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add a helper library, uart_repl, which handles basic ANSI over UART

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This commit is contained in:
Alex Hirzel 2018-04-01 20:00:51 -04:00
parent a89417e26e
commit f30f57059d
6 changed files with 493 additions and 0 deletions
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4
examples/uart_repl_test/FreeRTOSConfig.h Normal file
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#define configUSE_COUNTING_SEMAPHORES (1)
#include_next <FreeRTOSConfig.h>

9
examples/uart_repl_test/Makefile Normal file
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PROGRAM=uart_repl_test.c
EXTRA_COMPONENTS=extras/stdin_uart_interrupt extras/uart_repl
ESPBAUD=921600
include ../../common.mk
serial:
screen $(ESPPORT) 115200

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examples/uart_repl_test/uart_repl_test.c Normal file
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#include <stdlib.h>
#include <string.h> /* strlen */
#include <espressif/esp_common.h>
#include <espressif/user_interface.h>
#include <esp/uart.h>
#include <FreeRTOS.h>
#include <task.h>
#include <uart_repl/uart_repl.h>
void handle_command(char const d[]) {
if (!strcmp(d, "ts") || !strcmp(d, "time")) {
printf("the tick count since boot is: %u\n", xTaskGetTickCount());
} else if (!strcmp(d, "help")) {
printf("commands include ts, time\n");
} else {
printf("command not recognized, try help\n");
}
}
void user_init(void) {
uart_set_baud(0, 115200);
printf("\n\nWelcome to the uart REPL demo. try \"help\"\n");
uart_repl_init(&handle_command);
}

9
extras/uart_repl/component.mk Normal file
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# Component makefile for extras/uart_repl
# expected anyone using RTC driver includes it as 'uart_repl/uart_repl.h'
INC_DIRS += $(uart_repl_ROOT)..
# args for passing into compile rule generation
uart_repl_SRC_DIR = $(uart_repl_ROOT)
$(eval $(call component_compile_rules,uart_repl))

395
extras/uart_repl/uart_repl.c Normal file
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/* Read-Evaluate-Print Loop over UART
*
* This is a library that allows you to quickly prototype REPL-type loops.
* Currently, basic ANSI escape sequences are supported so that GNU screen(1)
* can be used with the delete and arrow keys. The framework is very expandable
* to other ANSI escape sequences.
*
* Dependencies: it is recommended that you also use extras/stdin_uart_interrupt
* to make this more responsive.
*/
#include <uart_repl/uart_repl.h>
#include <stdio.h> /* fflush, fputs, putchar, stdout, STDIN_FILENO */
#include <string.h>/* memset */
#include <unistd.h> /* read */
#include <ctype.h> /* isalnum */
#include <FreeRTOS.h>
#include <task.h> /* vTaskDelete, xTaskCreate */
/* This is a helper macro which creates a highly-localized and optimizable
* function. It greatly aids in code readability, and the compiler should be
* able to eliminate most of the stack overhead from these function calls.
*
* Note: Uses a GCC-specific version of VA_ARGS that allows us to have no
* arguments specified (the default case). */
#define UTIL(F, ...) static void F(struct serial_terminal_status *ST, \
##__VA_ARGS__)
// convenience macros
#define POS (ST->lineCursorPosition)
#define LEN (ST->lineLength)
#define CH (ST->lastReadChar)
#define LINE (ST->line)
#define STATE (ST->state)
#define CSI (ST->csi_seq)
UTIL(bell) {
// ring bell
putchar('\a');
}
UTIL(arrowLeft) {
if (POS) {
POS--;
putchar('\b'); // move cursor backward
} else {
bell(ST);
}
}
UTIL(arrowRight) {
if (POS < LEN) {
putchar(LINE[POS++]);
} else {
bell(ST);
}
}
UTIL(arrowUp) {
// TODO - in the future perhaps we can support line history
bell(ST);
}
UTIL(arrowDown) {
// TODO - in the future perhaps we can support line history
bell(ST);
}
UTIL(backSpace) {
if (POS) {
int j;
// copy the rest of the string (if any) one character backwards, and
// also update the screen as we go
putchar('\b');
for (j = POS; j < LEN; j++) {
LINE[j-1] = LINE[j];
putchar(LINE[j-1]);
}
// erase the ending character, also account for the loss
putchar(' ');
putchar('\b');
LINE[--LEN] = '\0';
POS--;
// we just moved the cursor right a few spaces, so reset it now
for (j = LEN - POS; j > 0; putchar('\b'), j--);
} else {
bell(ST);
}
}
UTIL(deleteKey) {
if (POS < LEN) {
arrowRight(ST);
backSpace(ST);
} else {
bell(ST);
}
}
UTIL(prompt) {
while (POS) {
LINE[--POS] = '\0';
}
LEN = 0;
fputs("> ", stdout);
}
UTIL(pushPrintable) {
if (POS == LEN) {
// XXX TODO could overflow
LINE[POS+1] = '\0';
}
LINE[POS] = CH;
LEN++;
POS++;
putchar(CH);
}
UTIL(realEscapeKey) {
//fputs("<Esc>", stdout);
}
UTIL(nonAnsiChar) {
// normal printable, echoing character (but line might be full)
if (CH >= 0x20 && CH < 0x7F) {
if (POS + 1 < sizeof(LINE)) {
// if line length is respected...
pushPrintable(ST);
} else {
bell(ST);
}
// Backspace key or CTRL+H
} else if (0x7F == CH || 0x08 == CH) {
backSpace(ST);
// <Enter> key
} else if ('\n' == CH || '\r' == CH) {
putchar('\n');
ST->lineCb((char const *) LINE);
prompt(ST);
// CTRL+C, abort current command
} else if (0x03 == CH) {
bell(ST);
putchar('\n');
prompt(ST);
// CTRL+L, redraw on new line
} else if (0x0C == CH) {
putchar('\n');
prompt(ST);
fputs(LINE, stdout);
// CTRL+U, clear line in place
} else if (0x15 == CH) {
while (POS) {
fputs("\b \b", stdout);
LINE[--POS] = '\0';
LEN--;
}
// <Esc>, starting an escape sequence maybe
} else if (0x1b == CH) {
/*
* There is going to be an issue here, and POS cannot fix it right now.
* There is a non-determinism when using only the character queue. It
* turns out that the ANSI escape sequence parser will need to introduce
* some kind of waiting concept to determine whether a given <Esc> is
* due to an escape sequence or just a stand-alone escape.
*
* TODO: For now, we just assume Esc is always part of an ANSI escape
* sequence. In the future. the character-wise state machine should
* incorporate one external event (a delay after pressing <Esc>) that
* can be used to determine a given <Esc> is stand-alone after that
* given time-out.
*/
STATE = UART_REPL_ANSI_JUST_ESCAPED;
} else {
// nonprintable or unhandled character; do nothing!
//printf("<NP 0x%02x>", CH);
}
}
UTIL(AnsiCSIBackout) {
if (UART_REPL_ANSI_NONE == STATE) {
// nothing to do
return;
}
/* If this gets called, we are part of the way thru parsing an ANSI
* sequence, and we need to back out of it from whereever we're at in the
* parsing process. Use the existing state information to functionally
* ignore this ANSI escape sequence by using nonAnsiChar(ST) to re-handle the
* keys in the proper order. if this routine is called after the CSI
* structure has been completely populated, it is assumed the CH character
* will still represent the final byte by the time we get here. so if
* AnsiCSIBackout is called from e.g. arrowRight(), it is assumed that CH is
* still equal to final_byte.
*/
char tempChar;
int j;
switch (STATE) {
case UART_REPL_ANSI_JUST_ESCAPED:
// handled below, only back out one character
realEscapeKey(ST);
nonAnsiChar(ST);
STATE = UART_REPL_ANSI_NONE;
break;
case UART_REPL_ANSI_READ_CSI_PARAMETER_BYTES:
case UART_REPL_ANSI_READ_CSI_INTERMEDIATE_BYTES:
case UART_REPL_ANSI_READ_CSI_FINAL_BYTE:
realEscapeKey(ST);
tempChar = CH; // backup the current key
CH = '[';
nonAnsiChar(ST);
for (j = 0; j < CSI.parameter_n_bytes; j++) {
CH = CSI.parameter_bytes[j];
nonAnsiChar(ST);
CSI.parameter_bytes[j] = '\0';
CSI.parameter_n_bytes--;
}
for (j = 0; j < CSI.intermediate_n_bytes; j++) {
CH = CSI.intermediate_bytes[j];
nonAnsiChar(ST);
CSI.intermediate_bytes[j] = '\0';
CSI.intermediate_n_bytes--;
}
CH = tempChar; // restore
nonAnsiChar(ST);
STATE = UART_REPL_ANSI_NONE;
break;
case UART_REPL_ANSI_NONE:
default:
break;
}
}
/* this takes an input of the csi_seq structure, and does whatever it wants with
* it */
UTIL(AnsiCSI) {
switch (CSI.final_byte) {
// handle arrow keys (note: shifted versions are not captured)
case 'A': arrowUp(ST); break;
case 'B': arrowDown(ST); break;
case 'C': arrowRight(ST); break;
case 'D': arrowLeft(ST); break;
case '~':
if (1 == CSI.parameter_n_bytes) {
switch (CSI.parameter_bytes[0]) {
//case '1': fputs("<Home>", stdout); break;
//case '2': fputs("<Ins>", stdout); break;
case '3': deleteKey(ST); break;
//case '4': fputs("<End>", stdout); break;
//case '5': fputs("<PgUp>", stdout); break;
//case '6': fputs("<PgDn>", stdout); break;
default: AnsiCSIBackout(ST); break;
}
} else {
AnsiCSIBackout(ST);
}
break;
default:
AnsiCSIBackout(ST);
break;
}
}
UTIL(readCH) {
if (!read(STDIN_FILENO, (void*)&CH, 1)) {
fputs("never see this print as read(...) is blocking\n", stdout);
}
}
UTIL(MainStateMachine) {
prompt(ST);
top:
fflush(stdout);
switch (STATE) {
case UART_REPL_ANSI_NONE:
readCH(ST);
nonAnsiChar(ST);
break;
case UART_REPL_ANSI_JUST_ESCAPED:
readCH(ST);
CSI.parameter_n_bytes = 0;
CSI.intermediate_n_bytes = 0;
/* Wikipedia: Sequences have different lengths. All sequences start
* with ESC (27 / hex 0x1B), followed by a second byte in the range
* 0x400x5F (ASCII @AZ[\]^_). */
if (CH < 0x40 || CH > 0x5F) {
AnsiCSIBackout(ST);
} else if ('[' == CH) {
STATE = UART_REPL_ANSI_READ_CSI_PARAMETER_BYTES;
readCH(ST);
} else {
AnsiCSIBackout(ST);
}
break;
/* Wikipedia: The ESC [ is followed by any number (including none) of
* "parameter bytes" in the range 0x300x3F (ASCII 09:;<=>?), then by
* any number of "intermediate bytes" in the range 0x200x2F (ASCII
* space and !"#$%&'()*+,-./), then finally by a single "final byte" in
* the range 0x400x7E (ASCII @AZ[\]^_`az{|}~). */
case UART_REPL_ANSI_READ_CSI_PARAMETER_BYTES:
if (CH >= 0x30 && CH <= 0x3F) {
// valid parameter byte
CSI.parameter_bytes[CSI.parameter_n_bytes++] = CH;
readCH(ST); // for the next thing
} else if (CH >= 0x20 && CH <= 0x2F) {
// valid intermediate byte
STATE = UART_REPL_ANSI_READ_CSI_INTERMEDIATE_BYTES;
} else if (CH >= 0x40 && CH <= 0x7E) {
// valid final byte
STATE = UART_REPL_ANSI_READ_CSI_FINAL_BYTE;
} else {
AnsiCSIBackout(ST);
}
break;
case UART_REPL_ANSI_READ_CSI_INTERMEDIATE_BYTES:
if (CH >= 0x20 && CH <= 0x2F) {
// valid intermediate byte
CSI.intermediate_bytes[CSI.intermediate_n_bytes++] = CH;
readCH(ST); // for the next thing
} else if (CH >= 0x40 && CH <= 0x7E) {
// valid final byte
STATE = UART_REPL_ANSI_READ_CSI_FINAL_BYTE;
} else {
AnsiCSIBackout(ST);
}
break;
case UART_REPL_ANSI_READ_CSI_FINAL_BYTE:
if (CH >= 0x40 && CH <= 0x7E) {
// valid final byte
CSI.final_byte = CH;
AnsiCSI(ST);
STATE = UART_REPL_ANSI_NONE;
} else {
AnsiCSIBackout(ST);
}
break;
}
goto top;
}
#undef UTIL
#undef POS
#undef LINE
#undef LEN
#undef CH
#undef STATE
void uart_repl_task(void *pvParameters) {
struct serial_terminal_status cc;
memset(&cc, 0, sizeof(cc));
cc.lineCb = pvParameters;
MainStateMachine(&cc);
vTaskDelete(NULL); // just in case we get here
}
void uart_repl_init(uart_repl_handler line_cb) {
xTaskCreate(uart_repl_task, "uart_repl", 256, (void *)line_cb, 10, NULL);
}

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extras/uart_repl/uart_repl.h Normal file
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#ifndef _SWC_UART_REPL_
#define _SWC_UART_REPL_
#include <stddef.h> /* size_t */
#if 0
/* in the future, maybe add support for special keys */
enum uart_repl_special_key {
UART_REPL_NONE,
UART_REPL_UP,
UART_REPL_DOWN,
UART_REPL_RIGHT,
UART_REPL_LEFT,
};
#endif
typedef void (*uart_repl_handler)(char const *);
struct serial_terminal_status {
char line[80];
unsigned int lineCursorPosition; // this is the index of the next character to be written
unsigned int lineLength; // length of string total so far
char lastReadChar;
uart_repl_handler lineCb;
enum uart_repl_ansi_parse_state {
UART_REPL_ANSI_NONE = 0,
UART_REPL_ANSI_JUST_ESCAPED,
UART_REPL_ANSI_READ_CSI_PARAMETER_BYTES,
UART_REPL_ANSI_READ_CSI_INTERMEDIATE_BYTES,
UART_REPL_ANSI_READ_CSI_FINAL_BYTE,
} state;
struct {
unsigned int parameter_n_bytes;
unsigned int intermediate_n_bytes;
char parameter_bytes[10];
char intermediate_bytes[10];
char final_byte;
} csi_seq;
};
void uart_repl_task(void *);
void uart_repl_init(uart_repl_handler);
#endif /* ndef _SWC_UART_REPL_ */