-/* 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
-