/* Copyright 2007, Freie Universitaet Berlin. All rights reserved. These sources were developed at the Freie Universität Berlin, Computer Systems and Telematics group. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. - Neither the name of Freie Universitaet Berlin (FUB) nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. This software is provided by FUB and the contributors on an "as is" basis, without any representations or warranties of any kind, express or implied including, but not limited to, representations or warranties of non-infringement, merchantability or fitness for a particular purpose. In no event shall FUB or contributors be liable for any direct, indirect, incidental, special, exemplary, or consequential damages (including, but not limited to, procurement of substitute goods or services; loss of use, data, or profits; or business interruption) however caused and on any theory of liability, whether in contract, strict liability, or tort (including negligence or otherwise) arising in any way out of the use of this software, even if advised of the possibility of such damage. This implementation was developed by the CST group at the FUB. For documentation and questions please use the web site http://scatterweb.mi.fu-berlin.de and the mailinglist scatterweb@lists.spline.inf.fu-berlin.de (subscription via the Website). Berlin, 2007 */ /** * @file ScatterWeb.Spi.c * @ingroup libsdspi * @brief Serial Peripheral Interface for SD library * * @author Michael Baar * @version $Revision: 1.2 $ * * $Id: sdspi.c,v 1.2 2008/03/28 23:03:05 nvt-se Exp $ */ #include #include "contiki-msb430.h" #if SPI_DMA_WRITE uint8_t sdspi_dma_lock; #endif #ifndef U1IFG #define U1IFG IFG2 #endif #define SPI_IDLE_SYMBOL 0xFF void sdspi_init(void) { #if SPI_DMA_WRITE sdspi_dma_lock = FALSE; #endif /* The 16-bit value of UxBR0+UxBR1 is the division factor of the USART clock * source, BRCLK. The maximum baud rate that can be generated in master * mode is BRCLK/2. The maximum baud rate that can be generated in slave * mode is BRCLK. The modulator in the USART baud rate generator is not used * for SPI mode and is recommended to be set to 000h. The UCLK frequency is * given by: * Baud rate = BRCLK / UxBR with UxBR= [UxBR1, UxBR0] */ uart_set_speed(UART_MODE_SPI, 0x02, 0x00, 0x00); } uint8_t sdspi_rx(void) { UART_TX = SPI_IDLE_SYMBOL; UART_WAIT_RX(); return (UART_RX); } void sdspi_tx(register const uint8_t c) { UART_TX = c; UART_WAIT_TXDONE(); } #if SPI_DMA_READ || SPI_DMA_WRITE void sdspi_dma_wait(void) { while (DMA0CTL & DMAEN) { _NOP(); } // Wait until a previous transfer is complete } #endif void sdspi_read(void *pDestination, const uint16_t size, const bool incDest) { #if SPI_DMA_READ sdspi_dma_wait(); UART_RESET_RXTX(); // clear interrupts // Configure the DMA transfer DMA0SA = (uint16_t) & UART_RX; // source DMA address DMA0DA = (uint16_t) pDestination; // destination DMA address DMA0SZ = size; // number of bytes to be transferred DMA1SA = (uint16_t) & UART_TX; // source DMA address (constant 0xff) DMA1DA = DMA1SA; // destination DMA address DMA1SZ = size - 1; // number of bytes to be transferred DMACTL0 = DMA0TSEL_9 | DMA1TSEL_9; // trigger is UART1 receive for both DMA0 and DMA1 DMA0CTL = DMADT_0 | // Single transfer mode DMASBDB | // Byte mode DMADSTINCR0 | DMADSTINCR1 | // Increment destination DMAEN; // Enable DMA if (!incDest) { DMA0CTL &= ~(DMADSTINCR0 | DMADSTINCR1); } DMA1CTL = DMADT_0 | // Single transfer mode DMASBDB | // Byte mode DMAEN; // Enable DMA UART_TX = SPI_IDLE_SYMBOL; // Initiate transfer by sending the first byte sdspi_dma_wait(); #else register uint8_t *p = (uint8_t *) pDestination; register uint16_t i = size; do { UART_TX = SPI_IDLE_SYMBOL; UART_WAIT_RX(); *p = UART_RX; if (incDest) { p++; } i--; } while (i); #endif } #if SPI_WRITE void sdspi_write(const void *pSource, const uint16_t size, const int increment) { #if SPI_DMA_WRITE sdspi_dma_wait(); UART_RESET_RXTX(); // clear interrupts // Configure the DMA transfer DMA0SA = ((uint16_t) pSource) + 1; // source DMA address DMA0DA = (uint16_t) & UART_TX; // destination DMA address DMA0SZ = size - 1; // number of bytes to be transferred DMACTL0 = DMA0TSEL_9; // trigger is UART1 receive DMA0CTL = DMADT_0 | // Single transfer mode DMASBDB | // Byte mode DMASRCINCR_3 | // Increment source DMAEN; // Enable DMA if (increment == 0) { DMA0CTL &= ~DMASRCINCR_3; } sdspi_dma_lock = TRUE; SPI_TX = ((uint8_t *) pSource)[0]; #else register uint8_t *p = (uint8_t *) pSource; register uint16_t i = size; do { UART_TX = *p; UART_WAIT_TXDONE(); UART_RX; p += increment; i--; } while (i); #endif } #endif void sdspi_idle(register const uint16_t clocks) { register uint16_t i = clocks; do { UART_TX = SPI_IDLE_SYMBOL; UART_WAIT_RX(); UART_RX; i--; } while (i); } uint16_t sdspi_wait_token(const uint8_t feed, const uint8_t mask, const uint8_t token, const uint16_t timeout) { uint16_t i = 0; uint8_t rx; do { UART_TX = feed; UART_WAIT_RX(); rx = UART_RX; i++; } while (((rx & mask) != token) && (i < timeout)); return i; }