/* * Copyright 2004-2012 Freescale Semiconductor, Inc. All Rights Reserved. */ /* * The code contained herein is licensed under the GNU General Public * License. You may obtain a copy of the GNU General Public License * Version 2 or later at the following locations: * * http://www.opensource.org/licenses/gpl-license.html * http://www.gnu.org/copyleft/gpl.html */ /*! * @file ipu_bg_overlay_sdc_bg.c * * @brief IPU Use case for PRP-VF back-ground * * @ingroup IPU */ #include #include #include #include #include "mxc_v4l2_capture.h" #include "ipu_prp_sw.h" static int csi_buffer_num; static u32 bpp, csi_mem_bufsize = 3; static u32 out_format; static struct ipu_soc *disp_ipu; static u32 offset; static void csi_buf_work_func(struct work_struct *work) { int err = 0; cam_data *cam = container_of(work, struct _cam_data, csi_work_struct); struct ipu_task task; memset(&task, 0, sizeof(task)); if (csi_buffer_num) task.input.paddr = cam->vf_bufs[0]; else task.input.paddr = cam->vf_bufs[1]; task.input.width = cam->crop_current.width; task.input.height = cam->crop_current.height; task.input.format = IPU_PIX_FMT_UYVY; task.output.paddr = offset; task.output.width = cam->overlay_fb->var.xres; task.output.height = cam->overlay_fb->var.yres; task.output.format = out_format; task.output.rotate = cam->rotation; task.output.crop.pos.x = cam->win.w.left; task.output.crop.pos.y = cam->win.w.top; if (cam->win.w.width > 1024 || cam->win.w.height > 1024) { task.output.crop.w = cam->overlay_fb->var.xres; task.output.crop.h = cam->overlay_fb->var.yres; } else { task.output.crop.w = cam->win.w.width; task.output.crop.h = cam->win.w.height; } again: err = ipu_check_task(&task); if (err != IPU_CHECK_OK) { if (err > IPU_CHECK_ERR_MIN) { if (err == IPU_CHECK_ERR_SPLIT_INPUTW_OVER) { task.input.crop.w -= 8; goto again; } if (err == IPU_CHECK_ERR_SPLIT_INPUTH_OVER) { task.input.crop.h -= 8; goto again; } if (err == IPU_CHECK_ERR_SPLIT_OUTPUTW_OVER) { task.output.width -= 8; task.output.crop.w = task.output.width; goto again; } if (err == IPU_CHECK_ERR_SPLIT_OUTPUTH_OVER) { task.output.height -= 8; task.output.crop.h = task.output.height; goto again; } printk(KERN_ERR "check ipu taks fail\n"); return; } printk(KERN_ERR "check ipu taks fail\n"); return; } err = ipu_queue_task(&task); if (err < 0) printk(KERN_ERR "queue ipu task error\n"); } static void get_disp_ipu(cam_data *cam) { if (cam->output > 2) disp_ipu = ipu_get_soc(1); /* using DISP4 */ else disp_ipu = ipu_get_soc(0); } /*! * csi ENC callback function. * * @param irq int irq line * @param dev_id void * device id * * @return status IRQ_HANDLED for handled */ static irqreturn_t csi_enc_callback(int irq, void *dev_id) { cam_data *cam = (cam_data *) dev_id; ipu_select_buffer(cam->ipu, CSI_MEM, IPU_OUTPUT_BUFFER, csi_buffer_num); schedule_work(&cam->csi_work_struct); csi_buffer_num = (csi_buffer_num == 0) ? 1 : 0; return IRQ_HANDLED; } static int csi_enc_setup(cam_data *cam) { ipu_channel_params_t params; u32 pixel_fmt; int err = 0, sensor_protocol = 0; #ifdef CONFIG_MXC_MIPI_CSI2 void *mipi_csi2_info; int ipu_id; int csi_id; #endif if (!cam) { printk(KERN_ERR "cam private is NULL\n"); return -ENXIO; } memset(¶ms, 0, sizeof(ipu_channel_params_t)); params.csi_mem.csi = cam->csi; sensor_protocol = ipu_csi_get_sensor_protocol(cam->ipu, cam->csi); switch (sensor_protocol) { case IPU_CSI_CLK_MODE_GATED_CLK: case IPU_CSI_CLK_MODE_NONGATED_CLK: case IPU_CSI_CLK_MODE_CCIR656_PROGRESSIVE: case IPU_CSI_CLK_MODE_CCIR1120_PROGRESSIVE_DDR: case IPU_CSI_CLK_MODE_CCIR1120_PROGRESSIVE_SDR: params.csi_mem.interlaced = false; break; case IPU_CSI_CLK_MODE_CCIR656_INTERLACED: case IPU_CSI_CLK_MODE_CCIR1120_INTERLACED_DDR: case IPU_CSI_CLK_MODE_CCIR1120_INTERLACED_SDR: params.csi_mem.interlaced = true; break; default: printk(KERN_ERR "sensor protocol unsupported\n"); return -EINVAL; } #ifdef CONFIG_MXC_MIPI_CSI2 mipi_csi2_info = mipi_csi2_get_info(); if (mipi_csi2_info) { if (mipi_csi2_get_status(mipi_csi2_info)) { ipu_id = mipi_csi2_get_bind_ipu(mipi_csi2_info); csi_id = mipi_csi2_get_bind_csi(mipi_csi2_info); if (cam->ipu == ipu_get_soc(ipu_id) && cam->csi == csi_id) { params.csi_mem.mipi_en = true; params.csi_mem.mipi_vc = mipi_csi2_get_virtual_channel(mipi_csi2_info); params.csi_mem.mipi_id = mipi_csi2_get_datatype(mipi_csi2_info); mipi_csi2_pixelclk_enable(mipi_csi2_info); } else { params.csi_mem.mipi_en = false; params.csi_mem.mipi_vc = 0; params.csi_mem.mipi_id = 0; } } else { params.csi_mem.mipi_en = false; params.csi_mem.mipi_vc = 0; params.csi_mem.mipi_id = 0; } } else { printk(KERN_ERR "Fail to get mipi_csi2_info!\n"); return -EPERM; } #endif if (cam->vf_bufs_vaddr[0]) { dma_free_coherent(0, cam->vf_bufs_size[0], cam->vf_bufs_vaddr[0], (dma_addr_t) cam->vf_bufs[0]); } if (cam->vf_bufs_vaddr[1]) { dma_free_coherent(0, cam->vf_bufs_size[1], cam->vf_bufs_vaddr[1], (dma_addr_t) cam->vf_bufs[1]); } csi_mem_bufsize = cam->crop_current.width * cam->crop_current.height * 2; cam->vf_bufs_size[0] = PAGE_ALIGN(csi_mem_bufsize); cam->vf_bufs_vaddr[0] = (void *)dma_alloc_coherent(0, cam->vf_bufs_size[0], (dma_addr_t *) & cam->vf_bufs[0], GFP_DMA | GFP_KERNEL); if (cam->vf_bufs_vaddr[0] == NULL) { printk(KERN_ERR "Error to allocate vf buffer\n"); err = -ENOMEM; goto out_2; } cam->vf_bufs_size[1] = PAGE_ALIGN(csi_mem_bufsize); cam->vf_bufs_vaddr[1] = (void *)dma_alloc_coherent(0, cam->vf_bufs_size[1], (dma_addr_t *) & cam->vf_bufs[1], GFP_DMA | GFP_KERNEL); if (cam->vf_bufs_vaddr[1] == NULL) { printk(KERN_ERR "Error to allocate vf buffer\n"); err = -ENOMEM; goto out_1; } pr_debug("vf_bufs %x %x\n", cam->vf_bufs[0], cam->vf_bufs[1]); err = ipu_init_channel(cam->ipu, CSI_MEM, ¶ms); if (err != 0) { printk(KERN_ERR "ipu_init_channel %d\n", err); goto out_1; } pixel_fmt = IPU_PIX_FMT_UYVY; err = ipu_init_channel_buffer(cam->ipu, CSI_MEM, IPU_OUTPUT_BUFFER, pixel_fmt, cam->crop_current.width, cam->crop_current.height, cam->crop_current.width, IPU_ROTATE_NONE, cam->vf_bufs[0], cam->vf_bufs[1], 0, cam->offset.u_offset, cam->offset.u_offset); if (err != 0) { printk(KERN_ERR "CSI_MEM output buffer\n"); goto out_1; } err = ipu_enable_channel(cam->ipu, CSI_MEM); if (err < 0) { printk(KERN_ERR "ipu_enable_channel CSI_MEM\n"); goto out_1; } csi_buffer_num = 0; ipu_select_buffer(cam->ipu, CSI_MEM, IPU_OUTPUT_BUFFER, 0); ipu_select_buffer(cam->ipu, CSI_MEM, IPU_OUTPUT_BUFFER, 1); return err; out_1: if (cam->vf_bufs_vaddr[0]) { dma_free_coherent(0, cam->vf_bufs_size[0], cam->vf_bufs_vaddr[0], (dma_addr_t) cam->vf_bufs[0]); cam->vf_bufs_vaddr[0] = NULL; cam->vf_bufs[0] = 0; } if (cam->vf_bufs_vaddr[1]) { dma_free_coherent(0, cam->vf_bufs_size[1], cam->vf_bufs_vaddr[1], (dma_addr_t) cam->vf_bufs[1]); cam->vf_bufs_vaddr[1] = NULL; cam->vf_bufs[1] = 0; } out_2: return err; } /*! * Enable encoder task * @param private struct cam_data * mxc capture instance * * @return status */ static int csi_enc_enabling_tasks(void *private) { cam_data *cam = (cam_data *) private; int err = 0; ipu_clear_irq(cam->ipu, IPU_IRQ_CSI0_OUT_EOF); err = ipu_request_irq(cam->ipu, IPU_IRQ_CSI0_OUT_EOF, csi_enc_callback, 0, "Mxc Camera", cam); if (err != 0) { printk(KERN_ERR "Error registering CSI0_OUT_EOF irq\n"); return err; } INIT_WORK(&cam->csi_work_struct, csi_buf_work_func); err = csi_enc_setup(cam); if (err != 0) { printk(KERN_ERR "csi_enc_setup %d\n", err); goto out1; } return err; out1: ipu_free_irq(cam->ipu, IPU_IRQ_CSI0_OUT_EOF, cam); return err; } /*! * bg_overlay_start - start the overlay task * * @param private cam_data * mxc v4l2 main structure * */ static int bg_overlay_start(void *private) { cam_data *cam = (cam_data *) private; int err = 0; if (!cam) { printk(KERN_ERR "private is NULL\n"); return -EIO; } if (cam->overlay_active == true) { pr_debug("already start.\n"); return 0; } get_disp_ipu(cam); out_format = cam->v4l2_fb.fmt.pixelformat; if (cam->v4l2_fb.fmt.pixelformat == IPU_PIX_FMT_BGR24) { bpp = 3, csi_mem_bufsize = 3; pr_info("BGR24\n"); } else if (cam->v4l2_fb.fmt.pixelformat == IPU_PIX_FMT_RGB565) { bpp = 2, csi_mem_bufsize = 2; pr_info("RGB565\n"); } else if (cam->v4l2_fb.fmt.pixelformat == IPU_PIX_FMT_BGR32) { bpp = 4, csi_mem_bufsize = 4; pr_info("BGR32\n"); } else { printk(KERN_ERR "unsupported fix format from the framebuffer.\n"); return -EINVAL; } offset = cam->v4l2_fb.fmt.bytesperline * cam->win.w.top + csi_mem_bufsize * cam->win.w.left; if (cam->v4l2_fb.base == 0) { printk(KERN_ERR "invalid frame buffer address.\n"); } else { offset += (u32) cam->v4l2_fb.base; } csi_mem_bufsize = cam->win.w.width * cam->win.w.height * csi_mem_bufsize; err = csi_enc_enabling_tasks(cam); if (err != 0) { printk(KERN_ERR "Error csi enc enable fail\n"); return err; } cam->overlay_active = true; return err; } /*! * bg_overlay_stop - stop the overlay task * * @param private cam_data * mxc v4l2 main structure * */ static int bg_overlay_stop(void *private) { int err = 0; cam_data *cam = (cam_data *) private; #ifdef CONFIG_MXC_MIPI_CSI2 void *mipi_csi2_info; int ipu_id; int csi_id; #endif if (cam->overlay_active == false) return 0; err = ipu_disable_channel(cam->ipu, CSI_MEM, true); ipu_uninit_channel(cam->ipu, CSI_MEM); csi_buffer_num = 0; #ifdef CONFIG_MXC_MIPI_CSI2 mipi_csi2_info = mipi_csi2_get_info(); if (mipi_csi2_info) { if (mipi_csi2_get_status(mipi_csi2_info)) { ipu_id = mipi_csi2_get_bind_ipu(mipi_csi2_info); csi_id = mipi_csi2_get_bind_csi(mipi_csi2_info); if (cam->ipu == ipu_get_soc(ipu_id) && cam->csi == csi_id) mipi_csi2_pixelclk_disable(mipi_csi2_info); } } else { printk(KERN_ERR "Fail to get mipi_csi2_info!\n"); return -EPERM; } #endif flush_work_sync(&cam->csi_work_struct); cancel_work_sync(&cam->csi_work_struct); if (cam->vf_bufs_vaddr[0]) { dma_free_coherent(0, cam->vf_bufs_size[0], cam->vf_bufs_vaddr[0], cam->vf_bufs[0]); cam->vf_bufs_vaddr[0] = NULL; cam->vf_bufs[0] = 0; } if (cam->vf_bufs_vaddr[1]) { dma_free_coherent(0, cam->vf_bufs_size[1], cam->vf_bufs_vaddr[1], cam->vf_bufs[1]); cam->vf_bufs_vaddr[1] = NULL; cam->vf_bufs[1] = 0; } if (cam->rot_vf_bufs_vaddr[0]) { dma_free_coherent(0, cam->rot_vf_buf_size[0], cam->rot_vf_bufs_vaddr[0], cam->rot_vf_bufs[0]); cam->rot_vf_bufs_vaddr[0] = NULL; cam->rot_vf_bufs[0] = 0; } if (cam->rot_vf_bufs_vaddr[1]) { dma_free_coherent(0, cam->rot_vf_buf_size[1], cam->rot_vf_bufs_vaddr[1], cam->rot_vf_bufs[1]); cam->rot_vf_bufs_vaddr[1] = NULL; cam->rot_vf_bufs[1] = 0; } cam->overlay_active = false; return err; } /*! * Enable csi * @param private struct cam_data * mxc capture instance * * @return status */ static int bg_overlay_enable_csi(void *private) { cam_data *cam = (cam_data *) private; return ipu_enable_csi(cam->ipu, cam->csi); } /*! * Disable csi * @param private struct cam_data * mxc capture instance * * @return status */ static int bg_overlay_disable_csi(void *private) { cam_data *cam = (cam_data *) private; /* free csi eof irq firstly. * when disable csi, wait for idmac eof. * it requests eof irq again */ ipu_free_irq(cam->ipu, IPU_IRQ_CSI0_OUT_EOF, cam); return ipu_disable_csi(cam->ipu, cam->csi); } /*! * function to select bg as the working path * * @param private cam_data * mxc v4l2 main structure * * @return status */ int bg_overlay_sdc_select(void *private) { cam_data *cam = (cam_data *) private; if (cam) { cam->vf_start_sdc = bg_overlay_start; cam->vf_stop_sdc = bg_overlay_stop; cam->vf_enable_csi = bg_overlay_enable_csi; cam->vf_disable_csi = bg_overlay_disable_csi; cam->overlay_active = false; } return 0; } /*! * function to de-select bg as the working path * * @param private cam_data * mxc v4l2 main structure * * @return status */ int bg_overlay_sdc_deselect(void *private) { cam_data *cam = (cam_data *) private; if (cam) { cam->vf_start_sdc = NULL; cam->vf_stop_sdc = NULL; cam->vf_enable_csi = NULL; cam->vf_disable_csi = NULL; } return 0; } /*! * Init background overlay task. * * @return Error code indicating success or failure */ __init int bg_overlay_sdc_init(void) { return 0; } /*! * Deinit background overlay task. * * @return Error code indicating success or failure */ void __exit bg_overlay_sdc_exit(void) { } module_init(bg_overlay_sdc_init); module_exit(bg_overlay_sdc_exit); EXPORT_SYMBOL(bg_overlay_sdc_select); EXPORT_SYMBOL(bg_overlay_sdc_deselect); MODULE_AUTHOR("Freescale Semiconductor, Inc."); MODULE_DESCRIPTION("IPU PRP VF SDC Backgroud Driver"); MODULE_LICENSE("GPL");