ao_convert.c \
ao_serial.c
+#
+# Spi bus driver
+#
+SPI_DRIVER_SRC = \
+ ao_spi.c
+
#
# Debug dongle driver (only on TI)
#
ao_serial_init(void);
#endif
+/*
+ * ao_spi.c
+ */
+
+void
+ao_spi_send(void __xdata *block, uint16_t len) __reentrant;
+
+void
+ao_spi_recv(void __xdata *block, uint16_t len) __reentrant;
+
+void
+ao_spi_init(void);
+
/*
* ao_gps.c
*/
#define EE_CS P1_2
#define EE_CS_INDEX 2
-__xdata uint8_t ao_ee_dma_in_done;
-__xdata uint8_t ao_ee_dma_out_done;
__xdata uint8_t ao_ee_mutex;
-uint8_t ao_ee_dma_out_id;
-uint8_t ao_ee_dma_in_id;
-
-static __xdata uint8_t ao_ee_const = 0xff;
-
#define ao_ee_delay() do { \
_asm nop _endasm; \
_asm nop _endasm; \
ao_ee_delay();
}
-/* Send bytes over SPI.
- *
- * This sets up two DMA engines, one writing the data and another reading
- * bytes coming back. We use the bytes coming back to tell when the transfer
- * is complete, as the transmit register is double buffered and hence signals
- * completion one byte before the transfer is actually complete
- */
-static void
-ao_ee_send(void __xdata *block, uint16_t len)
-{
- ao_dma_set_transfer(ao_ee_dma_in_id,
- &U0DBUFXADDR,
- &ao_ee_const,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_URX0,
- DMA_CFG1_SRCINC_0 |
- DMA_CFG1_DESTINC_0 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_set_transfer(ao_ee_dma_out_id,
- block,
- &U0DBUFXADDR,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_UTX0,
- DMA_CFG1_SRCINC_1 |
- DMA_CFG1_DESTINC_0 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_start(ao_ee_dma_in_id);
- ao_dma_start(ao_ee_dma_out_id);
- ao_dma_trigger(ao_ee_dma_out_id);
- __critical while (!ao_ee_dma_in_done)
- ao_sleep(&ao_ee_dma_in_done);
-}
-
-/* Receive bytes over SPI.
- *
- * This sets up tow DMA engines, one reading the data and another
- * writing constant values to the SPI transmitter as that is what
- * clocks the data coming in.
- */
-static void
-ao_ee_recv(void __xdata *block, uint16_t len)
-{
- ao_dma_set_transfer(ao_ee_dma_in_id,
- &U0DBUFXADDR,
- block,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_URX0,
- DMA_CFG1_SRCINC_0 |
- DMA_CFG1_DESTINC_1 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_set_transfer(ao_ee_dma_out_id,
- &ao_ee_const,
- &U0DBUFXADDR,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_UTX0,
- DMA_CFG1_SRCINC_0 |
- DMA_CFG1_DESTINC_0 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_start(ao_ee_dma_in_id);
- ao_dma_start(ao_ee_dma_out_id);
- ao_dma_trigger(ao_ee_dma_out_id);
- __critical while (!ao_ee_dma_in_done)
- ao_sleep(&ao_ee_dma_in_done);
-}
#define EE_BLOCK 256
{
ao_ee_cs_low();
ao_ee_instruction.instruction = EE_WREN;
- ao_ee_send(&ao_ee_instruction, 1);
+ ao_spi_send(&ao_ee_instruction, 1);
ao_ee_cs_high();
}
{
ao_ee_cs_low();
ao_ee_instruction.instruction = EE_RDSR;
- ao_ee_send(&ao_ee_instruction, 1);
- ao_ee_recv(&ao_ee_instruction, 1);
+ ao_spi_send(&ao_ee_instruction, 1);
+ ao_spi_recv(&ao_ee_instruction, 1);
ao_ee_cs_high();
return ao_ee_instruction.instruction;
}
ao_ee_cs_low();
ao_ee_instruction.instruction = EE_WRSR;
ao_ee_instruction.address[0] = status;
- ao_ee_send(&ao_ee_instruction, 2);
+ ao_spi_send(&ao_ee_instruction, 2);
ao_ee_cs_high();
}
ao_ee_instruction.address[0] = ao_ee_block >> 8;
ao_ee_instruction.address[1] = ao_ee_block;
ao_ee_instruction.address[2] = 0;
- ao_ee_send(&ao_ee_instruction, 4);
- ao_ee_send(ao_ee_data, EE_BLOCK);
+ ao_spi_send(&ao_ee_instruction, 4);
+ ao_spi_send(ao_ee_data, EE_BLOCK);
ao_ee_cs_high();
for (;;) {
uint8_t status = ao_ee_rdsr();
ao_ee_instruction.address[0] = ao_ee_block >> 8;
ao_ee_instruction.address[1] = ao_ee_block;
ao_ee_instruction.address[2] = 0;
- ao_ee_send(&ao_ee_instruction, 4);
- ao_ee_recv(ao_ee_data, EE_BLOCK);
+ ao_spi_send(&ao_ee_instruction, 4);
+ ao_spi_recv(ao_ee_data, EE_BLOCK);
ao_ee_cs_high();
}
P1DIR |= (1 << EE_CS_INDEX);
P1SEL &= ~(1 << EE_CS_INDEX);
- /* Set up the USART pin assignment */
- PERCFG = (PERCFG & ~PERCFG_U0CFG_ALT_MASK) | PERCFG_U0CFG_ALT_2;
-
- /* Ensure that USART0 takes precidence over USART1 for pins that
- * they share
- */
- P2SEL = (P2SEL & ~P2SEL_PRI3P1_MASK) | P2SEL_PRI3P1_USART0;
-
- /* Make the SPI pins be controlled by the USART peripheral */
- P1SEL |= ((1 << 5) | (1 << 4) | (1 << 3));
-
- /* Set up OUT DMA */
- ao_ee_dma_out_id = ao_dma_alloc(&ao_ee_dma_out_done);
-
- /* Set up IN DMA */
- ao_ee_dma_in_id = ao_dma_alloc(&ao_ee_dma_in_done);
-
- /* Set up the USART.
- *
- * SPI master mode
- */
- U0CSR = (UxCSR_MODE_SPI | UxCSR_RE | UxCSR_MASTER);
-
- /* Set the baud rate and signal parameters
- *
- * The cc1111 is limited to a 24/8 MHz SPI clock,
- * while the 25LC1024 is limited to 20MHz. So,
- * use the 3MHz clock (BAUD_E 17, BAUD_M 0)
- */
- U0BAUD = 0;
- U0GCR = (UxGCR_CPOL_NEGATIVE |
- UxGCR_CPHA_FIRST_EDGE |
- UxGCR_ORDER_MSB |
- (17 << UxGCR_BAUD_E_SHIFT));
ao_cmd_register(&ao_ee_cmds[0]);
}
#include "ao.h"
#include "at45db161d.h"
-/*
- * Using SPI on USART 0, with P1_1 as the chip select
- */
-
#define FLASH_CS P1_1
#define FLASH_CS_INDEX 1
-__xdata uint8_t ao_flash_dma_in_done;
-__xdata uint8_t ao_flash_dma_out_done;
__xdata uint8_t ao_flash_mutex;
-uint8_t ao_flash_dma_out_id;
-uint8_t ao_flash_dma_in_id;
-
-static __xdata uint8_t ao_flash_const = 0xff;
-
#define ao_flash_delay() do { \
_asm nop _endasm; \
_asm nop _endasm; \
ao_flash_delay();
}
-/* Send bytes over SPI.
- *
- * This sets up two DMA engines, one writing the data and another reading
- * bytes coming back. We use the bytes coming back to tell when the transfer
- * is complete, as the transmit register is double buffered and hence signals
- * completion one byte before the transfer is actually complete
- */
-static void
-ao_flash_send(void __xdata *block, uint16_t len)
-{
- ao_dma_set_transfer(ao_flash_dma_in_id,
- &U0DBUFXADDR,
- &ao_flash_const,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_URX0,
- DMA_CFG1_SRCINC_0 |
- DMA_CFG1_DESTINC_0 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_set_transfer(ao_flash_dma_out_id,
- block,
- &U0DBUFXADDR,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_UTX0,
- DMA_CFG1_SRCINC_1 |
- DMA_CFG1_DESTINC_0 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_start(ao_flash_dma_in_id);
- ao_dma_start(ao_flash_dma_out_id);
- ao_dma_trigger(ao_flash_dma_out_id);
- __critical while (!ao_flash_dma_in_done)
- ao_sleep(&ao_flash_dma_in_done);
-}
-
-/* Receive bytes over SPI.
- *
- * This sets up tow DMA engines, one reading the data and another
- * writing constant values to the SPI transmitter as that is what
- * clocks the data coming in.
- */
-static void
-ao_flash_recv(void __xdata *block, uint16_t len)
-{
- ao_dma_set_transfer(ao_flash_dma_in_id,
- &U0DBUFXADDR,
- block,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_URX0,
- DMA_CFG1_SRCINC_0 |
- DMA_CFG1_DESTINC_1 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_set_transfer(ao_flash_dma_out_id,
- &ao_flash_const,
- &U0DBUFXADDR,
- len,
- DMA_CFG0_WORDSIZE_8 |
- DMA_CFG0_TMODE_SINGLE |
- DMA_CFG0_TRIGGER_UTX0,
- DMA_CFG1_SRCINC_0 |
- DMA_CFG1_DESTINC_0 |
- DMA_CFG1_PRIORITY_NORMAL);
-
- ao_dma_start(ao_flash_dma_in_id);
- ao_dma_start(ao_flash_dma_out_id);
- ao_dma_trigger(ao_flash_dma_out_id);
- __critical while (!ao_flash_dma_in_done)
- ao_sleep(&ao_flash_dma_in_done);
-}
-
struct ao_flash_instruction {
uint8_t instruction;
uint8_t address[3];
ao_flash_instruction.address[0] = FLASH_SET_512_BYTE_0;
ao_flash_instruction.address[1] = FLASH_SET_512_BYTE_1;
ao_flash_instruction.address[2] = FLASH_SET_512_BYTE_2;
- ao_flash_send(&ao_flash_instruction, 4);
+ ao_spi_send(&ao_flash_instruction, 4);
ao_flash_cs_high();
}
{
ao_flash_cs_low();
ao_flash_instruction.instruction = FLASH_READ_STATUS;
- ao_flash_send(&ao_flash_instruction, 1);
- ao_flash_recv(&ao_flash_instruction, 1);
+ ao_spi_send(&ao_flash_instruction, 1);
+ ao_spi_recv(&ao_flash_instruction, 1);
ao_flash_cs_high();
return ao_flash_instruction.instruction;
}
ao_flash_instruction.address[0] = ao_flash_block >> (16 - ao_flash_block_shift);
ao_flash_instruction.address[1] = ao_flash_block << (ao_flash_block_shift - 8);
ao_flash_instruction.address[2] = 0;
- ao_flash_send(&ao_flash_instruction, 4);
- ao_flash_send(ao_flash_data, FLASH_BLOCK_SIZE);
+ ao_spi_send(&ao_flash_instruction, 4);
+ ao_spi_send(ao_flash_data, FLASH_BLOCK_SIZE);
ao_flash_cs_high();
ao_flash_write_pending = 1;
}
ao_flash_instruction.address[0] = ao_flash_block >> (16 - ao_flash_block_shift);
ao_flash_instruction.address[1] = ao_flash_block << (ao_flash_block_shift - 8);
ao_flash_instruction.address[2] = 0;
- ao_flash_send(&ao_flash_instruction, 4);
- ao_flash_recv(ao_flash_data, FLASH_BLOCK_SIZE);
+ ao_spi_send(&ao_flash_instruction, 4);
+ ao_spi_recv(ao_flash_data, FLASH_BLOCK_SIZE);
ao_flash_cs_high();
}
FLASH_CS = 1;
P1DIR |= (1 << FLASH_CS_INDEX);
P1SEL &= ~(1 << FLASH_CS_INDEX);
-
- /* Set up the USART pin assignment */
- PERCFG = (PERCFG & ~PERCFG_U0CFG_ALT_MASK) | PERCFG_U0CFG_ALT_2;
-
- /* Ensure that USART0 takes precidence over USART1 for pins that
- * they share
- */
- P2SEL = (P2SEL & ~P2SEL_PRI3P1_MASK) | P2SEL_PRI3P1_USART0;
-
- /* Make the SPI pins be controlled by the USART peripheral */
- P1SEL |= ((1 << 5) | (1 << 4) | (1 << 3));
-
- /* Set up OUT DMA */
- ao_flash_dma_out_id = ao_dma_alloc(&ao_flash_dma_out_done);
-
- /* Set up IN DMA */
- ao_flash_dma_in_id = ao_dma_alloc(&ao_flash_dma_in_done);
-
- /* Set up the USART.
- *
- * SPI master mode
- */
- U0CSR = (UxCSR_MODE_SPI | UxCSR_RE | UxCSR_MASTER);
-
- /* Set the baud rate and signal parameters
- *
- * The cc1111 is limited to a 24/8 MHz SPI clock,
- * while the at45db161d.h is limited to 20MHz. So,
- * use the 3MHz clock (BAUD_E 17, BAUD_M 0)
- */
- U0BAUD = 0;
- U0GCR = (UxGCR_CPOL_NEGATIVE |
- UxGCR_CPHA_FIRST_EDGE |
- UxGCR_ORDER_MSB |
- (17 << UxGCR_BAUD_E_SHIFT));
ao_cmd_register(&ao_flash_cmds[0]);
}
#define AO_LED_RED 1
#define LEDS_AVAILABLE (AO_LED_RED)
#define HAS_EXTERNAL_TEMP 0
+ #define SPI_CS_ON_P1 1
+ #define SPI_CS_ON_P0 0
#endif
#if defined(TELEDONGLE_V_0_2)
#define AO_LED_RED 1
#define AO_LED_GREEN 2
#define LEDS_AVAILABLE (AO_LED_RED|AO_LED_GREEN)
+ #define SPI_CS_ON_P1 1
+ #define SPI_CS_ON_P0 0
#endif
#if defined(TELEMETRUM_V_0_1)
#define AO_LED_GREEN 1
#define LEDS_AVAILABLE (AO_LED_RED|AO_LED_GREEN)
#define HAS_EXTERNAL_TEMP 1
+ #define SPI_CS_ON_P1 1
+ #define SPI_CS_ON_P0 0
#endif
#if defined(TELEDONGLE_V_0_1)
#define AO_LED_RED 2
#define AO_LED_GREEN 1
#define LEDS_AVAILABLE (AO_LED_RED|AO_LED_GREEN)
+ #define SPI_CS_ON_P1 0
+ #define SPI_CS_ON_P0 1
#endif
#if defined(TIDONGLE)
#define PACKET_HAS_SLAVE 0
#define AO_LED_RED 2
#define LEDS_AVAILABLE (AO_LED_RED)
+ #define SPI_CS_ON_P1 0
+ #define SPI_CS_ON_P0 1
#endif
#if DBG_ON_P1
#endif /* DBG_ON_P0 */
+#if SPI_CS_ON_P1
+ #define SPI_CS_PORT P1
+ #define SPI_CS_SEL P1SEL
+ #define SPI_CS_DIR P1DIR
+#endif
+
+#if SPI_CS_ON_P0
+ #define SPI_CS_PORT P0
+ #define SPI_CS_SEL P0SEL
+ #define SPI_CS_DIR P0DIR
+#endif
+
#ifndef HAS_SERIAL_1
#error Please define HAS_SERIAL_1
#endif
--- /dev/null
+/*
+ * Copyright © 2010 Keith Packard <keithp@keithp.com>
+ *
+ * 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; version 2 of the License.
+ *
+ * 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, write to the Free Software Foundation, Inc.,
+ * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
+ */
+
+#include "ao.h"
+
+__xdata uint8_t ao_spi_mutex;
+__xdata uint8_t ao_spi_dma_in_done;
+__xdata uint8_t ao_spi_dma_out_done;
+
+uint8_t ao_spi_dma_out_id;
+uint8_t ao_spi_dma_in_id;
+
+static __xdata uint8_t ao_spi_const = 0xff;
+
+/* Send bytes over SPI.
+ *
+ * This sets up two DMA engines, one writing the data and another reading
+ * bytes coming back. We use the bytes coming back to tell when the transfer
+ * is complete, as the transmit register is double buffered and hence signals
+ * completion one byte before the transfer is actually complete
+ */
+void
+ao_spi_send(void __xdata *block, uint16_t len) __reentrant
+{
+ ao_mutex_get(&ao_spi_mutex);
+ ao_dma_set_transfer(ao_spi_dma_in_id,
+ &U0DBUFXADDR,
+ &ao_spi_const,
+ len,
+ DMA_CFG0_WORDSIZE_8 |
+ DMA_CFG0_TMODE_SINGLE |
+ DMA_CFG0_TRIGGER_URX0,
+ DMA_CFG1_SRCINC_0 |
+ DMA_CFG1_DESTINC_0 |
+ DMA_CFG1_PRIORITY_NORMAL);
+
+ ao_dma_set_transfer(ao_spi_dma_out_id,
+ block,
+ &U0DBUFXADDR,
+ len,
+ DMA_CFG0_WORDSIZE_8 |
+ DMA_CFG0_TMODE_SINGLE |
+ DMA_CFG0_TRIGGER_UTX0,
+ DMA_CFG1_SRCINC_1 |
+ DMA_CFG1_DESTINC_0 |
+ DMA_CFG1_PRIORITY_NORMAL);
+
+ ao_dma_start(ao_spi_dma_in_id);
+ ao_dma_start(ao_spi_dma_out_id);
+ ao_dma_trigger(ao_spi_dma_out_id);
+ __critical while (!ao_spi_dma_in_done)
+ ao_sleep(&ao_spi_dma_in_done);
+ ao_mutex_put(&ao_spi_mutex);
+}
+
+/* Receive bytes over SPI.
+ *
+ * This sets up tow DMA engines, one reading the data and another
+ * writing constant values to the SPI transmitter as that is what
+ * clocks the data coming in.
+ */
+void
+ao_spi_recv(void __xdata *block, uint16_t len) __reentrant
+{
+ ao_mutex_get(&ao_spi_mutex);
+ ao_dma_set_transfer(ao_spi_dma_in_id,
+ &U0DBUFXADDR,
+ block,
+ len,
+ DMA_CFG0_WORDSIZE_8 |
+ DMA_CFG0_TMODE_SINGLE |
+ DMA_CFG0_TRIGGER_URX0,
+ DMA_CFG1_SRCINC_0 |
+ DMA_CFG1_DESTINC_1 |
+ DMA_CFG1_PRIORITY_NORMAL);
+
+ ao_dma_set_transfer(ao_spi_dma_out_id,
+ &ao_spi_const,
+ &U0DBUFXADDR,
+ len,
+ DMA_CFG0_WORDSIZE_8 |
+ DMA_CFG0_TMODE_SINGLE |
+ DMA_CFG0_TRIGGER_UTX0,
+ DMA_CFG1_SRCINC_0 |
+ DMA_CFG1_DESTINC_0 |
+ DMA_CFG1_PRIORITY_NORMAL);
+
+ ao_dma_start(ao_spi_dma_in_id);
+ ao_dma_start(ao_spi_dma_out_id);
+ ao_dma_trigger(ao_spi_dma_out_id);
+ __critical while (!ao_spi_dma_in_done)
+ ao_sleep(&ao_spi_dma_in_done);
+ ao_mutex_put(&ao_spi_mutex);
+}
+
+/*
+ * Initialize USART0 for SPI using config alt 2
+ *
+ * MO P1_5
+ * MI P1_4
+ * CLK P1_3
+ *
+ * Chip select is the responsibility of the caller
+ */
+
+void
+ao_spi_init(void)
+{
+ /* Set up the USART pin assignment */
+ PERCFG = (PERCFG & ~PERCFG_U0CFG_ALT_MASK) | PERCFG_U0CFG_ALT_2;
+
+ /* Ensure that USART0 takes precidence over USART1 for pins that
+ * they share
+ */
+ P2SEL = (P2SEL & ~P2SEL_PRI3P1_MASK) | P2SEL_PRI3P1_USART0;
+
+ /* Make the SPI pins be controlled by the USART peripheral */
+ P1SEL |= ((1 << 5) | (1 << 4) | (1 << 3));
+
+ /* Set up OUT DMA */
+ ao_spi_dma_out_id = ao_dma_alloc(&ao_spi_dma_out_done);
+
+ /* Set up IN DMA */
+ ao_spi_dma_in_id = ao_dma_alloc(&ao_spi_dma_in_done);
+
+ /* Set up the USART.
+ *
+ * SPI master mode
+ */
+ U0CSR = (UxCSR_MODE_SPI | UxCSR_RE | UxCSR_MASTER);
+
+ /* Set the baud rate and signal parameters
+ *
+ * The cc1111 is limited to a 24/8 MHz SPI clock.
+ * Every peripheral I've ever seen goes faster than that,
+ * so set the clock to 3MHz (BAUD_E 17, BAUD_M 0)
+ */
+ U0BAUD = 0;
+ U0GCR = (UxGCR_CPOL_NEGATIVE |
+ UxGCR_CPHA_FIRST_EDGE |
+ UxGCR_ORDER_MSB |
+ (17 << UxGCR_BAUD_E_SHIFT));
+}
ao_adc_init();
ao_beep_init();
ao_cmd_init();
+ ao_spi_init();
ao_ee_init();
ao_flight_init();
ao_log_init();
SRC = \
$(TM_BASE_SRC) \
+ $(SPI_DRIVER_SRC) \
$(EE_DRIVER_SRC) \
$(SIRF_DRIVER_SRC) \
$(DBG_SRC)
SRC = \
$(TM_BASE_SRC) \
+ $(SPI_DRIVER_SRC) \
$(EE_DRIVER_SRC) \
$(SKY_DRIVER_SRC) \
$(DBG_SRC)
SRC = \
$(TM_BASE_SRC) \
+ $(SPI_DRIVER_SRC) \
$(FLASH_DRIVER_SRC) \
$(SKY_DRIVER_SRC) \
$(DBG_SRC)