From 668c89f88988e4bd6149fa7d13650254037f028d Mon Sep 17 00:00:00 2001
From: jaseg <git@jaseg.net>
Date: Sun, 14 Apr 2019 13:25:23 +0900
Subject: driver/fw: I2C LCD working

---
 driver_fw/serial.c | 233 +++++++++++++++++++++++++++++++++++++++++++++++++++++
 1 file changed, 233 insertions(+)
 create mode 100644 driver_fw/serial.c

(limited to 'driver_fw/serial.c')

diff --git a/driver_fw/serial.c b/driver_fw/serial.c
new file mode 100644
index 0000000..efbcb95
--- /dev/null
+++ b/driver_fw/serial.c
@@ -0,0 +1,233 @@
+/* Megumin LED display firmware
+ * Copyright (C) 2018 Sebastian Götte <code@jaseg.net>
+ * 
+ * This program is free software: you can redistribute it and/or modify
+ * it under the terms of the GNU General Public License as published by
+ * the Free Software Foundation, either version 3 of the License, or
+ * (at your option) any later version.
+ * 
+ * This program is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
+ * GNU General Public License for more details.
+ * 
+ * You should have received a copy of the GNU General Public License
+ * along with this program.  If not, see <http://www.gnu.org/licenses/>.
+ */
+
+#include "serial.h"
+#include "mac.h"
+
+unsigned int uart_overruns = 0;
+unsigned int invalid_frames = 0;
+
+static union tx_buf_union tx_buf;
+volatile union rx_buf_union rx_buf;
+
+void serial_init() {
+    USART1->CR1 = /* 8-bit -> M1, M0 clear */
+        /* RTOIE clear */
+          (8 << USART_CR1_DEAT_Pos) /* 8 sample cycles/1 bit DE assertion time */
+        | (8 << USART_CR1_DEDT_Pos) /* 8 sample cycles/1 bit DE assertion time */
+        /* OVER8 clear. Use default 16x oversampling */
+        /* CMIF clear */
+        | USART_CR1_MME
+        /* WAKE clear */
+        /* PCE, PS clear */
+        | USART_CR1_RXNEIE /* Enable receive interrupt */
+        /* other interrupts clear */
+        | USART_CR1_TE
+        | USART_CR1_RE;
+    /* Invert TX and DE to accomodate the level shifters */
+    USART1->CR2 = USART_CR2_TXINV;
+    USART1->CR3 = USART_CR3_DEM | USART_CR3_DEP; /* enable RS485 DE (output on RTS) */
+    /* Set divider for 9600 baud rate @48MHz system clock. */
+    int usartdiv = 5000;
+    USART1->BRR = usartdiv;
+
+    /* And... go! */
+    USART1->CR1 |= USART_CR1_UE;
+
+    /* Enable receive interrupt */
+    NVIC_EnableIRQ(USART1_IRQn);
+    NVIC_SetPriority(USART1_IRQn, 1);
+}
+
+void tx_char(uint8_t c) {
+    while (!(USART1->ISR & USART_ISR_TC));
+    USART1->TDR = c;
+}
+
+void send_frame_formatted(uint8_t *buf, int len) {
+    uint8_t *p=buf, *q=buf, *end=buf+len;
+    do {
+        while (*q && q!=end)
+            q++;
+        tx_char(q-p+1);
+        while (*p && p!=end)
+            tx_char(*p++);
+        p++, q++;
+    } while (p < end);
+    tx_char('\0');
+}
+
+void send_status_reply(void) {
+    tx_buf.desc_reply.firmware_version = FIRMWARE_VERSION;
+    tx_buf.desc_reply.hardware_version = HARDWARE_VERSION;
+    tx_buf.desc_reply.pad[0] = tx_buf.desc_reply.pad[1] = 0;
+    tx_buf.desc_reply.uptime_s = sys_time_s;
+    //tx_buf.desc_reply.vcc_mv = adc_vcc_mv;
+    //tx_buf.desc_reply.temp_celsius = adc_temp_celsius;
+    tx_buf.desc_reply.global_brightness = global_brightness;
+    tx_buf.desc_reply.framerate_millifps = frame_duration_us > 0 ? 1000000000 / frame_duration_us : 0;
+    tx_buf.desc_reply.uart_overruns = uart_overruns;
+    tx_buf.desc_reply.invalid_frames = invalid_frames;
+    send_frame_formatted(tx_buf.byte_data, sizeof(tx_buf.desc_reply));
+}
+
+/* This is the higher-level protocol handler for the serial protocol. It gets passed the number of data bytes in this
+ * frame (which may be zero) and returns a pointer to the buffer where the next frame should be stored.
+ */
+volatile uint8_t *packet_received(int len) {
+    static enum {
+        PROT_ADDRESSED = 0,
+        PROT_IGNORE = 2,
+    } protocol_state = PROT_IGNORE; 
+    /* Use mac frames as delimiters to synchronize this protocol layer */
+    trigger_comm_led();
+    if (len == 0) { /* Discovery packet */
+        if (sys_time_tick < 100) { /* Only respond during the first 100ms after boot */
+            send_frame_formatted((uint8_t*)&device_mac, sizeof(device_mac));
+        }
+
+    } else if (len == 1) { /* Command packet */
+        if (protocol_state == PROT_ADDRESSED) {
+            switch (rx_buf.byte_data[0]) {
+            case 0x01:
+                send_status_reply();
+                break;
+            }
+        } else {
+            invalid_frames++;
+            trigger_error_led();
+        }
+        protocol_state = PROT_IGNORE;
+
+    } else if (len == 4) { /* Address packet */
+        if (rx_buf.mac_data == device_mac) { /* we are addressed */
+            protocol_state = PROT_ADDRESSED; /* start listening for frame buffer data */
+        } else { /* we are not addressed */
+            protocol_state = PROT_IGNORE; /* ignore packet */
+        }
+
+    } else if (len == sizeof(rx_buf.set_fb_rq)/2) {
+        if (protocol_state == PROT_ADDRESSED) { /* First of two half-framebuffer data frames */
+
+            /* FIXME */
+
+            /* Go to "hang mode" until next zero-length packet. */
+            protocol_state = PROT_IGNORE;
+        }
+
+    } else {
+        /* FIXME An invalid packet has been received. What should we do? */
+        invalid_frames++;
+        trigger_error_led();
+        protocol_state = PROT_IGNORE; /* go into "hang mode" until next zero-length packet */
+    }
+
+    /* By default, return rx_buf.byte_data . This means if an invalid protocol state is reached ("hang mode"), the next
+     * frame is still written to rx_buf. This is not a problem since whatever garbage is written at that point will be
+     * overwritten before the next buffer transfer. */
+    return rx_buf.byte_data;
+}
+
+void USART1_IRQHandler(void) {
+    /* Since a large amount of data will be shoved down this UART interface we need a more reliable and more efficient
+     * way of framing than just waiting between transmissions.
+     *
+     * This code uses "Consistent Overhead Byte Stuffing" (COBS). For details, see its Wikipedia page[0] or the proper
+     * scientific paper[1] published on it. Roughly, it works like this:
+     *
+     * * A frame is at most 254 bytes in length.
+     * * The null byte 0x00 acts as a frame delimiter. There is no null bytes inside frames.
+     * * Every frame starts with an "overhead" byte indicating the number of non-null payload bytes until the next null
+     *   byte in the payload, **plus one**. This means this byte can never be zero.
+     * * Every null byte in the payload is replaced by *its* distance to *its* next null byte as above.
+     *
+     * This means, at any point the receiver can efficiently be synchronized on the next frame boundary by simply
+     * waiting for a null byte. After that, only a simple state machine is necessary to strip the overhead byte and a
+     * counter to then count skip intervals.
+     *
+     * Here is Wikipedia's table of example values:
+     *
+     *    Unencoded data          Encoded with COBS
+     *    00                      01 01 00
+     *    00 00                   01 01 01 00
+     *    11 22 00 33             03 11 22 02 33 00
+     *    11 22 33 44             05 11 22 33 44 00
+     *    11 00 00 00             02 11 01 01 01 00
+     *    01 02 ...FE             FF 01 02 ...FE 00
+     *
+     * [0] https://en.wikipedia.org/wiki/Consistent_Overhead_Byte_Stuffing
+     * [1] Cheshire, Stuart; Baker, Mary (1999). "Consistent Overhead Byte Stuffing"
+     *     IEEE/ACM Transactions on Networking. doi:10.1109/90.769765
+     *     http://www.stuartcheshire.org/papers/COBSforToN.pdf
+     */
+
+    /* This pointer stores where we write data. The higher-level protocol logic decides on a frame-by-frame-basis where
+     * the next frame's data will be stored. */
+    static volatile uint8_t *writep = rx_buf.byte_data;
+    /* Index inside the current frame payload */
+    static int rxpos = 0;
+    /* COBS state machine. This implementation might be a little too complicated, but it works well enough and I find it
+     * reasonably easy to understand. */
+    static enum {
+        COBS_WAIT_SYNC = 0,  /* Synchronize with frame */
+        COBS_WAIT_START = 1, /* Await overhead byte */
+        COBS_RUNNING = 2     /* Process payload */
+    } cobs_state = 0;
+    /* COBS skip counter. During payload processing this contains the remaining non-null payload bytes */
+    static int cobs_count = 0;
+
+    if (USART1->ISR & USART_ISR_ORE) { /* Overrun handling */
+        uart_overruns++;
+        trigger_error_led();
+        /* Reset and re-synchronize. Retry next frame. */
+        rxpos = 0;
+        cobs_state = COBS_WAIT_SYNC;
+        /* Clear interrupt flag */
+        USART1->ICR = USART_ICR_ORECF;
+
+    } else { /* Data received */
+        uint8_t data = USART1->RDR; /* This automatically acknowledges the IRQ */
+
+        if (data == 0x00) { /* End-of-packet */
+            /* Process higher protocol layers on this packet. */
+            writep = packet_received(rxpos);
+
+            /* Reset for next packet. */
+            cobs_state = COBS_WAIT_START;
+            rxpos = 0;
+
+        } else { /* non-null byte */
+            if (cobs_state == COBS_WAIT_SYNC) { /* Wait for null byte */
+                /* ignore data */
+
+            } else if (cobs_state == COBS_WAIT_START) { /* Overhead byte */
+                cobs_count = data;
+                cobs_state = COBS_RUNNING;
+
+            } else { /* Payload byte */
+                if (--cobs_count == 0) { /* Skip byte */
+                    cobs_count = data;
+                    data = 0;
+                }
+
+                /* Write processed payload byte to current receive buffer */
+                writep[rxpos++] = data;
+            }
+        }
+    }
+}
+
-- 
cgit