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pull from: josh:c-backend
Branches Tags
josh:master
josh:wip
josh:c-backend
josh:sumtype
josh:v1.5.1
josh:v1.5.0
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josh:v1.3.0
josh:v1.2.0
josh:v1.1.0
josh:v1.0.0

14 Commits
master ... c-backend

Author SHA1 Message Date
Josh Holtrop
06af7fbe3b wip 2023-08-20 21:22:34 -04:00
Josh Holtrop
9760da4df4 wip 2023-08-20 21:19:34 -04:00
Josh Holtrop
35acdde09f generates a parser specs passing 2023-08-20 20:49:24 -04:00
Josh Holtrop
aef5367378 Get test_lexer_unknown_character working for C 2023-08-20 18:43:33 -04:00
Josh Holtrop
36213d9e9c wip 2023-08-20 17:25:48 -04:00
Josh Holtrop
7b1d903b00 wip 2023-08-20 16:58:02 -04:00
Josh Holtrop
59e8e0a095 wip 2023-08-20 16:56:00 -04:00
Josh Holtrop
dace12310a wip 2023-08-20 16:53:54 -04:00
Josh Holtrop
c7185edef0 Add spec support for C tests 2023-08-20 16:38:35 -04:00
Josh Holtrop
9d2b3be20b Determine output language by output file extension 2023-08-20 16:27:58 -04:00
Josh Holtrop
2b515e1a7a wip 2023-08-20 16:13:18 -04:00
Josh Holtrop
4ffdea07bb wip 2023-08-08 22:43:46 -04:00
Josh Holtrop
cdb6294f1f wip 2023-08-06 11:49:26 -04:00
Josh Holtrop
48b4033ef2 wip 2023-08-02 21:36:43 -04:00
22 changed files with 1894 additions and 183 deletions
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938
assets/parser.c.erb Normal file
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#include "<%= File.basename(output_file).sub(%r{\.[a-z]+$}, "") %>.h"
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
/**************************************************************************
* User code blocks
*************************************************************************/
<% @grammar.code_blocks.each do |code| %>
<%= code %>
<% end %>
/**************************************************************************
* Private types
*************************************************************************/
<% if @grammar.prefix.upcase != "P_" %>
/* Result codes. */
#define P_SUCCESS 0u
#define P_DECODE_ERROR 1u
#define P_UNEXPECTED_INPUT 2u
#define P_UNEXPECTED_TOKEN 3u
#define P_DROP 4u
#define P_EOF 5u
<% end %>
/* An invalid ID value. */
#define INVALID_ID ((size_t)-1)
/**************************************************************************
* State initialization
*************************************************************************/
/**
* Initialize lexer/parser context structure.
*
* @param[out] context
* Lexer/parser context structure.
* @param input
* Text input.
* @param input_length
* Text input length.
*/
void <%= @grammar.prefix %>context_init(<%= @grammar.prefix %>context_t * context, uint8_t const * input, size_t input_length)
{
/* New default-initialized context structure. */
<%= @grammar.prefix %>context_t newcontext = {0};
/* Lexer initialization. */
newcontext.input = input;
newcontext.input_length = input_length;
newcontext.mode = <%= @lexer.mode_id("default") %>;
/* Copy to the user's context structure. */
*context = newcontext;
}
/**************************************************************************
* Decoder
*************************************************************************/
/**
* Decode a UTF-8 code point.
*
* @param input
* Text input to decode.
* @param input_length
* Input text length.
* @param[out] out_code_point
* The decoded code point is stored here if the return value is P_SUCCESS.
* @param[out] out_code_point_length
* The number of bytes the code point used is stored here if the return value
* is P_SUCCESS.
*
* @retval P_SUCCESS on a successful code point decode
* @retval P_DECODE_ERROR when an encoding error is observed
* @retval P_EOF when the end of the text input is reached
*/
size_t <%= @grammar.prefix %>decode_code_point(uint8_t const * input, size_t input_length,
<%= @grammar.prefix %>code_point_t * out_code_point, uint8_t * out_code_point_length)
{
if (input_length == 0u)
{
return P_EOF;
}
char c = input[0];
<%= @grammar.prefix %>code_point_t code_point;
uint8_t code_point_length;
if ((c & 0x80u) == 0u)
{
code_point = c;
code_point_length = 1u;
}
else
{
uint8_t following_bytes;
if ((c & 0xE0u) == 0xC0u)
{
code_point = c & 0x1Fu;
following_bytes = 1u;
}
else if ((c & 0xF0u) == 0xE0u)
{
code_point = c & 0x0Fu;
following_bytes = 2u;
}
else if ((c & 0xF8u) == 0xF0u)
{
code_point = c & 0x07u;
following_bytes = 3u;
}
else if ((c & 0xFCu) == 0xF8u)
{
code_point = c & 0x03u;
following_bytes = 4u;
}
else if ((c & 0xFEu) == 0xFCu)
{
code_point = c & 0x01u;
following_bytes = 5u;
}
else
{
return P_DECODE_ERROR;
}
if (input_length <= following_bytes)
{
return P_DECODE_ERROR;
}
code_point_length = (uint8_t)(following_bytes + 1u);
for (size_t i = 0u; i < following_bytes; i++)
{
char b = input[i + 1u];
if ((b & 0xC0u) != 0x80u)
{
return P_DECODE_ERROR;
}
code_point = (code_point << 6u) | (b & 0x3Fu);
}
}
*out_code_point = code_point;
*out_code_point_length = code_point_length;
return P_SUCCESS;
}
/**************************************************************************
* Lexer
*************************************************************************/
/** Lexer state ID type. */
typedef <%= get_type_for(@lexer.state_table.size) %> lexer_state_id_t;
/** Invalid lexer state ID. */
#define INVALID_LEXER_STATE_ID <%= @lexer.state_table.size %>u
/** Lexer user code ID type. */
<% user_code_id_count = (@grammar.patterns.map(&:code_id).compact.max || 0) + 1 %>
typedef <%= get_type_for(user_code_id_count) %> lexer_user_code_id_t;
/** Invalid lexer user code ID. */
#define INVALID_USER_CODE_ID <%= user_code_id_count %>u
/**
* Lexer transition table entry.
*
* An incoming code point matching the range for a transition entry will cause
* the lexer to progress to the destination state.
*/
typedef struct
{
/** First code point in the range for this transition. */
<%= @grammar.prefix %>code_point_t first;
/** Last code point in the range for this transition. */
<%= @grammar.prefix %>code_point_t last;
/** Destination lexer state ID for this transition. */
lexer_state_id_t destination_state;
} lexer_transition_t;
/** Lexer state table entry. */
typedef struct
{
/** Index to the transition table for this state. */
<%= get_type_for(@lexer.transition_table.size - 1) %> transition_table_index;
/** Number of transition table entries for this state. */
<%= get_type_for(@lexer.state_table.map {|ste| ste[:n_transitions]}.max) %> n_transitions;
/** Lexer token formed at this state. */
<%= @grammar.prefix %>token_t token;
/** Lexer user code ID to execute at this state. */
lexer_user_code_id_t code_id;
/** Whether this state matches a lexer pattern. */
bool accepts;
} lexer_state_t;
/** Lexer mode table entry. */
typedef struct
{
/** Offset in the state table to be used for this mode. */
uint32_t state_table_offset;
} lexer_mode_t;
/**
* Lexer match info structure.
*
* This structure holds output values from the lexer upon a successful pattern
* match.
*/
typedef struct
{
/** Number of bytes of input text used to match. */
size_t length;
/** Input text position delta. */
<%= @grammar.prefix %>position_t delta_position;
/** Accepting lexer state from the match. */
lexer_state_t const * accepting_state;
} lexer_match_info_t;
/** Lexer transition table. */
static lexer_transition_t lexer_transition_table[] = {
<% @lexer.transition_table.each do |transition_table_entry| %>
{<%= transition_table_entry[:first] %>u, <%= transition_table_entry[:last] %>u, <%= transition_table_entry[:destination] %>u},
<% end %>
};
/** Lexer state table. */
static lexer_state_t lexer_state_table[] = {
<% @lexer.state_table.each do |state_table_entry| %>
{<%= state_table_entry[:transition_table_index] %>u, <%= state_table_entry[:n_transitions] %>u, <%= state_table_entry[:token] || "INVALID_TOKEN_ID" %>, <%= state_table_entry[:code_id] || "INVALID_USER_CODE_ID" %>, <%= state_table_entry[:accepts] %>},
<% end %>
};
/** Lexer mode table. */
static lexer_mode_t lexer_mode_table[] = {
<% @lexer.mode_table.each do |mode_table_entry| %>
{<%= mode_table_entry[:state_table_offset] %>},
<% end %>
};
/**
* Execute user code associated with a lexer pattern.
*
* @param context
* Lexer/parser context structure.
* @param code_id
* The ID of the user code block to execute.
* @param match
* Matched text for this pattern.
* @param match_length
* Matched text length.
* @param out_token_info
* Lexer token info in progress.
*
* @return Token to accept, or invalid token if the user code does
* not explicitly return a token.
*/
static <%= @grammar.prefix %>token_t lexer_user_code(<%= @grammar.prefix %>context_t * context,
lexer_user_code_id_t code_id, uint8_t const * match,
size_t match_length, <%= @grammar.prefix %>token_info_t * out_token_info)
{
switch (code_id)
{
<% @grammar.patterns.each do |pattern| %>
<% if pattern.code_id %>
case <%= pattern.code_id %>u: {
<%= expand_code(pattern.code, false, nil, pattern) %>
} break;
<% end %>
<% end %>
default: break;
}
return INVALID_TOKEN_ID;
}
/**
* Check if there is a transition from the current lexer state to another
* based on the given input code point.
*
* @param current_state
* Current lexer state.
* @param code_point
* Input code point.
*
* @return Lexer state to transition to, or INVALID_LEXER_STATE_ID if none.
*/
static lexer_state_id_t check_lexer_transition(uint32_t current_state, uint32_t code_point)
{
uint32_t transition_table_index = lexer_state_table[current_state].transition_table_index;
for (uint32_t i = 0u; i < lexer_state_table[current_state].n_transitions; i++)
{
if ((lexer_transition_table[transition_table_index + i].first <= code_point) &&
(code_point <= lexer_transition_table[transition_table_index + i].last))
{
return lexer_transition_table[transition_table_index + i].destination_state;
}
}
return INVALID_LEXER_STATE_ID;
}
/**
* Find the longest lexer pattern match at the current position.
*
* @param context
* Lexer/parser context structure.
* @param[out] out_token_info
* The lexed token information is stored here if the return value is
* P_SUCCESS.
*
* @reval P_SUCCESS
* A token was successfully lexed.
* @reval P_DECODE_ERROR
* The decoder encountered invalid text encoding.
* @reval P_UNEXPECTED_INPUT
* Input text does not match any lexer pattern.
* @retval P_EOF
* The end of the text input was reached.
*/
static size_t find_longest_match(<%= @grammar.prefix %>context_t * context,
lexer_match_info_t * out_match_info, size_t * out_unexpected_input_length)
{
lexer_match_info_t longest_match = {0};
lexer_match_info_t attempt_match = {0};
*out_match_info = longest_match;
uint32_t current_state = lexer_mode_table[context->mode].state_table_offset;
for (;;)
{
size_t const input_index = context->input_index + attempt_match.length;
uint8_t const * input = &context->input[input_index];
size_t input_length = context->input_length - input_index;
<%= @grammar.prefix %>code_point_t code_point;
uint8_t code_point_length;
size_t result = <%= @grammar.prefix %>decode_code_point(input, input_length, &code_point, &code_point_length);
switch (result)
{
case P_SUCCESS:
lexer_state_id_t transition_state = check_lexer_transition(current_state, code_point);
if (transition_state != INVALID_LEXER_STATE_ID)
{
attempt_match.length += code_point_length;
if (code_point == '\n')
{
attempt_match.delta_position.row++;
attempt_match.delta_position.col = 0u;
}
else
{
attempt_match.delta_position.col++;
}
current_state = transition_state;
if (lexer_state_table[current_state].accepts)
{
attempt_match.accepting_state = &lexer_state_table[current_state];
longest_match = attempt_match;
}
}
else if (longest_match.length > 0)
{
*out_match_info = longest_match;
return P_SUCCESS;
}
else
{
*out_unexpected_input_length = attempt_match.length + code_point_length;
return P_UNEXPECTED_INPUT;
}
break;
case P_EOF:
/* We hit EOF. */
if (longest_match.length > 0)
{
/* We have a match, so use it. */
*out_match_info = longest_match;
return P_SUCCESS;
}
else if (attempt_match.length != 0)
{
/* There is a partial match - error! */
*out_unexpected_input_length = attempt_match.length;
return P_UNEXPECTED_INPUT;
}
else
{
/* Valid EOF return. */
return P_EOF;
}
break;
case P_DECODE_ERROR:
/* If we see a decode error, we may be partially in the middle of
* matching a pattern, so return the attempted match info so that
* the input text position can be updated. */
*out_match_info = attempt_match;
return result;
default:
return result;
}
}
}
/**
* Attempt to lex the next token in the input stream.
*
* @param context
* Lexer/parser context structure.
* @param[out] out_token_info
* The lexed token information is stored here if the return value is
* P_SUCCESS.
*
* @reval P_SUCCESS
* A token was successfully lexed.
* @reval P_DECODE_ERROR
* The decoder encountered invalid text encoding.
* @reval P_UNEXPECTED_INPUT
* Input text does not match any lexer pattern.
* @retval P_DROP
* A drop pattern was matched so the lexer should continue.
*/
static size_t attempt_lex_token(<%= @grammar.prefix %>context_t * context, <%= @grammar.prefix %>token_info_t * out_token_info)
{
<%= @grammar.prefix %>token_info_t token_info = {0};
token_info.position = context->text_position;
token_info.token = INVALID_TOKEN_ID;
*out_token_info = token_info; // TODO: remove
lexer_match_info_t match_info;
size_t unexpected_input_length;
size_t result = find_longest_match(context, &match_info, &unexpected_input_length);
switch (result)
{
case P_SUCCESS:
<%= @grammar.prefix %>token_t token_to_accept = match_info.accepting_state->token;
if (match_info.accepting_state->code_id != INVALID_USER_CODE_ID)
{
uint8_t const * match = &context->input[context->input_index];
<%= @grammar.prefix %>token_t user_code_token = lexer_user_code(context,
match_info.accepting_state->code_id, match, match_info.length, &token_info);
/* An invalid token returned from lexer_user_code() means that the
* user code did not explicitly return a token. So only override
* the token to return if the user code does explicitly return a
* token. */
if (user_code_token != INVALID_TOKEN_ID)
{
token_to_accept = user_code_token;
}
}
/* Update the input position tracking. */
context->input_index += match_info.length;
context->text_position.row += match_info.delta_position.row;
if (match_info.delta_position.row != 0u)
{
context->text_position.col = match_info.delta_position.col;
}
else
{
context->text_position.col += match_info.delta_position.col;
}
if (token_to_accept == INVALID_TOKEN_ID)
{
return P_DROP;
}
token_info.token = token_to_accept;
token_info.length = match_info.length;
*out_token_info = token_info;
return P_SUCCESS;
case P_EOF:
token_info.token = TOKEN___EOF;
*out_token_info = token_info;
return P_SUCCESS;
case P_DECODE_ERROR:
/* Update the input position tracking. */
context->input_index += match_info.length;
context->text_position.row += match_info.delta_position.row;
if (match_info.delta_position.row != 0u)
{
context->text_position.col = match_info.delta_position.col;
}
else
{
context->text_position.col += match_info.delta_position.col;
}
return result;
default:
return result;
}
}
/**
* Lex the next token in the input stream.
*
* @param context
* Lexer/parser context structure.
* @param[out] out_token_info
* The lexed token information is stored here if the return value is
* P_SUCCESS.
*
* @reval P_SUCCESS
* A token was successfully lexed.
* @reval P_DECODE_ERROR
* The decoder encountered invalid text encoding.
* @reval P_UNEXPECTED_INPUT
* Input text does not match any lexer pattern.
*/
size_t <%= @grammar.prefix %>lex(<%= @grammar.prefix %>context_t * context, <%= @grammar.prefix %>token_info_t * out_token_info)
{
for (;;)
{
size_t result = attempt_lex_token(context, out_token_info);
if (result != P_DROP)
{
return result;
}
}
}
/**************************************************************************
* Parser
*************************************************************************/
/** Reduce ID type. */
typedef <%= get_type_for(@parser.reduce_table.size) %> reduce_id_t;
/**
* A symbol ID can hold either a token ID or a rule set ID.
*
* Token IDs and rule set IDs share the same namespace, with rule set IDs
* beginning after token IDs end.
*/
typedef <%= get_type_for(@parser.rule_sets.map(&:last).map(&:id).max) %> symbol_id_t;
/** Parser state ID type. */
typedef <%= get_type_for(@parser.state_table.size) %> parser_state_id_t;
/** Parser rule ID type. */
typedef <%= get_type_for(@grammar.rules.size) %> rule_id_t;
/** Parser shift ID type. */
typedef <%= get_type_for(@parser.shift_table.size) %> shift_id_t;
/** Shift table entry. */
typedef struct
{
/** Token or rule set ID. */
symbol_id_t symbol_id;
/** Parser state to shift to. */
parser_state_id_t state_id;
} shift_t;
/** Reduce table entry. */
typedef struct
{
/** Lookahead token. */
<%= @grammar.prefix %>token_t token;
/**
* Rule ID.
*
* This is used to execute the parser user code block associated with a
* grammar rule.
*/
rule_id_t rule;
/**
* Rule set ID.
*
* This is used as the new top symbol ID of the parse stack after this
* reduce action.
*/
symbol_id_t rule_set;
/**
* Number of states leading to this reduce action.
*
* This is the number of entries popped from the parse stack after this
* reduce action.
*/
parser_state_id_t n_states;
} reduce_t;
/** Parser state entry. */
typedef struct
{
/** First shift table entry for this parser state. */
shift_id_t shift_table_index;
/** Number of shift table entries for this parser state. */
shift_id_t n_shift_entries;
/** First reduce table entry for this parser state. */
reduce_id_t reduce_table_index;
/** Number of reduce table entries for this parser state. */
reduce_id_t n_reduce_entries;
} parser_state_t;
/**
* Structure to hold a state ID and value pair.
*
* A stack of these structures makes up the parse stack.
*/
typedef struct
{
/** Parser state ID. */
size_t state_id;
/** Parser value from this state. */
<%= @grammar.prefix %>value_t pvalue;
} state_value_t;
/** Parser shift table. */
static const shift_t parser_shift_table[] = {
<% @parser.shift_table.each do |shift| %>
{<%= shift[:symbol_id] %>u, <%= shift[:state_id] %>u},
<% end %>
};
/** Parser reduce table. */
static const reduce_t parser_reduce_table[] = {
<% @parser.reduce_table.each do |reduce| %>
{<%= reduce[:token_id] %>u, <%= reduce[:rule_id] %>u, <%= reduce[:rule_set_id] %>u, <%= reduce[:n_states] %>u},
<% end %>
};
/** Parser state table. */
static const parser_state_t parser_state_table[] = {
<% @parser.state_table.each do |state| %>
{<%= state[:shift_index] %>u, <%= state[:n_shifts] %>u, <%= state[:reduce_index] %>u, <%= state[:n_reduces] %>u},
<% end %>
};
/* state_values stack functionality */
/** state_values stack type. */
typedef struct
{
size_t length;
size_t capacity;
state_value_t * entries;
} state_values_stack_t;
/**
* Initialize state_values stack structure.
*
* @param stack
* state_values stack structure.
*/
static void state_values_stack_init(state_values_stack_t * stack)
{
const size_t initial_capacity = 10u;
stack->length = 0u;
stack->capacity = initial_capacity;
stack->entries = (state_value_t *)malloc(initial_capacity * sizeof(state_value_t));
}
/**
* Index a state_values stack.
*
* @param stack
* state_values stack structure.
* @param index
* Index to the stack.
*
* @return Pointer to the state value structure at the given index.
*/
static state_value_t * state_values_stack_index(state_values_stack_t * stack, int index)
{
if (index >= 0)
{
return &stack->entries[index];
}
else
{
return &stack->entries[stack->length - (size_t)(unsigned int)(-index)];
}
}
/**
* Push a new state_value to the state_values stack.
*
* @param stack
* state_values stack structure.
*/
static void state_values_stack_push(state_values_stack_t * stack)
{
size_t const current_capacity = stack->capacity;
size_t const current_length = stack->length;
if (current_length >= current_capacity)
{
size_t const new_capacity = current_capacity * 2u;
state_value_t * new_entries = malloc(new_capacity * sizeof(state_value_t));
memcpy(new_entries, stack->entries, current_length * sizeof(state_value_t));
free(stack->entries);
stack->capacity = new_capacity;
stack->entries = new_entries;
}
memset(&stack->entries[current_length], 0, sizeof(state_value_t));
stack->length = current_length + 1u;
}
/**
* Pop entries from a state_values stack.
*
* @param stack
* state_values stack structure.
* @param n
* Number of states to pop.
*/
static void state_values_stack_pop(state_values_stack_t * stack, size_t n)
{
stack->length -= n;
}
/**
* Free memory for a state_values stack structure.
*
* @param stack
* state_values stack structure.
*/
static void state_values_stack_free(state_values_stack_t * stack)
{
free(stack->entries);
}
/**
* Execute user code associated with a parser rule.
*
* @param rule The ID of the rule.
*
* @return Parse value.
*/
static <%= @grammar.prefix %>value_t parser_user_code(uint32_t rule, state_values_stack_t * statevalues, uint32_t n_states)
{
<%= @grammar.prefix %>value_t _pvalue = {0};
switch (rule)
{
<% @grammar.rules.each do |rule| %>
<% if rule.code %>
case <%= rule.id %>u: {
<%= expand_code(rule.code, true, rule, nil) %>
} break;
<% end %>
<% end %>
default: break;
}
return _pvalue;
}
/**
* Check if the parser should shift to a new state.
*
* @param state_id
* Parser state ID.
* @param symbol_id
* Incoming token/rule set ID.
*
* @return State to shift to, or INVALID_ID if none.
*/
static size_t check_shift(size_t state_id, size_t symbol_id)
{
uint32_t start = parser_state_table[state_id].shift_table_index;
uint32_t end = start + parser_state_table[state_id].n_shift_entries;
for (uint32_t i = start; i < end; i++)
{
if (parser_shift_table[i].symbol_id == symbol_id)
{
return parser_shift_table[i].state_id;
}
}
return INVALID_ID;
}
/**
* Check if the parser should reduce to a new state.
*
* @param state_id
* Parser state ID.
* @param token
* Incoming token.
*
* @return State to reduce to, or INVALID_ID if none.
*/
static size_t check_reduce(size_t state_id, <%= @grammar.prefix %>token_t token)
{
size_t start = parser_state_table[state_id].reduce_table_index;
size_t end = start + parser_state_table[state_id].n_reduce_entries;
for (size_t i = start; i < end; i++)
{
if ((parser_reduce_table[i].token == token) ||
(parser_reduce_table[i].token == INVALID_TOKEN_ID))
{
return i;
}
}
return INVALID_ID;
}
/**
* Run the parser.
*
* @param context
* Lexer/parser context structure.
*
* @retval P_SUCCESS
* The parser successfully matched the input text. The parse result value
* can be accessed with <%= @grammar.prefix %>result().
* @retval P_UNEXPECTED_TOKEN
* An unexpected token was encountered that does not match any grammar rule.
* The value context->token holds the unexpected token.
* @reval P_DECODE_ERROR
* The decoder encountered invalid text encoding.
* @reval P_UNEXPECTED_INPUT
* Input text does not match any lexer pattern.
*/
size_t <%= @grammar.prefix %>parse(<%= @grammar.prefix %>context_t * context)
{
<%= @grammar.prefix %>token_info_t token_info;
<%= @grammar.prefix %>token_t token = INVALID_TOKEN_ID;
state_values_stack_t statevalues;
size_t reduced_rule_set = INVALID_ID;
<%= @grammar.prefix %>value_t reduced_parser_value;
state_values_stack_init(&statevalues);
state_values_stack_push(&statevalues);
size_t result;
for (;;)
{
if (token == INVALID_TOKEN_ID)
{
size_t lexer_result = <%= @grammar.prefix %>lex(context, &token_info);
if (lexer_result != P_SUCCESS)
{
result = lexer_result;
break;
}
token = token_info.token;
}
size_t shift_state = INVALID_ID;
if (reduced_rule_set != INVALID_ID)
{
shift_state = check_shift(state_values_stack_index(&statevalues, -1)->state_id, reduced_rule_set);
}
if (shift_state == INVALID_ID)
{
shift_state = check_shift(state_values_stack_index(&statevalues, -1)->state_id, token);
if ((shift_state != INVALID_ID) && (token == TOKEN___EOF))
{
/* Successful parse. */
context->parse_result = state_values_stack_index(&statevalues, -1)->pvalue;
result = P_SUCCESS;
break;
}
}
if (shift_state != INVALID_ID)
{
/* We have something to shift. */
state_values_stack_push(&statevalues);
state_values_stack_index(&statevalues, -1)->state_id = shift_state;
if (reduced_rule_set == INVALID_ID)
{
/* We shifted a token, mark it consumed. */
token = INVALID_TOKEN_ID;
state_values_stack_index(&statevalues, -1)->pvalue = token_info.pvalue;
}
else
{
/* We shifted a RuleSet. */
state_values_stack_index(&statevalues, -1)->pvalue = reduced_parser_value;
<%= @grammar.prefix %>value_t new_parse_result = {0};
reduced_parser_value = new_parse_result;
reduced_rule_set = INVALID_ID;
}
continue;
}
size_t reduce_index = check_reduce(state_values_stack_index(&statevalues, -1)->state_id, token);
if (reduce_index != INVALID_ID)
{
/* We have something to reduce. */
reduced_parser_value = parser_user_code(parser_reduce_table[reduce_index].rule, &statevalues, parser_reduce_table[reduce_index].n_states);
reduced_rule_set = parser_reduce_table[reduce_index].rule_set;
state_values_stack_pop(&statevalues, parser_reduce_table[reduce_index].n_states);
continue;
}
/* A token was successfully lexed, so the input text position was
* advanced. However, this is an unexpected token, so we want to reset
* the context text position to point to the token rather than the text
* after it, so that if the caller wants to report the error position,
* it will point to the correct position of the unexpected token. */
context->text_position = token_info.position;
context->token = token;
result = P_UNEXPECTED_TOKEN;
break;
}
state_values_stack_free(&statevalues);
return result;
}
/**
* Get the parse result value.
*
* @param context
* Lexer/parser context structure.
*
* @return Parse result value.
*/
<%= start_rule_type[1] %> <%= @grammar.prefix %>result(<%= @grammar.prefix %>context_t * context)
{
return context->parse_result.v_<%= start_rule_type[0] %>;
}
/**
* Get the current text input position.
*
* @param context
* Lexer/parser context structure.
*
* @return Current text position.
*/
<%= @grammar.prefix %>position_t <%= @grammar.prefix %>position(<%= @grammar.prefix %>context_t * context)
{
return context->text_position;
}

122
assets/parser.h.erb Normal file
View File

@ -0,0 +1,122 @@
/**
* @file
*
* This file is generated by Propane.
*/
#pragma once
#include <stdint.h>
#include <stddef.h>
/**************************************************************************
* Public types
*************************************************************************/
/* Result codes. */
#define <%= @grammar.prefix.upcase %>SUCCESS 0u
#define <%= @grammar.prefix.upcase %>DECODE_ERROR 1u
#define <%= @grammar.prefix.upcase %>UNEXPECTED_INPUT 2u
#define <%= @grammar.prefix.upcase %>UNEXPECTED_TOKEN 3u
#define <%= @grammar.prefix.upcase %>DROP 4u
#define <%= @grammar.prefix.upcase %>EOF 5u
/** Token type. */
typedef <%= get_type_for(@grammar.invalid_token_id) %> <%= @grammar.prefix %>token_t;
/** Token IDs. */
<% @grammar.tokens.each_with_index do |token, index| %>
#define TOKEN_<%= token.code_name %> <%= index %>u
<% unless token.id == index %>
<% raise "Token ID (#{token.id}) does not match index (#{index}) for token #{token.name}!" %>
<% end %>
<% end %>
#define INVALID_TOKEN_ID <%= @grammar.invalid_token_id %>u
/** Code point type. */
typedef uint32_t <%= @grammar.prefix %>code_point_t;
/** Parser values type(s). */
typedef union
{
<% @grammar.ptypes.each do |name, typestring| %>
<%= typestring %> v_<%= name %>;
<% end %>
} <%= @grammar.prefix %>value_t;
/**
* A structure to keep track of parser position.
*
* This is useful for reporting errors, etc...
*/
typedef struct
{
/** Input text row (0-based). */
uint32_t row;
/** Input text column (0-based). */
uint32_t col;
} <%= @grammar.prefix %>position_t;
/** Lexed token information. */
typedef struct
{
/** Text position where the token was found. */
<%= @grammar.prefix %>position_t position;
/** Number of input bytes used by the token. */
size_t length;
/** Token that was lexed. */
<%= @grammar.prefix %>token_t token;
/** Parser value associated with the token. */
<%= @grammar.prefix %>value_t pvalue;
} <%= @grammar.prefix %>token_info_t;
/**
* Lexer and parser context.
*
* The user must allocate an instance of this structure and pass it to any
* public API function.
*/
typedef struct
{
/* Lexer context data. */
/** Input text. */
uint8_t const * input;
/** Input text length. */
size_t input_length;
/** Input text index (byte offset). */
size_t input_index;
/** Input text position (row/column). */
<%= @grammar.prefix %>position_t text_position;
/** Current lexer mode. */
size_t mode;
/* Parser context data. */
/** Parse result value. */
<%= @grammar.prefix %>value_t parse_result;
/** Unexpected token received. */
<%= @grammar.prefix %>token_t token;
} <%= @grammar.prefix %>context_t;
void <%= @grammar.prefix %>context_init(<%= @grammar.prefix %>context_t * context, uint8_t const * input, size_t input_length);
size_t <%= @grammar.prefix %>decode_code_point(uint8_t const * input, size_t input_length,
<%= @grammar.prefix %>code_point_t * out_code_point, uint8_t * out_code_point_length);
size_t <%= @grammar.prefix %>lex(<%= @grammar.prefix %>context_t * context, <%= @grammar.prefix %>token_info_t * out_token_info);
size_t <%= @grammar.prefix %>parse(<%= @grammar.prefix %>context_t * context);
<%= start_rule_type[1] %> <%= @grammar.prefix %>result(<%= @grammar.prefix %>context_t * context);
<%= @grammar.prefix %>position_t <%= @grammar.prefix %>position(<%= @grammar.prefix %>context_t * context);

63
lib/propane/generator.rb
View File

@ -11,14 +11,27 @@ class Propane
@log = StringIO.new
end
@classname = @grammar.classname || File.basename(output_file).sub(%r{[^a-zA-Z0-9].*}, "").capitalize
@language =
if output_file =~ /\.([a-z]+)$/
$1
else
"d"
end
process_grammar!
end
def generate
erb = ERB.new(File.read(File.join(File.dirname(File.expand_path(__FILE__)), "../../assets/parser.d.erb")), trim_mode: "<>")
result = erb.result(binding.clone)
File.open(@output_file, "wb") do |fh|
fh.write(result)
extensions = [@language]
if @language == "c"
extensions += %w[h]
end
extensions.each do |extension|
erb = ERB.new(File.read(File.join(File.dirname(File.expand_path(__FILE__)), "../../assets/parser.#{extension}.erb")), trim_mode: "<>")
output_file = @output_file.sub(%r{\.[a-z]+$}, ".#{extension}")
result = erb.result(binding.clone)
File.open(output_file, "wb") do |fh|
fh.write(result)
end
end
@log.close
end
@ -191,11 +204,21 @@ class Propane
end
code = code.gsub(/\$(\d+)/) do |match|
index = $1.to_i
"statevalues[$-1-n_states+#{index}].pvalue.v_#{rule.components[index - 1].ptypename}"
case @language
when "c"
"state_values_stack_index(statevalues, -1 - (int)n_states + #{index})->pvalue.v_#{rule.components[index - 1].ptypename}"
when "d"
"statevalues[$-1-n_states+#{index}].pvalue.v_#{rule.components[index - 1].ptypename}"
end
end
else
code = code.gsub(/\$\$/) do |match|
"out_token_info.pvalue.v_#{pattern.ptypename}"
case @language
when "c"
"out_token_info->pvalue.v_#{pattern.ptypename}"
when "d"
"out_token_info.pvalue.v_#{pattern.ptypename}"
end
end
code = code.gsub(/\$mode\(([a-zA-Z_][a-zA-Z_0-9]*)\)/) do |match|
mode_name = $1
@ -203,7 +226,12 @@ class Propane
unless mode_id
raise Error.new("Lexer mode '#{mode_name}' not found")
end
"context.mode = #{mode_id}u"
case @language
when "c"
"context->mode = #{mode_id}u"
when "d"
"context.mode = #{mode_id}u"
end
end
end
code
@ -229,11 +257,26 @@ class Propane
# Type.
def get_type_for(max)
if max <= 0xFF
"ubyte"
case @language
when "c"
"uint8_t"
when "d"
"ubyte"
end
elsif max <= 0xFFFF
"ushort"
case @language
when "c"
"uint16_t"
when "d"
"ushort"
end
else
"uint"
case @language
when "c"
"uint32_t"
else
"uint"
end
end
end

552
spec/propane_spec.rb
View File

@ -11,7 +11,7 @@ describe Propane do
def build_parser(options = {})
options[:name] ||= ""
command = %W[./propane.sh spec/run/testparser#{options[:name]}.propane spec/run/testparser#{options[:name]}.d --log spec/run/testparser#{options[:name]}.log]
command = %W[./propane.sh spec/run/testparser#{options[:name]}.propane spec/run/testparser#{options[:name]}.#{options[:language]} --log spec/run/testparser#{options[:name]}.log]
if (options[:capture])
stdout, stderr, status = Open3.capture3(*command)
Results.new(stdout, stderr, status)
@ -25,9 +25,14 @@ describe Propane do
test_files = Array(test_files)
options[:parsers] ||= [""]
parsers = options[:parsers].map do |name|
"spec/run/testparser#{name}.d"
"spec/run/testparser#{name}.#{options[:language]}"
end
case options[:language]
when "c"
result = system(*%w[gcc -Wall -o spec/run/testparser -Ispec -Ispec/run], *parsers, *test_files, "spec/testutils.c", "-lm")
when "d"
result = system(*%w[ldc2 --unittest -of spec/run/testparser -Ispec], *parsers, *test_files, "spec/testutils.d")
end
result = system(*%w[ldc2 --unittest -of spec/run/testparser -Ispec], *parsers, *test_files, "spec/testutils.d")
expect(result).to be_truthy
end
@ -69,8 +74,12 @@ describe Propane do
FileUtils.mkdir_p("spec/run")
end
it "generates a lexer" do
write_grammar <<EOF
%w[d c].each do |language|
context "#{language.upcase} language" do
it "generates a lexer" do
write_grammar <<EOF
token int /\\d+/;
token plus /\\+/;
token times /\\*/;
@ -81,15 +90,33 @@ Foo -> int <<
Foo -> plus <<
>>
EOF
build_parser
compile("spec/test_lexer.d")
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
build_parser(language: language)
compile("spec/test_lexer.#{language}", language: language)
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
it "detects a lexer error when an unknown character is seen" do
write_grammar <<EOF
it "detects a lexer error when an unknown character is seen" do
case language
when "c"
write_grammar <<EOF
ptype int;
token int /\\d+/ <<
int v = 0;
for (size_t i = 0u; i < match_length; i++)
{
v *= 10;
v += (match[i] - '0');
}
$$ = v;
>>
Start -> int <<
$$ = $1;
>>
EOF
when "d"
write_grammar <<EOF
ptype int;
token int /\\d+/ <<
int v;
@ -104,15 +131,16 @@ Start -> int <<
$$ = $1;
>>
EOF
build_parser
compile("spec/test_lexer_unknown_character.d")
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
end
build_parser(language: language)
compile("spec/test_lexer_unknown_character.#{language}", language: language)
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
it "generates a parser" do
write_grammar <<EOF
it "generates a parser" do
write_grammar <<EOF
token plus /\\+/;
token times /\\*/;
token zero /0/;
@ -124,11 +152,65 @@ E -> B;
B -> zero;
B -> one;
EOF
build_parser
end
build_parser(language: language)
end
it "generates a parser that does basic math - user guide example" do
write_grammar <<EOF
it "generates a parser that does basic math - user guide example" do
case language
when "c"
write_grammar <<EOF
<<
#include <math.h>
>>
ptype size_t;
token plus /\\+/;
token times /\\*/;
token power /\\*\\*/;
token integer /\\d+/ <<
size_t v = 0u;
for (size_t i = 0u; i < match_length; i++)
{
v *= 10;
v += (match[i] - '0');
}
$$ = v;
>>
token lparen /\\(/;
token rparen /\\)/;
drop /\\s+/;
Start -> E1 <<
$$ = $1;
>>
E1 -> E2 <<
$$ = $1;
>>
E1 -> E1 plus E2 <<
$$ = $1 + $3;
>>
E2 -> E3 <<
$$ = $1;
>>
E2 -> E2 times E3 <<
$$ = $1 * $3;
>>
E3 -> E4 <<
$$ = $1;
>>
E3 -> E3 power E4 <<
$$ = (size_t)pow($1, $3);
>>
E4 -> integer <<
$$ = $1;
>>
E4 -> lparen E1 rparen <<
$$ = $2;
>>
EOF
when "d"
write_grammar <<EOF
<<
import std.math;
>>
@ -179,25 +261,26 @@ E4 -> lparen E1 rparen <<
$$ = $2;
>>
EOF
build_parser
compile("spec/test_basic_math_grammar.d")
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
end
build_parser(language: language)
compile("spec/test_basic_math_grammar.#{language}", language: language)
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
it "generates an SLR parser" do
write_grammar <<EOF
it "generates an SLR parser" do
write_grammar <<EOF
token one /1/;
Start -> E;
E -> one E;
E -> one;
EOF
build_parser
end
build_parser(language: language)
end
it "distinguishes between multiple identical rules with lookahead symbol" do
write_grammar <<EOF
it "distinguishes between multiple identical rules with lookahead symbol" do
write_grammar <<EOF
token a;
token b;
Start -> R1 a;
@ -205,14 +288,14 @@ Start -> R2 b;
R1 -> a b;
R2 -> a b;
EOF
build_parser
compile("spec/test_parser_identical_rules_lookahead.d")
results = run
expect(results.status).to eq 0
end
build_parser(language: language)
compile("spec/test_parser_identical_rules_lookahead.#{language}", language: language)
results = run
expect(results.status).to eq 0
end
it "handles reducing a rule that could be arrived at from multiple states" do
write_grammar <<EOF
it "handles reducing a rule that could be arrived at from multiple states" do
write_grammar <<EOF
token a;
token b;
drop /\\s+/;
@ -220,14 +303,29 @@ Start -> a R1;
Start -> b R1;
R1 -> b;
EOF
build_parser
compile("spec/test_parser_rule_from_multiple_states.d")
results = run
expect(results.status).to eq 0
end
build_parser(language: language)
compile("spec/test_parser_rule_from_multiple_states.#{language}", language: language)
results = run
expect(results.status).to eq 0
end
it "executes user code when matching lexer token" do
write_grammar <<EOF
it "executes user code when matching lexer token" do
case language
when "c"
write_grammar <<EOF
<<
#include <stdio.h>
>>
token abc <<
printf("abc!\\n");
>>
token def;
Start -> Abcs def;
Abcs -> ;
Abcs -> abc Abcs;
EOF
when "d"
write_grammar <<EOF
<<
import std.stdio;
>>
@ -239,21 +337,35 @@ Start -> Abcs def;
Abcs -> ;
Abcs -> abc Abcs;
EOF
build_parser
compile("spec/test_user_code.d")
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"abc!",
"pass1",
"abc!",
"abc!",
"pass2",
])
end
end
build_parser(language: language)
compile("spec/test_user_code.#{language}", language: language)
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"abc!",
"pass1",
"abc!",
"abc!",
"pass2",
])
end
it "supports a pattern statement" do
write_grammar <<EOF
it "supports a pattern statement" do
case language
when "c"
write_grammar <<EOF
<<
#include <stdio.h>
>>
token abc;
/def/ <<
printf("def!\\n");
>>
Start -> abc;
EOF
when "d"
write_grammar <<EOF
<<
import std.stdio;
>>
@ -263,21 +375,39 @@ token abc;
>>
Start -> abc;
EOF
build_parser
compile("spec/test_pattern.d")
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"def!",
"pass1",
"def!",
"def!",
"pass2",
])
end
end
build_parser(language: language)
compile("spec/test_pattern.#{language}", language: language)
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"def!",
"pass1",
"def!",
"def!",
"pass2",
])
end
it "supports returning tokens from pattern code blocks" do
write_grammar <<EOF
it "supports returning tokens from pattern code blocks" do
case language
when "c"
write_grammar <<EOF
<<
#include <stdio.h>
>>
token abc;
/def/ <<
printf("def!\\n");
>>
/ghi/ <<
printf("ghi!\\n");
return $token(abc);
>>
Start -> abc;
EOF
when "d"
write_grammar <<EOF
<<
import std.stdio;
>>
@ -291,19 +421,44 @@ token abc;
>>
Start -> abc;
EOF
build_parser
compile("spec/test_return_token_from_pattern.d")
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"def!",
"ghi!",
"def!",
])
end
end
build_parser(language: language)
compile("spec/test_return_token_from_pattern.#{language}", language: language)
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"def!",
"ghi!",
"def!",
])
end
it "supports lexer modes" do
write_grammar <<EOF
it "supports lexer modes" do
case language
when "c"
write_grammar <<EOF
<<
#include <stdio.h>
>>
token abc;
token def;
tokenid string;
drop /\\s+/;
/"/ <<
printf("begin string mode\\n");
$mode(string);
>>
string: /[^"]+/ <<
printf("captured string\\n");
>>
string: /"/ <<
$mode(default);
return $token(string);
>>
Start -> abc string def;
EOF
when "d"
write_grammar <<EOF
<<
import std.stdio;
>>
@ -324,22 +479,42 @@ string: /"/ <<
>>
Start -> abc string def;
EOF
build_parser
compile("spec/test_lexer_modes.d")
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"begin string mode",
"captured string",
"pass1",
"begin string mode",
"captured string",
"pass2",
])
end
end
build_parser(language: language)
compile("spec/test_lexer_modes.#{language}", language: language)
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"begin string mode",
"captured string",
"pass1",
"begin string mode",
"captured string",
"pass2",
])
end
it "executes user code associated with a parser rule" do
write_grammar <<EOF
it "executes user code associated with a parser rule" do
case language
when "c"
write_grammar <<EOF
<<
#include <stdio.h>
>>
token a;
token b;
Start -> A B <<
printf("Start!\\n");
>>
A -> a <<
printf("A!\\n");
>>
B -> b <<
printf("B!\\n");
>>
EOF
when "d"
write_grammar <<EOF
<<
import std.stdio;
>>
@ -355,20 +530,21 @@ B -> b <<
writeln("B!");
>>
EOF
build_parser
compile("spec/test_parser_rule_user_code.d")
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"A!",
"B!",
"Start!",
])
end
end
build_parser(language: language)
compile("spec/test_parser_rule_user_code.#{language}", language: language)
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"A!",
"B!",
"Start!",
])
end
it "parses lists" do
write_grammar <<EOF
ptype uint;
it "parses lists" do
write_grammar <<EOF
ptype #{language == "c" ? "uint32_t" : "uint"};
token a;
Start -> As <<
$$ = $1;
@ -380,15 +556,15 @@ As -> As a <<
$$ = $1 + 1u;
>>
EOF
build_parser
compile("spec/test_parsing_lists.d")
results = run
expect(results.status).to eq 0
expect(results.stderr).to eq ""
end
build_parser(language: language)
compile("spec/test_parsing_lists.#{language}", language: language)
results = run
expect(results.status).to eq 0
expect(results.stderr).to eq ""
end
it "fails to generate a parser for a LR(1) grammar that is not LALR" do
write_grammar <<EOF
it "fails to generate a parser for a LR(1) grammar that is not LALR" do
write_grammar <<EOF
token a;
token b;
token c;
@ -401,13 +577,29 @@ Start -> b E d;
E -> e;
F -> e;
EOF
results = build_parser(capture: true)
expect(results.status).to_not eq 0
expect(results.stderr).to match %r{reduce/reduce conflict.*\(E\).*\(F\)}
end
results = build_parser(capture: true, language: language)
expect(results.status).to_not eq 0
expect(results.stderr).to match %r{reduce/reduce conflict.*\(E\).*\(F\)}
end
it "provides matched text to user code blocks" do
write_grammar <<EOF
it "provides matched text to user code blocks" do
case language
when "c"
write_grammar <<EOF
<<
#include <stdio.h>
#include <stdlib.h>
>>
token id /[a-zA-Z_][a-zA-Z0-9_]*/ <<
char * t = malloc(match_length + 1);
strncpy(t, (char *)match, match_length);
printf("Matched token is %s\\n", t);
free(t);
>>
Start -> id;
EOF
when "d"
write_grammar <<EOF
<<
import std.stdio;
>>
@ -416,18 +608,31 @@ token id /[a-zA-Z_][a-zA-Z0-9_]*/ <<
>>
Start -> id;
EOF
build_parser
compile("spec/test_lexer_match_text.d")
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"Matched token is identifier_123",
"pass1",
])
end
end
build_parser(language: language)
compile("spec/test_lexer_match_text.#{language}", language: language)
results = run
expect(results.status).to eq 0
verify_lines(results.stdout, [
"Matched token is identifier_123",
"pass1",
])
end
it "allows storing a result value for the lexer" do
write_grammar <<EOF
it "allows storing a result value for the lexer" do
case language
when "c"
write_grammar <<EOF
ptype uint64_t;
token word /[a-z]+/ <<
$$ = match_length;
>>
Start -> word <<
$$ = $1;
>>
EOF
when "d"
write_grammar <<EOF
ptype ulong;
token word /[a-z]+/ <<
$$ = match.length;
@ -436,53 +641,56 @@ Start -> word <<
$$ = $1;
>>
EOF
build_parser
compile("spec/test_lexer_result_value.d")
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
end
build_parser(language: language)
compile("spec/test_lexer_result_value.#{language}", language: language)
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
it "tracks position of parser errors" do
write_grammar <<EOF
it "tracks position of parser errors" do
write_grammar <<EOF
token a;
token num /\\d+/;
drop /\\s+/;
Start -> a num Start;
Start -> a num;
EOF
build_parser
compile("spec/test_error_positions.d")
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
build_parser(language: language)
compile("spec/test_error_positions.#{language}", language: language)
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
it "allows creating a JSON parser" do
write_grammar(File.read("spec/json_parser.propane"))
build_parser
compile(["spec/test_parsing_json.d", "spec/json_types.d"])
end
it "allows creating a JSON parser" do
write_grammar(File.read("spec/json_parser.propane"))
build_parser(language: language)
compile(["spec/test_parsing_json.#{language}", "spec/json_types.#{language}"], language: language)
end
it "allows generating multiple parsers in the same program" do
write_grammar(<<EOF, name: "myp1")
it "allows generating multiple parsers in the same program" do
write_grammar(<<EOF, name: "myp1")
prefix myp1_;
token a;
token num /\\d+/;
drop /\\s+/;
Start -> a num;
EOF
build_parser(name: "myp1")
write_grammar(<<EOF, name: "myp2")
build_parser(name: "myp1", language: language)
write_grammar(<<EOF, name: "myp2")
prefix myp2_;
token b;
token c;
Start -> b c b;
EOF
build_parser(name: "myp2")
compile("spec/test_multiple_parsers.d", parsers: %w[myp1 myp2])
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
build_parser(name: "myp2", language: language)
compile("spec/test_multiple_parsers.#{language}", parsers: %w[myp1 myp2], language: language)
results = run
expect(results.stderr).to eq ""
expect(results.status).to eq 0
end
end
end
end

29
spec/test_basic_math_grammar.c Normal file
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@ -0,0 +1,29 @@
#include "testparser.h"
#include "testutils.h"
#include <string.h>
int main()
{
char const * input = "1 + 2 * 3 + 4";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert_eq(P_SUCCESS, p_parse(&context));
assert_eq(11, p_result(&context));
input = "1 * 2 ** 4 * 3";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert_eq(P_SUCCESS, p_parse(&context));
assert_eq(48, p_result(&context));
input = "(1 + 2) * 3 + 4";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert_eq(P_SUCCESS, p_parse(&context));
assert_eq(13, p_result(&context));
input = "(2 * 2) ** 3 + 4 + 5";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert_eq(P_SUCCESS, p_parse(&context));
assert_eq(73, p_result(&context));
return 0;
}

39
spec/test_error_positions.c Normal file
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@ -0,0 +1,39 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "a 42";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
input = "a\n123\na a";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_UNEXPECTED_TOKEN);
assert(p_position(&context).row == 2);
assert(p_position(&context).col == 3);
assert(context.token == TOKEN_a);
input = "12";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_UNEXPECTED_TOKEN);
assert(p_position(&context).row == 0);
assert(p_position(&context).col == 0);
assert(context.token == TOKEN_num);
input = "a 12\n\nab";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_UNEXPECTED_INPUT);
assert(p_position(&context).row == 2);
assert(p_position(&context).col == 1);
input = "a 12\n\na\n\n77\na \xAA";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_DECODE_ERROR);
assert(p_position(&context).row == 5);
assert(p_position(&context).col == 4);
return 0;
}

1
spec/test_error_positions.d
View File

@ -33,6 +33,5 @@ unittest
input = "a 12\n\na\n\n77\na \xAA";
p_context_init(&context, input);
assert(p_parse(&context) == P_DECODE_ERROR);
writeln(p_position(&context));
assert(p_position(&context) == p_position_t(5, 4));
}

92
spec/test_lexer.c Normal file
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@ -0,0 +1,92 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
size_t result;
p_code_point_t code_point;
uint8_t code_point_length;
result = p_decode_code_point((uint8_t const *)"5", 1u, &code_point, &code_point_length);
assert(result == P_SUCCESS);
assert(code_point == '5');
assert(code_point_length == 1u);
result = p_decode_code_point((uint8_t const *)"", 0u, &code_point, &code_point_length);
assert(result == P_EOF);
result = p_decode_code_point((uint8_t const *)"\xC2\xA9", 2u, &code_point, &code_point_length);
assert(result == P_SUCCESS);
assert(code_point == 0xA9u);
assert(code_point_length == 2u);
result = p_decode_code_point((uint8_t const *)"\xf0\x9f\xa7\xa1", 4u, &code_point, &code_point_length);
assert(result == P_SUCCESS);
assert(code_point == 0x1F9E1u);
assert(code_point_length == 4u);
result = p_decode_code_point((uint8_t const *)"\xf0\x9f\x27", 3u, &code_point, &code_point_length);
assert(result == P_DECODE_ERROR);
result = p_decode_code_point((uint8_t const *)"\xf0\x9f\xa7\xFF", 4u, &code_point, &code_point_length);
assert(result == P_DECODE_ERROR);
result = p_decode_code_point((uint8_t const *)"\xfe", 1u, &code_point, &code_point_length);
assert(result == P_DECODE_ERROR);
p_token_info_t token_info;
char const * input = "5 + 4 * \n677 + 567";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 0u);
assert(token_info.position.col == 0u);
assert(token_info.length == 1u);
assert(token_info.token == TOKEN_int);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 0u);
assert(token_info.position.col == 2u);
assert(token_info.length == 1u);
assert(token_info.token == TOKEN_plus);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 0u);
assert(token_info.position.col == 4u);
assert(token_info.length == 1u);
assert(token_info.token == TOKEN_int);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 0u);
assert(token_info.position.col == 6u);
assert(token_info.length == 1u);
assert(token_info.token == TOKEN_times);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 1u);
assert(token_info.position.col == 0u);
assert(token_info.length == 3u);
assert(token_info.token == TOKEN_int);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 1u);
assert(token_info.position.col == 4u);
assert(token_info.length == 1u);
assert(token_info.token == TOKEN_plus);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 1u);
assert(token_info.position.col == 6u);
assert(token_info.length == 3u);
assert(token_info.token == TOKEN_int);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 1u);
assert(token_info.position.col == 9u);
assert(token_info.length == 0u);
assert(token_info.token == TOKEN___EOF);
p_context_init(&context, (uint8_t const *)"", 0u);
assert(p_lex(&context, &token_info) == P_SUCCESS);
assert(token_info.position.row == 0u);
assert(token_info.position.col == 0u);
assert(token_info.length == 0u);
assert(token_info.token == TOKEN___EOF);
return 0;
}

15
spec/test_lexer_match_text.c Normal file
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@ -0,0 +1,15 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
#include <stdio.h>
int main()
{
char const * input = "identifier_123";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
printf("pass1\n");
return 0;
}

20
spec/test_lexer_modes.c Normal file
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@ -0,0 +1,20 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
#include <stdio.h>
int main()
{
char const * input = "abc \"a string\" def";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
printf("pass1\n");
input = "abc \"abc def\" def";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
printf("pass2\n");
return 0;
}

19
spec/test_lexer_result_value.c Normal file
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@ -0,0 +1,19 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "x";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
assert(p_result(&context) == 1u);
input = "fabulous";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
assert(p_result(&context) == 8u);
return 0;
}

18
spec/test_lexer_unknown_character.c Normal file
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@ -0,0 +1,18 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "x";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_UNEXPECTED_INPUT);
input = "123";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
assert(p_result(&context) == 123u);
return 0;
}

19
spec/test_multiple_parsers.c Normal file
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@ -0,0 +1,19 @@
#include "testparsermyp1.h"
#include "testparsermyp2.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input1 = "a\n1";
myp1_context_t context1;
myp1_context_init(&context1, (uint8_t const *)input1, strlen(input1));
assert(myp1_parse(&context1) == MYP1_SUCCESS);
char const * input2 = "bcb";
myp2_context_t context2;
myp2_context_init(&context2, (uint8_t const *)input2, strlen(input2));
assert(myp2_parse(&context2) == MYP2_SUCCESS);
return 0;
}

17
spec/test_parser_identical_rules_lookahead.c Normal file
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@ -0,0 +1,17 @@
#include "testparser.h"
#include <string.h>
#include <assert.h>
int main()
{
char const * input = "aba";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
input = "abb";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
return 0;
}

24
spec/test_parser_rule_from_multiple_states.c Normal file
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@ -0,0 +1,24 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "a";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_UNEXPECTED_TOKEN);
assert(p_position(&context).row == 0);
assert(p_position(&context).col == 1);
assert(context.token == TOKEN___EOF);
input = "a b";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
input = "bb";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
return 0;
}

13
spec/test_parser_rule_user_code.c Normal file
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@ -0,0 +1,13 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "ab";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
return 0;
}

24
spec/test_parsing_lists.c Normal file
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@ -0,0 +1,24 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "a";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
assert(p_result(&context) == 1u);
input = "";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
assert(p_result(&context) == 0u);
input = "aaaaaaaaaaaaaaaa";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
assert(p_result(&context) == 16u);
return 0;
}

20
spec/test_pattern.c Normal file
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@ -0,0 +1,20 @@
#include "testparser.h"
#include <stdio.h>
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "abcdef";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
printf("pass1\n");
input = "defabcdef";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
printf("pass2\n");
return 0;
}

13
spec/test_return_token_from_pattern.c Normal file
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@ -0,0 +1,13 @@
#include "testparser.h"
#include <assert.h>
#include <string.h>
int main()
{
char const * input = "defghidef";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
return 0;
}

20
spec/test_user_code.c Normal file
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@ -0,0 +1,20 @@
#include "testparser.h"
#include <assert.h>
#include <stdio.h>
#include <string.h>
int main()
{
char const * input = "abcdef";
p_context_t context;
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
printf("pass1\n");
input = "abcabcdef";
p_context_init(&context, (uint8_t const *)input, strlen(input));
assert(p_parse(&context) == P_SUCCESS);
printf("pass2\n");
return 0;
}

12
spec/testutils.c Normal file
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@ -0,0 +1,12 @@
#include <stdio.h>
#include <assert.h>
#include <stdbool.h>
void assert_eq_size_t_i(size_t expected, size_t actual, char const * file, size_t line)
{
if (expected != actual)
{
fprintf(stderr, "%s:%lu: expected %lu, got %lu\n", file, line, expected, actual);
assert(false);
}
}

7
spec/testutils.h Normal file
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@ -0,0 +1,7 @@
#pragma once
void assert_eq_size_t_i(size_t expected, size_t actual, char const * file, size_t line);
#define assert_eq(expected, actual) \
assert_eq_size_t_i(expected, actual, __FILE__, __LINE__)