); } return result; } case RULE_ACCUMULATE: { uint32_t tag = rule[2]; int oldmode = s->mode; if (!tag && oldmode == PEG_MODE_ACCUMULATE) { rule = s->bytecode + rule[1]; goto tail; } CapState cs = cap_save(s); s->mode = PEG_MODE_ACCUMULATE; down1(s); const uint8_t *result = peg_rule(s, s->bytecode + rule[1], text); up1(s); s->mode = oldmode; if (!result) return NULL; Janet cap = janet_stringv(s->scratch->data + cs.scratch, s->scratch->count - cs.scratch); cap_load(s, cs); pushcap(s, cap, tag); return result; } case RULE_DROP: { CapState cs = cap_save(s); down1(s); const uint8_t *result = peg_rule(s, s->bytecode + rule[1], text); up1(s); if (!result) return NULL; cap_load(s, cs); return result; } case RULE_GROUP: { uint32_t tag = rule[2]; int oldmode = s->mode; CapState cs = cap_save(s); s->mode = PEG_MODE_NORMAL; down1(s); const uint8_t *result = peg_rule(s, s->bytecode + rule[1], text); up1(s); s->mode = oldmode; if (!result) return NULL; int32_t num_sub_captures = s->captures->count - cs.cap; JanetArray *sub_captures = janet_array(num_sub_captures); memcpy(sub_captures->data, s->captures->data + cs.cap, sizeof(Janet) * num_sub_captures); sub_captures->count = num_sub_captures; cap_load(s, cs); pushcap(s, janet_wrap_array(sub_captures), tag); return result; } case RULE_REPLACE: case RULE_MATCHTIME: { uint32_t tag = rule[3]; int oldmode = s->mode; CapState cs = cap_save(s); s->mode = PEG_MODE_NORMAL; down1(s); const uint8_t *result = peg_rule(s, s->bytecode + rule[1], text); up1(s); s->mode = oldmode; if (!result) return NULL; Janet cap; Janet constant = s->constants[rule[2]]; switch (janet_type(constant)) { default: cap = constant; break; case JANET_STRUCT: cap = janet_struct_get(janet_unwrap_struct(constant), s->captures->data[s->captures->count - 1]); break; case JANET_TABLE: cap = janet_table_get(janet_unwrap_table(constant), s->captures->data[s->captures->count - 1]); break; case JANET_CFUNCTION: cap = janet_unwrap_cfunction(constant)(s->captures->count - cs.cap, s->captures->data + cs.cap); break; case JANET_FUNCTION: cap = janet_call(janet_unwrap_function(constant), s->captures->count - cs.cap, s->captures->data + cs.cap); break; } cap_load(s, cs); if (rule[0] == RULE_MATCHTIME && !janet_truthy(cap)) return NULL; pushcap(s, cap, tag); return result; } case RULE_ERROR: { int oldmode = s->mode; s->mode = PEG_MODE_NORMAL; int32_t old_cap = s->captures->count; down1(s); const uint8_t *result = peg_rule(s, s->bytecode + rule[1], text); up1(s); s->mode = oldmode; if (!result) return NULL; if (s->captures->count > old_cap) { /* Throw last capture */ janet_panicv(s->captures->data[s->captures->count - 1]); } else { /* Throw generic error */ int32_t start = (int32_t)(text - s->text_start); int32_t end = (int32_t)(result - s->text_start); janet_panicf("match error in range (%d:%d)", start, end); } return NULL; } } } /* * Compilation */ typedef struct { JanetTable *grammar; JanetTable *memoized; JanetTable *tags; Janet *constants; uint32_t *bytecode; Janet form; int depth; uint32_t nexttag; } Builder; /* Forward declaration to allow recursion */ static uint32_t peg_compile1(Builder *b, Janet peg); /* * Errors */ static void builder_cleanup(Builder *b) { janet_v_free(b->constants); janet_v_free(b->bytecode); } static void peg_panic(Builder *b, const char *msg) { builder_cleanup(b); janet_panicf("grammar error in %p, %s", b->form, msg); } #define peg_panicf(b,...) peg_panic((b), (const char *) janet_formatc(__VA_ARGS__)) static void peg_fixarity(Builder *b, int32_t argc, int32_t arity) { if (argc != arity) { peg_panicf(b, "expected %d argument%s, got %d%", arity, arity == 1 ? "" : "s", argc); } } static void peg_arity(Builder *b, int32_t arity, int32_t min, int32_t max) { if (min >= 0 && arity < min) peg_panicf(b, "arity mismatch, expected at least %d, got %d", min, arity); if (max >= 0 && arity > max) peg_panicf(b, "arity mismatch, expected at most %d, got %d", max, arity); } static const uint8_t *peg_getset(Builder *b, Janet x) { if (!janet_checktype(x, JANET_STRING)) peg_panic(b, "expected string for character set"); const uint8_t *str = janet_unwrap_string(x); return str; } static const uint8_t *peg_getrange(Builder *b, Janet x) { if (!janet_checktype(x, JANET_STRING)) peg_panic(b, "expected string for character range"); const uint8_t *str = janet_unwrap_string(x); if (janet_string_length(str) != 2) peg_panicf(b, "expected string to have length 2, got %v", x); if (str[1] < str[0]) peg_panicf(b, "range %v is empty", x); return str; } static int32_t peg_getinteger(Builder *b, Janet x) { if (!janet_checkint(x)) peg_panicf(b, "expected integer, got %v", x); return janet_unwrap_integer(x); } static int32_t peg_getnat(Builder *b, Janet x) { int32_t i = peg_getinteger(b, x); if (i < 0) peg_panicf(b, "expected non-negative integer, got %v", x); return i; } /* * Emission */ static uint32_t emit_constant(Builder *b, Janet c) { uint32_t cindex = (uint32_t) janet_v_count(b->constants); janet_v_push(b->constants, c); return cindex; } static uint32_t emit_tag(Builder *b, Janet t) { if (!janet_checktype(t, JANET_KEYWORD)) peg_panicf(b, "expected keyword for capture tag, got %v", t); Janet check = janet_table_get(b->tags, t); if (janet_checktype(check, JANET_NIL)) { uint32_t tag = b->nexttag++; if (tag > 255) { peg_panic(b, "too many tags - up to 255 tags are supported per peg"); } Janet val = janet_wrap_number(tag); janet_table_put(b->tags, t, val); return tag; } else { return (uint32_t) janet_unwrap_number(check); } } /* Reserve space in bytecode for a rule. When a special emits a rule, * it must place that rule immediately on the bytecode stack. This lets * the compiler know where the rule is going to be before it is complete, * allowing recursive rules. */ typedef struct { Builder *builder; uint32_t index; int32_t size; } Reserve; static Reserve reserve(Builder *b, int32_t size) { Reserve r; r.index = janet_v_count(b->bytecode); r.builder = b; r.size = size; for (int32_t i = 0; i < size; i++) janet_v_push(b->bytecode, 0); return r; } /* Emit a rule in the builder. Returns the index of the new rule */ static void emit_rule(Reserve r, int32_t op, int32_t n, const uint32_t *body) { janet_assert(r.size == n + 1, "bad reserve"); r.builder->bytecode[r.index] = op; memcpy(r.builder->bytecode + r.index + 1, body, n * sizeof(uint32_t)); } /* For RULE_LITERAL */ static void emit_bytes(Builder *b, uint32_t op, int32_t len, const uint8_t *bytes) { uint32_t next_rule = janet_v_count(b->bytecode); janet_v_push(b->bytecode, op); janet_v_push(b->bytecode, len); int32_t words = ((len + 3) >> 2); for (int32_t i = 0; i < words; i++) janet_v_push(b->bytecode, 0); memcpy(b->bytecode + next_rule + 2, bytes, len); } /* For fixed arity rules of arities 1, 2, and 3 */ static void emit_1(Reserve r, uint32_t op, uint32_t arg) { emit_rule(r, op, 1, &arg); } static void emit_2(Reserve r, uint32_t op, uint32_t arg1, uint32_t arg2) { uint32_t arr[2] = {arg1, arg2}; emit_rule(r, op, 2, arr); } static void emit_3(Reserve r, uint32_t op, uint32_t arg1, uint32_t arg2, uint32_t arg3) { uint32_t arr[3] = {arg1, arg2, arg3}; emit_rule(r, op, 3, arr); } /* * Specials */ static void bitmap_set(uint32_t *bitmap, uint8_t c) { bitmap[c >> 5] |= ((uint32_t)1) << (c & 0x1F); } static void spec_range(Builder *b, int32_t argc, const Janet *argv) { peg_arity(b, argc, 1, -1); if (argc == 1) { Reserve r = reserve(b, 2); const uint8_t *str = peg_getrange(b, argv[0]); uint32_t arg = str[0] | (str[1] << 16); emit_1(r, RULE_RANGE, arg); } else { /* Compile as a set */ Reserve r = reserve(b, 9); uint32_t bitmap[8] = {0}; for (int32_t i = 0; i < argc; i++) { const uint8_t *str = peg_getrange(b, argv[i]); for (uint32_t c = str[0]; c <= str[1]; c++) bitmap_set(bitmap, c); } emit_rule(r, RULE_SET, 8, bitmap); } } static void spec_set(Builder *b, int32_t argc, const Janet *argv) { peg_fixarity(b, argc, 1); Reserve r = reserve(b, 9); const uint8_t *str = peg_getset(b, argv[0]); uint32_t bitmap[8] = {0}; for (int32_t i = 0; i < janet_string_length(str); i++) bitmap_set(bitmap, str[i]); emit_rule(r, RULE_SET, 8, bitmap); } static void spec_look(Builder *b, int32_t argc, const Janet *argv) { peg_arity(b, argc, 1, 2); Reserve r = reserve(b, 3); int32_t rulearg = argc == 2 ? 1 : 0; int32_t offset = argc == 2 ? peg_getinteger(b, argv[0]) : 0; uint32_t subrule = peg_compile1(b, argv[rulearg]); emit_2(r, RULE_LOOK, (uint32_t) offset, subrule); } /* Rule of the form [len, rules...] */ static void spec_variadic(Builder *b, int32_t argc, const Janet *argv, uint32_t op) { uint32_t rule = janet_v_count(b->bytecode); janet_v_push(b->bytecode, op); janet_v_push(b->bytecode, argc); for (int32_t i = 0; i < argc; i++) janet_v_push(b->bytecode, 0); for (int32_t i = 0; i < argc; i++) { uint32_t rulei = peg_compile1(b, argv[i]); b->bytecode[rule + 2 + i] = rulei; } } static void spec_choice(Builder *b, int32_t argc, const Janet *argv) { spec_variadic(b, argc, argv, RULE_CHOICE); } static void spec_sequence(Builder *b, int32_t argc, const Janet *argv) { spec_variadic(b, argc, argv, RULE_SEQUENCE); } /* For (if a b) and (if-not a b) */ static void spec_branch(Builder *b, int32_t argc, const Janet *argv, uint32_t rule) { peg_fixarity(b, argc, 2); Reserve r = reserve(b, 3); uint32_t rule_a = peg_compile1(b, argv[0]); uint32_t rule_b = peg_compile1(b, argv[1]); emit_2(r, rule, rule_a, rule_b); } static void spec_if(Builder *b, int32_t argc, const Janet *argv) { spec_branch(b, argc, argv, RULE_IF); } static void spec_ifnot(Builder *b, int32_t argc, const Janet *argv) { spec_branch(b, argc, argv, RULE_IFNOT); } static void spec_between(Builder *b, int32_t argc, const Janet *argv) { peg_fixarity(b, argc, 3); Reserve r = reserve(b, 4); int32_t lo = peg_getnat(b, argv[0]); int32_t hi = peg_getnat(b, argv[1]); uint32_t subrule = peg_compile1(b, argv[2]); emit_3(r, RULE_BETWEEN, lo, hi, subrule); } static void spec_repeater(Builder *b, int32_t argc, const Janet *argv, int32_t min) { peg_fixarity(b, argc, 1); Reserve r = reserve(b, 4); uint32_t subrule = peg_compile1(b, argv[0]); emit_3(r, RULE_BETWEEN, min, UINT32_MAX, subrule); } static void spec_some(Builder *b, int32_t argc, const Janet *argv) { spec_repeater(b, argc, argv, 1); } static void spec_any(Builder *b, int32_t argc, const Janet *argv) { spec_repeater(b, argc, argv, 0); } static void spec_atleast(Builder *b, int32_t argc, const Janet *argv) { peg_fixarity(b, argc, 2); Reserve r = reserve(b, 4); int32_t n = peg_getnat(b, argv[0]); uint32_t subrule = peg_compile1(b, argv[1]); emit_3(r, RULE_BETWEEN, n, UINT32_MAX, subrule); } static void spec_atmost(Builder *b, int32_t argc, const Janet *argv) { peg_fixarity(b, argc, 2); Reserve r = reserve(b, 4); int32_t n = peg_getnat(b, argv[0]); uint32_t subrule = peg_compile1(b, argv[1]); emit_3(r, RULE_BETWEEN, 0, n, subrule); } static void spec_opt(Builder *b, int32_t argc, const Janet *argv) { peg_fixarity(b, argc, 1); Reserve r = reserve(b, 4); uint32_t subrule = peg_compile1(b, argv[0]); emit_3(r, RULE_BETWEEN, 0, 1, subrule); } /* Rule of the form [rule] */ static void spec_onerule(Builder *b, int32_t argc, const Janet *argv, uint32_t op) { peg_fixarity(b, argc, 1); Reserve r = reserve(b, 2); uint32_t rule = peg_compile1(b, argv[0]); emit_1(r, op, rule); } static void spec_not(Builder *b, int32_t argc, const Janet *argv) { spec_onerule(b, argc, argv, RULE_NOT); } static void spec_error(Builder *b, int32_t argc, const Janet *argv) { spec_onerule(b, argc, argv, RULE_ERROR); } static void spec_drop(Builder *b, int32_t argc, const Janet *argv) { spec_onerule(b, argc, argv, RULE_DROP); } /* Rule of the form [rule, tag] */ static void spec_cap1(Builder *b, int32_t argc, const Janet *argv, uint32_t op) { peg_arity(b, argc, 1, 2); Reserve r = reserve(b, 3); uint32_t tag = (argc == 2) ? emit_tag(b, argv[1]) : 0; uint32_t rule = peg_compile1(b, argv[0]); emit_2(r, op, rule, tag); } static void spec_capture(Builder *b, int32_t argc, const Janet *argv) { spec_cap1(b, argc, argv, RULE_CAPTURE); } static void spec_accumulate(Builder *b, int32_t argc, const Janet *argv) { spec_cap1(b, argc, argv, RULE_ACCUMULATE); } static void spec_group(Builder *b, int32_t argc, const Janet *argv) { spec_cap1(b, argc, argv, RULE_GROUP); } static void spec_reference(Builder *b, int32_t argc, const Janet *argv) { peg_arity(b, argc, 1, 2); Reserve r = reserve(b, 3); uint32_t search = emit_tag(b, argv[0]); uint32_t tag = (argc == 2) ? emit_tag(b, argv[1]) : 0; emit_2(r, RULE_GETTAG, search, tag); } static void spec_position(Builder *b, int32_t argc, const Janet *argv) { peg_arity(b, argc, 0, 1); Reserve r = reserve(b, 2); uint32_t tag = (argc) ? emit_tag(b, argv[0]) : 0; (void) argv; emit_1(r, RULE_POSITION, tag); } static void spec_argument(Builder *b, int32_t argc, const Janet *argv) { peg_arity(b, argc, 1, 2); Reserve r = reserve(b, 3); uint32_t tag = (argc == 2) ? emit_tag(b, argv[1]) : 0; int32_t index = peg_getnat(b, argv[0]); emit_2(r, RULE_ARGUMENT, index, tag); } static void spec_constant(Builder *b, int32_t argc, const Janet *argv) { janet_arity(argc, 1, 2); Reserve r = reserve(b, 3); uint32_t tag = (argc == 2) ? emit_tag(b, argv[1]) : 0; emit_2(r, RULE_CONSTANT, emit_constant(b, argv[0]), tag); } static void spec_replace(Builder *b, int32_t argc, const Janet *argv) { peg_arity(b, argc, 2, 3); Reserve r = reserve(b, 4); uint32_t subrule = peg_compile1(b, argv[0]); uint32_t constant = emit_constant(b, argv[1]); uint32_t tag = (argc == 3) ? emit_tag(b, argv[2]) : 0; emit_3(r, RULE_REPLACE, subrule, constant, tag); } static void spec_matchtime(Builder *b, int32_t argc, const Janet *argv) { peg_arity(b, argc, 2, 3); Reserve r = reserve(b, 4); uint32_t subrule = peg_compile1(b, argv[0]); Janet fun = argv[1]; if (!janet_checktype(fun, JANET_FUNCTION) && !janet_checktype(fun, JANET_CFUNCTION)) { peg_panicf(b, "expected function|cfunction, got %v", fun); } uint32_t tag = (argc == 3) ? emit_tag(b, argv[2]) : 0; uint32_t cindex = emit_constant(b, fun); emit_3(r, RULE_MATCHTIME, subrule, cindex, tag); } /* Special compiler form */ typedef void (*Special)(Builder *b, int32_t argc, const Janet *argv); typedef struct { const char *name; Special special; } SpecialPair; /* Keep in lexical order (vim :sort works well) */ static const SpecialPair peg_specials[] = { {"!", spec_not}, {"$", spec_position}, {"%", spec_accumulate}, {"*", spec_sequence}, {"+", spec_choice}, {"->", spec_reference}, {"/", spec_replace}, {"<-", spec_capture}, {">", spec_look}, {"?", spec_opt}, {"accumulate", spec_accumulate}, {"any", spec_any}, {"argument", spec_argument}, {"at-least", spec_atleast}, {"at-most", spec_atmost}, {"backref", spec_reference}, {"between", spec_between}, {"capture", spec_capture}, {"choice", spec_choice}, {"cmt", spec_matchtime}, {"constant", spec_constant}, {"drop", spec_drop}, {"error", spec_error}, {"group", spec_group}, {"if", spec_if}, {"if-not", spec_ifnot}, {"look", spec_look}, {"not", spec_not}, {"opt", spec_opt}, {"position", spec_position}, {"quote", spec_capture}, {"range", spec_range}, {"replace", spec_replace}, {"sequence", spec_sequence}, {"set", spec_set}, {"some", spec_some}, }; /* Compile a janet value into a rule and return the rule index. */ static uint32_t peg_compile1(Builder *b, Janet peg) { /* Check for already compiled rules */ Janet check = janet_table_get(b->memoized, peg); if (!janet_checktype(check, JANET_NIL)) { uint32_t rule = (uint32_t) janet_unwrap_number(check); return rule; } /* Keep track of the form being compiled for error purposes */ Janet old_form = b->form; b->form = peg; /* Check depth */ if (b->depth-- == 0) { peg_panic(b, "peg grammar recursed too deeply"); } /* The final rule to return */ uint32_t rule = janet_v_count(b->bytecode); if (!janet_checktype(peg, JANET_KEYWORD) && !janet_checktype(peg, JANET_STRUCT)) { janet_table_put(b->memoized, peg, janet_wrap_number(rule)); } switch (janet_type(peg)) { default: peg_panic(b, "unexpected peg source"); return 0; case JANET_NUMBER: { int32_t n = peg_getinteger(b, peg); Reserve r = reserve(b, 2); if (n < 0) { emit_1(r, RULE_NOTNCHAR, -n); } else { emit_1(r, RULE_NCHAR, n); } break; } case JANET_STRING: { const uint8_t *str = janet_unwrap_string(peg); int32_t len = janet_string_length(str); emit_bytes(b, RULE_LITERAL, len, str); break; } case JANET_KEYWORD: { Janet check = janet_table_get(b->grammar, peg); if (janet_checktype(check, JANET_NIL)) peg_panic(b, "unknown rule"); rule = peg_compile1(b, check); break; } case JANET_STRUCT: { JanetTable *grammar = janet_struct_to_table(janet_unwrap_struct(peg)); grammar->proto = b->grammar; b->grammar = grammar; Janet main_rule = janet_table_get(grammar, janet_ckeywordv("main")); if (janet_checktype(main_rule, JANET_NIL)) peg_panic(b, "grammar requires :main rule"); rule = peg_compile1(b, main_rule); b->grammar = grammar->proto; break; } case JANET_TUPLE: { const Janet *tup = janet_unwrap_tuple(peg); int32_t len = janet_tuple_length(tup); if (len == 0) peg_panic(b, "tuple in grammar must have non-zero length"); if (!janet_checktype(tup[0], JANET_SYMBOL)) peg_panicf(b, "expected grammar command, found %v", tup[0]); const uint8_t *sym = janet_unwrap_symbol(tup[0]); const SpecialPair *sp = janet_strbinsearch( &peg_specials, sizeof(peg_specials) / sizeof(SpecialPair), sizeof(SpecialPair), sym); if (sp) { sp->special(b, len - 1, tup + 1); } else { peg_panicf(b, "unknown special %S", sym); } break; } } /* Increase depth again */ b->depth++; b->form = old_form; return rule; } /* * Post-Compilation */ typedef struct { uint32_t *bytecode; Janet *constants; uint32_t num_constants; } Peg; static int peg_mark(void *p, size_t size) { (void) size; Peg *peg = (Peg *)p; for (uint32_t i = 0; i < peg->num_constants; i++) janet_mark(peg->constants[i]); return 0; } static JanetAbstractType peg_type = { "core/peg", NULL, peg_mark, NULL, NULL, NULL, NULL, NULL }; /* Used to ensure that if we place several arrays in one memory chunk, each * array will be correctly aligned */ static size_t size_padded(size_t offset, size_t size) { size_t x = size + offset - 1; return x - (x % size); } /* Convert Builder to Peg (Janet Abstract Value) */ static Peg *make_peg(Builder *b) { size_t bytecode_start = size_padded(sizeof(Peg), sizeof(uint32_t)); size_t bytecode_size = janet_v_count(b->bytecode) * sizeof(uint32_t); size_t constants_start = size_padded(bytecode_start + bytecode_size, sizeof(Janet)); size_t constants_size = janet_v_count(b->constants) * sizeof(Janet); size_t total_size = constants_start + constants_size; char *mem = janet_abstract(&peg_type, total_size); Peg *peg = (Peg *)mem; peg->bytecode = (uint32_t *)(mem + bytecode_start); peg->constants = (Janet *)(mem + constants_start); peg->num_constants = janet_v_count(b->constants); memcpy(peg->bytecode, b->bytecode, bytecode_size); memcpy(peg->constants, b->constants, constants_size); return peg; } /* Compiler entry point */ static Peg *compile_peg(Janet x) { Builder builder; builder.grammar = janet_table(0); builder.memoized = janet_table(0); builder.tags = janet_table(0); builder.constants = NULL; builder.bytecode = NULL; builder.nexttag = 1; builder.form = x; builder.depth = JANET_RECURSION_GUARD; peg_compile1(&builder, x); Peg *peg = make_peg(&builder); builder_cleanup(&builder); return peg; } /* * C Functions */ static Janet cfun_peg_compile(int32_t argc, Janet *argv) { janet_fixarity(argc, 1); Peg *peg = compile_peg(argv[0]); return janet_wrap_abstract(peg); } static Janet cfun_peg_match(int32_t argc, Janet *argv) { janet_arity(argc, 2, -1); Peg *peg; if (janet_checktype(argv[0], JANET_ABSTRACT) && janet_abstract_type(janet_unwrap_abstract(argv[0])) == &peg_type) { peg = janet_unwrap_abstract(argv[0]); } else { peg = compile_peg(argv[0]); } JanetByteView bytes = janet_getbytes(argv, 1); int32_t start; PegState s; if (argc > 2) { start = janet_gethalfrange(argv, 2, bytes.len, "offset"); s.extrac = argc - 3; s.extrav = janet_tuple_n(argv + 3, argc - 3); } else { start = 0; s.extrac = 0; s.extrav = NULL; } s.mode = PEG_MODE_NORMAL; s.text_start = bytes.bytes; s.text_end = bytes.bytes + bytes.len; s.depth = JANET_RECURSION_GUARD; s.captures = janet_array(0); s.scratch = janet_buffer(10); s.tags = janet_buffer(10); s.constants = peg->constants; s.bytecode = peg->bytecode; const uint8_t *result = peg_rule(&s, s.bytecode, bytes.bytes + start); return result ? janet_wrap_array(s.captures) : janet_wrap_nil(); } static const JanetReg peg_cfuns[] = { { "peg/compile", cfun_peg_compile, JDOC("(peg/compile peg)\n\n" "Compiles a peg source data structure into a . This will speed up matching " "if the same peg will be used multiple times.") }, { "peg/match", cfun_peg_match, JDOC("(peg/match peg text [,start=0])\n\n" "Match a Parsing Expression Grammar to a byte string and return an array of captured values. " "Returns nil if text does not match the language defined by peg. The syntax of PEGs are very " "similar to those defined by LPeg, and have similar capabilities.") }, {NULL, NULL, NULL} }; /* Load the peg module */ void janet_lib_peg(JanetTable *env) { janet_core_cfuns(env, NULL, peg_cfuns); } #endif /* ifdef JANET_PEG */