/* * Copyright (c) 2016 Linaro Limited. * * SPDX-License-Identifier: Apache-2.0 * */ #define SYS_LOG_LEVEL CONFIG_SYS_LOG_DMA_LEVEL #include #include #include #include #include #include #include #include #include #define DMA_STM32_MAX_STREAMS 8 /* Number of streams per controller */ #define DMA_STM32_MAX_DEVS 2 /* Number of controllers */ #define DMA_STM32_1 0 /* First DMA controller */ #define DMA_STM32_2 1 /* Second DMA controller */ #define DMA_STM32_IRQ_PRI CONFIG_DMA_0_IRQ_PRI #define DMA_STM32_1_RX_CHANNEL_ID CONFIG_DMA_1_RX_SUB_CHANNEL_ID #define DMA_STM32_1_TX_CHANNEL_ID CONFIG_DMA_1_TX_SUB_CHANNEL_ID #define DMA_STM32_2_RX_CHANNEL_ID CONFIG_DMA_2_RX_SUB_CHANNEL_ID #define DMA_STM32_2_TX_CHANNEL_ID CONFIG_DMA_2_TX_SUB_CHANNEL_ID struct dma_stm32_stream_reg { /* Shared registers */ u32_t lisr; u32_t hisr; u32_t lifcr; u32_t hifcr; /* Per stream registers */ u32_t scr; u32_t sndtr; u32_t spar; u32_t sm0ar; u32_t sm1ar; u32_t sfcr; }; struct dma_stm32_stream { u32_t direction; struct device *dev; struct dma_stm32_stream_reg regs; bool busy; void (*dma_callback)(struct device *dev, u32_t id, int error_code); }; static struct dma_stm32_device { u32_t base; struct device *clk; struct dma_stm32_stream stream[DMA_STM32_MAX_STREAMS]; bool mem2mem; u8_t channel_rx; u8_t channel_tx; } device_data[DMA_STM32_MAX_DEVS]; struct dma_stm32_config { struct stm32_pclken pclken; void (*config)(struct dma_stm32_device *); }; /* DMA burst length */ #define BURST_TRANS_LENGTH_1 0 /* DMA direction */ #define DMA_STM32_DEV_TO_MEM 0 #define DMA_STM32_MEM_TO_DEV 1 #define DMA_STM32_MEM_TO_MEM 2 /* DMA priority level */ #define DMA_STM32_PRIORITY_LOW 0 #define DMA_STM32_PRIORITY_MEDIUM 1 #define DMA_STM32_PRIORITY_HIGH 2 #define DMA_STM32_PRIORITY_VERY_HIGH 3 /* DMA FIFO threshold selection */ #define DMA_STM32_FIFO_THRESHOLD_1QUARTERFULL 0 #define DMA_STM32_FIFO_THRESHOLD_HALFFULL 1 #define DMA_STM32_FIFO_THRESHOLD_3QUARTERSFULL 2 #define DMA_STM32_FIFO_THRESHOLD_FULL 3 /* Maximum data sent in single transfer (Bytes) */ #define DMA_STM32_MAX_DATA_ITEMS 0xffff #define BITS_PER_LONG 32 #define GENMASK(h, l) (((~0UL) << (l)) & (~0UL >> (BITS_PER_LONG - 1 - (h)))) #define DMA_STM32_1_BASE 0x40026000 #define DMA_STM32_2_BASE 0x40026400 /* Shared registers */ #define DMA_STM32_LISR 0x00 /* DMA low int status reg */ #define DMA_STM32_HISR 0x04 /* DMA high int status reg */ #define DMA_STM32_LIFCR 0x08 /* DMA low int flag clear reg */ #define DMA_STM32_HIFCR 0x0c /* DMA high int flag clear reg */ #define DMA_STM32_FEI BIT(0) /* FIFO error interrupt */ #define RESERVED_1 BIT(1) #define DMA_STM32_DMEI BIT(2) /* Direct mode error interrupt */ #define DMA_STM32_TEI BIT(3) /* Transfer error interrupt */ #define DMA_STM32_HTI BIT(4) /* Transfer half complete interrupt */ #define DMA_STM32_TCI BIT(5) /* Transfer complete interrupt */ /* DMA Stream x Configuration Register */ #define DMA_STM32_SCR(x) (0x10 + 0x18 * (x)) #define DMA_STM32_SCR_EN BIT(0) /* Stream Enable */ #define DMA_STM32_SCR_DMEIE BIT(1) /* Direct Mode Err Int En */ #define DMA_STM32_SCR_TEIE BIT(2) /* Transfer Error Int En */ #define DMA_STM32_SCR_HTIE BIT(3) /* Transfer 1/2 Comp Int En */ #define DMA_STM32_SCR_TCIE BIT(4) /* Transfer Comp Int En */ #define DMA_STM32_SCR_PFCTRL BIT(5) /* Peripheral Flow Controller */ #define DMA_STM32_SCR_DIR_MASK GENMASK(7, 6) /* Transfer direction */ #define DMA_STM32_SCR_CIRC BIT(8) /* Circular mode */ #define DMA_STM32_SCR_PINC BIT(9) /* Peripheral increment mode */ #define DMA_STM32_SCR_MINC BIT(10) /* Memory increment mode */ #define DMA_STM32_SCR_PSIZE_MASK GENMASK(12, 11) /* Periph data size */ #define DMA_STM32_SCR_MSIZE_MASK GENMASK(14, 13) /* Memory data size */ #define DMA_STM32_SCR_PINCOS BIT(15) /* Periph inc offset size */ #define DMA_STM32_SCR_PL_MASK GENMASK(17, 16) /* Priority level */ #define DMA_STM32_SCR_DBM BIT(18) /* Double Buffer Mode */ #define DMA_STM32_SCR_CT BIT(19) /* Target in double buffer */ #define DMA_STM32_SCR_PBURST_MASK GENMASK(22, 21) /* Periph burst size */ #define DMA_STM32_SCR_MBURST_MASK GENMASK(24, 23) /* Memory burst size */ /* Setting MACROS */ #define DMA_STM32_SCR_DIR(n) ((n & 0x3) << 6) #define DMA_STM32_SCR_PSIZE(n) ((n & 0x3) << 11) #define DMA_STM32_SCR_MSIZE(n) ((n & 0x3) << 13) #define DMA_STM32_SCR_PL(n) ((n & 0x3) << 16) #define DMA_STM32_SCR_PBURST(n) ((n & 0x3) << 21) #define DMA_STM32_SCR_MBURST(n) ((n & 0x3) << 23) #define DMA_STM32_SCR_REQ(n) ((n & 0x7) << 25) /* Getting MACROS */ #define DMA_STM32_SCR_PSIZE_GET(n) ((n & DMA_STM32_SCR_PSIZE_MASK) >> 11) #define DMA_STM32_SCR_CFG_MASK (DMA_STM32_SCR_PINC \ | DMA_STM32_SCR_MINC \ | DMA_STM32_SCR_PINCOS \ | DMA_STM32_SCR_PL_MASK) #define DMA_STM32_SCR_IRQ_MASK (DMA_STM32_SCR_TCIE \ | DMA_STM32_SCR_TEIE \ | DMA_STM32_SCR_DMEIE) /* DMA stream x number of data register (len) */ #define DMA_STM32_SNDTR(x) (0x14 + 0x18 * (x)) /* DMA stream peripheral address register (source) */ #define DMA_STM32_SPAR(x) (0x18 + 0x18 * (x)) /* DMA stream x memory 0 address register (destination) */ #define DMA_STM32_SM0AR(x) (0x1c + 0x18 * (x)) /* DMA stream x memory 1 address register (destination - double buffer) */ #define DMA_STM32_SM1AR(x) (0x20 + 0x18 * (x)) /* DMA stream x FIFO control register */ #define DMA_STM32_SFCR(x) (0x24 + 0x18 * (x)) #define DMA_STM32_SFCR_FTH_MASK GENMASK(1, 0) /* FIFO threshold */ #define DMA_STM32_SFCR_DMDIS BIT(2) /* Direct mode disable */ #define DMA_STM32_SFCR_STAT_MASK GENMASK(5, 3) /* FIFO status */ #define RESERVED_6 BIT(6) /* Reserved */ #define DMA_STM32_SFCR_FEIE BIT(7) /* FIFO error interrupt enable */ /* Setting MACROS */ #define DMA_STM32_SFCR_FTH(n) (n & DMA_STM32_SFCR_FTH_MASK) #define DMA_STM32_SFCR_MASK (DMA_STM32_SFCR_FEIE \ | DMA_STM32_SFCR_DMDIS) #define SYS_LOG_U32 __attribute((__unused__)) u32_t static void dma_stm32_1_config(struct dma_stm32_device *ddata); static void dma_stm32_2_config(struct dma_stm32_device *ddata); static u32_t dma_stm32_read(struct dma_stm32_device *ddata, u32_t reg) { return sys_read32(ddata->base + reg); } static void dma_stm32_write(struct dma_stm32_device *ddata, u32_t reg, u32_t val) { sys_write32(val, ddata->base + reg); } static void dma_stm32_dump_reg(struct dma_stm32_device *ddata, u32_t id) { SYS_LOG_INF("Using stream: %d\n", id); SYS_LOG_INF("SCR: 0x%x \t(config)\n", dma_stm32_read(ddata, DMA_STM32_SCR(id))); SYS_LOG_INF("SNDTR: 0x%x \t(length)\n", dma_stm32_read(ddata, DMA_STM32_SNDTR(id))); SYS_LOG_INF("SPAR: 0x%x \t(source)\n", dma_stm32_read(ddata, DMA_STM32_SPAR(id))); SYS_LOG_INF("SM0AR: 0x%x \t(destination)\n", dma_stm32_read(ddata, DMA_STM32_SM0AR(id))); SYS_LOG_INF("SM1AR: 0x%x \t(destination (double buffer mode))\n", dma_stm32_read(ddata, DMA_STM32_SM1AR(id))); SYS_LOG_INF("SFCR: 0x%x \t(fifo control)\n", dma_stm32_read(ddata, DMA_STM32_SFCR(id))); } static u32_t dma_stm32_irq_status(struct dma_stm32_device *ddata, u32_t id) { u32_t irqs; if (id & 4) { irqs = dma_stm32_read(ddata, DMA_STM32_HISR); } else { irqs = dma_stm32_read(ddata, DMA_STM32_LISR); } return (irqs >> (((id & 2) << 3) | ((id & 1) * 6))); } static void dma_stm32_irq_clear(struct dma_stm32_device *ddata, u32_t id, u32_t irqs) { irqs = irqs << (((id & 2) << 3) | ((id & 1) * 6)); if (id & 4) { dma_stm32_write(ddata, DMA_STM32_HIFCR, irqs); } else { dma_stm32_write(ddata, DMA_STM32_LIFCR, irqs); } } static void dma_stm32_irq_handler(void *arg, u32_t id) { struct device *dev = arg; struct dma_stm32_device *ddata = dev->driver_data; struct dma_stm32_stream *stream = &ddata->stream[id]; u32_t irqstatus, config, sfcr; irqstatus = dma_stm32_irq_status(ddata, id); config = dma_stm32_read(ddata, DMA_STM32_SCR(id)); sfcr = dma_stm32_read(ddata, DMA_STM32_SFCR(id)); /* Silently ignore spurious transfer half complete IRQ */ if (irqstatus & DMA_STM32_HTI) { dma_stm32_irq_clear(ddata, id, DMA_STM32_HTI); return; } stream->busy = false; if ((irqstatus & DMA_STM32_TCI) && (config & DMA_STM32_SCR_TCIE)) { dma_stm32_irq_clear(ddata, id, DMA_STM32_TCI); stream->dma_callback(stream->dev, id, 0); } else { SYS_LOG_ERR("Internal error: IRQ status: 0x%x\n", irqstatus); dma_stm32_irq_clear(ddata, id, irqstatus); stream->dma_callback(stream->dev, id, -EIO); } } static int dma_stm32_disable_stream(struct dma_stm32_device *ddata, u32_t id) { u32_t config; int count = 0; int ret = 0; for (;;) { config = dma_stm32_read(ddata, DMA_STM32_SCR(id)); /* Stream already disabled */ if (!(config & DMA_STM32_SCR_EN)) { return 0; } /* Try to disable stream */ dma_stm32_write(ddata, DMA_STM32_SCR(id), config &= ~DMA_STM32_SCR_EN); /* After trying for 5 seconds, give up */ k_sleep(K_SECONDS(5)); if (count++ > (5 * 1000) / 50) { SYS_LOG_ERR("DMA error: Stream in use\n"); return -EBUSY; } } return ret; } static int dma_stm32_config_devcpy(struct device *dev, u32_t id, struct dma_config *config) { struct dma_stm32_device *ddata = dev->driver_data; struct dma_stm32_stream_reg *regs = &ddata->stream[id].regs; u32_t src_bus_width = dma_width_index(config->source_data_size); u32_t dst_bus_width = dma_width_index(config->dest_data_size); u32_t src_burst_size = dma_burst_index(config->source_burst_length); u32_t dst_burst_size = dma_burst_index(config->dest_burst_length); enum dma_channel_direction direction = config->channel_direction; switch (direction) { case MEMORY_TO_PERIPHERAL: regs->scr = DMA_STM32_SCR_DIR(DMA_STM32_MEM_TO_DEV) | DMA_STM32_SCR_PSIZE(dst_bus_width) | DMA_STM32_SCR_MSIZE(src_bus_width) | DMA_STM32_SCR_PBURST(dst_burst_size) | DMA_STM32_SCR_MBURST(src_burst_size) | DMA_STM32_SCR_REQ(ddata->channel_tx) | DMA_STM32_SCR_MINC; break; case PERIPHERAL_TO_MEMORY: regs->scr = DMA_STM32_SCR_DIR(DMA_STM32_DEV_TO_MEM) | DMA_STM32_SCR_PSIZE(src_bus_width) | DMA_STM32_SCR_MSIZE(dst_bus_width) | DMA_STM32_SCR_PBURST(src_burst_size) | DMA_STM32_SCR_MBURST(dst_burst_size) | DMA_STM32_SCR_REQ(ddata->channel_rx); break; default: SYS_LOG_ERR("DMA error: Direction not supported: %d", direction); return -EINVAL; } if (src_burst_size == BURST_TRANS_LENGTH_1 && dst_burst_size == BURST_TRANS_LENGTH_1) { /* Enable 'direct' mode error IRQ, disable 'FIFO' error IRQ */ regs->scr |= DMA_STM32_SCR_DMEIE; regs->sfcr &= ~DMA_STM32_SFCR_MASK; } else { /* Enable 'FIFO' error IRQ, disable 'direct' mode error IRQ */ regs->sfcr |= DMA_STM32_SFCR_MASK; regs->scr &= ~DMA_STM32_SCR_DMEIE; } return 0; } static int dma_stm32_config_memcpy(struct device *dev, u32_t id) { struct dma_stm32_device *ddata = dev->driver_data; struct dma_stm32_stream_reg *regs = &ddata->stream[id].regs; regs->scr = DMA_STM32_SCR_DIR(DMA_STM32_MEM_TO_MEM) | DMA_STM32_SCR_MINC | /* Memory increment mode */ DMA_STM32_SCR_PINC | /* Peripheral increment mode */ DMA_STM32_SCR_TCIE | /* Transfer comp IRQ enable */ DMA_STM32_SCR_TEIE; /* Transfer error IRQ enable */ regs->sfcr = DMA_STM32_SFCR_DMDIS | /* Direct mode disable */ DMA_STM32_SFCR_FTH(DMA_STM32_FIFO_THRESHOLD_FULL) | DMA_STM32_SFCR_FEIE; /* FIFI error IRQ enable */ return 0; } static int dma_stm32_config(struct device *dev, u32_t id, struct dma_config *config) { struct dma_stm32_device *ddata = dev->driver_data; struct dma_stm32_stream *stream = &ddata->stream[id]; struct dma_stm32_stream_reg *regs = &ddata->stream[id].regs; int ret; if (stream->busy) { return -EBUSY; } if (config->head_block->block_size > DMA_STM32_MAX_DATA_ITEMS) { SYS_LOG_ERR("DMA error: Data size too big: %d\n", config->head_block->block_size); return -EINVAL; } stream->busy = true; stream->dma_callback = config->dma_callback; stream->direction = config->channel_direction; if (stream->direction == MEMORY_TO_PERIPHERAL) { regs->sm0ar = (u32_t)config->head_block->source_address; regs->spar = (u32_t)config->head_block->dest_address; } else { regs->spar = (u32_t)config->head_block->source_address; regs->sm0ar = (u32_t)config->head_block->dest_address; } if (stream->direction == MEMORY_TO_MEMORY) { ret = dma_stm32_config_memcpy(dev, id); } else { ret = dma_stm32_config_devcpy(dev, id, config); } regs->sndtr = config->head_block->block_size; return ret; } static int dma_stm32_start(struct device *dev, u32_t id) { struct dma_stm32_device *ddata = dev->driver_data; struct dma_stm32_stream_reg *regs = &ddata->stream[id].regs; u32_t irqstatus; int ret; ret = dma_stm32_disable_stream(ddata, id); if (ret) { return ret; } dma_stm32_write(ddata, DMA_STM32_SCR(id), regs->scr); dma_stm32_write(ddata, DMA_STM32_SPAR(id), regs->spar); dma_stm32_write(ddata, DMA_STM32_SM0AR(id), regs->sm0ar); dma_stm32_write(ddata, DMA_STM32_SFCR(id), regs->sfcr); dma_stm32_write(ddata, DMA_STM32_SM1AR(id), regs->sm1ar); dma_stm32_write(ddata, DMA_STM32_SNDTR(id), regs->sndtr); /* Clear remanent IRQs from previous transfers */ irqstatus = dma_stm32_irq_status(ddata, id); if (irqstatus) { dma_stm32_irq_clear(ddata, id, irqstatus); } dma_stm32_dump_reg(ddata, id); /* Push the start button */ dma_stm32_write(ddata, DMA_STM32_SCR(id), regs->scr | DMA_STM32_SCR_EN); return 0; } static int dma_stm32_stop(struct device *dev, u32_t id) { struct dma_stm32_device *ddata = dev->driver_data; struct dma_stm32_stream *stream = &ddata->stream[id]; u32_t scr, sfcr, irqstatus; int ret; /* Disable all IRQs */ scr = dma_stm32_read(ddata, DMA_STM32_SCR(id)); scr &= ~DMA_STM32_SCR_IRQ_MASK; dma_stm32_write(ddata, DMA_STM32_SCR(id), scr); sfcr = dma_stm32_read(ddata, DMA_STM32_SFCR(id)); sfcr &= ~DMA_STM32_SFCR_FEIE; dma_stm32_write(ddata, DMA_STM32_SFCR(id), sfcr); /* Disable stream */ ret = dma_stm32_disable_stream(ddata, id); if (ret) return ret; /* Clear remanent IRQs from previous transfers */ irqstatus = dma_stm32_irq_status(ddata, id); if (irqstatus) { dma_stm32_irq_clear(ddata, id, irqstatus); } /* Finally, flag stream as free */ stream->busy = false; return 0; } static int dma_stm32_init(struct device *dev) { struct dma_stm32_device *ddata = dev->driver_data; const struct dma_stm32_config *cdata = dev->config->config_info; int i; for (i = 0; i < DMA_STM32_MAX_STREAMS; i++) { ddata->stream[i].dev = dev; ddata->stream[i].busy = false; } /* Enable DMA clock */ ddata->clk = device_get_binding(STM32_CLOCK_CONTROL_NAME); __ASSERT_NO_MSG(ddata->clk); clock_control_on(ddata->clk, (clock_control_subsys_t *) &cdata->pclken); /* Set controller specific configuration */ cdata->config(ddata); return 0; } static const struct dma_driver_api dma_funcs = { .config = dma_stm32_config, .start = dma_stm32_start, .stop = dma_stm32_stop, }; const struct dma_stm32_config dma_stm32_1_cdata = { .pclken = { .bus = STM32_CLOCK_BUS_AHB1, .enr = LL_AHB1_GRP1_PERIPH_DMA1 }, .config = dma_stm32_1_config, }; DEVICE_AND_API_INIT(dma_stm32_1, CONFIG_DMA_1_NAME, &dma_stm32_init, &device_data[DMA_STM32_1], &dma_stm32_1_cdata, POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE, (void *)&dma_funcs); static const struct dma_stm32_config dma_stm32_2_cdata = { .pclken = { .bus = STM32_CLOCK_BUS_AHB1, .enr = LL_AHB1_GRP1_PERIPH_DMA2 }, .config = dma_stm32_2_config, }; DEVICE_AND_API_INIT(dma_stm32_2, CONFIG_DMA_2_NAME, &dma_stm32_init, &device_data[DMA_STM32_2], &dma_stm32_2_cdata, POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE, (void *)&dma_funcs); static void dma_stm32_irq_0(void *arg) { dma_stm32_irq_handler(arg, 0); } static void dma_stm32_irq_1(void *arg) { dma_stm32_irq_handler(arg, 1); } static void dma_stm32_irq_2(void *arg) { dma_stm32_irq_handler(arg, 2); } static void dma_stm32_irq_3(void *arg) { dma_stm32_irq_handler(arg, 3); } static void dma_stm32_irq_4(void *arg) { dma_stm32_irq_handler(arg, 4); } static void dma_stm32_irq_5(void *arg) { dma_stm32_irq_handler(arg, 5); } static void dma_stm32_irq_6(void *arg) { dma_stm32_irq_handler(arg, 6); } static void dma_stm32_irq_7(void *arg) { dma_stm32_irq_handler(arg, 7); } static void dma_stm32_1_config(struct dma_stm32_device *ddata) { ddata->base = DMA_STM32_1_BASE; ddata->channel_tx = DMA_STM32_1_TX_CHANNEL_ID; ddata->channel_rx = DMA_STM32_1_RX_CHANNEL_ID; IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM0, DMA_STM32_IRQ_PRI, dma_stm32_irq_0, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM0); IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM1, DMA_STM32_IRQ_PRI, dma_stm32_irq_1, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM1); IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM2, DMA_STM32_IRQ_PRI, dma_stm32_irq_2, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM2); IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM3, DMA_STM32_IRQ_PRI, dma_stm32_irq_3, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM3); IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM4, DMA_STM32_IRQ_PRI, dma_stm32_irq_4, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM4); IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM5, DMA_STM32_IRQ_PRI, dma_stm32_irq_5, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM5); IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM6, DMA_STM32_IRQ_PRI, dma_stm32_irq_6, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM6); IRQ_CONNECT(STM32F4_IRQ_DMA1_STREAM7, DMA_STM32_IRQ_PRI, dma_stm32_irq_7, DEVICE_GET(dma_stm32_1), 0); irq_enable(STM32F4_IRQ_DMA1_STREAM7); } static void dma_stm32_2_config(struct dma_stm32_device *ddata) { ddata->base = DMA_STM32_2_BASE; ddata->mem2mem = true; ddata->channel_tx = DMA_STM32_2_TX_CHANNEL_ID; ddata->channel_rx = DMA_STM32_2_RX_CHANNEL_ID; IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM0, DMA_STM32_IRQ_PRI, dma_stm32_irq_0, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM0); IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM1, DMA_STM32_IRQ_PRI, dma_stm32_irq_1, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM1); IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM2, DMA_STM32_IRQ_PRI, dma_stm32_irq_2, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM2); IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM3, DMA_STM32_IRQ_PRI, dma_stm32_irq_3, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM3); IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM4, DMA_STM32_IRQ_PRI, dma_stm32_irq_4, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM4); IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM5, DMA_STM32_IRQ_PRI, dma_stm32_irq_5, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM5); IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM6, DMA_STM32_IRQ_PRI, dma_stm32_irq_6, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM6); IRQ_CONNECT(STM32F4_IRQ_DMA2_STREAM7, DMA_STM32_IRQ_PRI, dma_stm32_irq_7, DEVICE_GET(dma_stm32_2), 0); irq_enable(STM32F4_IRQ_DMA2_STREAM7); }