diff options
Diffstat (limited to 'drivers/staging/media/atomisp/pci/hive_isp_css_common/host/input_system.c')
-rw-r--r-- | drivers/staging/media/atomisp/pci/hive_isp_css_common/host/input_system.c | 1849 |
1 files changed, 1849 insertions, 0 deletions
diff --git a/drivers/staging/media/atomisp/pci/hive_isp_css_common/host/input_system.c b/drivers/staging/media/atomisp/pci/hive_isp_css_common/host/input_system.c new file mode 100644 index 000000000000..2114cf4f3fda --- /dev/null +++ b/drivers/staging/media/atomisp/pci/hive_isp_css_common/host/input_system.c @@ -0,0 +1,1849 @@ +/* + * Support for Intel Camera Imaging ISP subsystem. + * Copyright (c) 2010-015, Intel Corporation. + * + * This program is free software; you can redistribute it and/or modify it + * under the terms and conditions of the GNU General Public License, + * version 2, as published by the Free Software Foundation. + * + * This program is distributed in the hope 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. + */ + +#include "system_global.h" + +#ifdef USE_INPUT_SYSTEM_VERSION_2 + +#include "input_system.h" +#include <type_support.h> +#include "gp_device.h" + +#include "assert_support.h" + +#ifndef __INLINE_INPUT_SYSTEM__ +#include "input_system_private.h" +#endif /* __INLINE_INPUT_SYSTEM__ */ + +#define ZERO (0x0) +#define ONE (1U) + +static const ib_buffer_t IB_BUFFER_NULL = {0, 0, 0 }; + +static input_system_error_t input_system_configure_channel( + const channel_cfg_t channel); + +static input_system_error_t input_system_configure_channel_sensor( + const channel_cfg_t channel); + +static input_system_error_t input_buffer_configuration(void); + +static input_system_error_t configuration_to_registers(void); + +static void receiver_rst(const rx_ID_t ID); +static void input_system_network_rst(const input_system_ID_t ID); + +static void capture_unit_configure( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + const ib_buffer_t *const cfg); + +static void acquisition_unit_configure( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + const ib_buffer_t *const cfg); + +static void ctrl_unit_configure( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + const ctrl_unit_cfg_t *const cfg); + +static void input_system_network_configure( + const input_system_ID_t ID, + const input_system_network_cfg_t *const cfg); + +// MW: CSI is previously named as "rx" short for "receiver" +static input_system_error_t set_csi_cfg( + csi_cfg_t *const lhs, + const csi_cfg_t *const rhs, + input_system_config_flags_t *const flags); + +static input_system_error_t set_source_type( + input_system_source_t *const lhs, + const input_system_source_t rhs, + input_system_config_flags_t *const flags); + +static input_system_error_t input_system_multiplexer_cfg( + input_system_multiplex_t *const lhs, + const input_system_multiplex_t rhs, + input_system_config_flags_t *const flags); + +static inline void capture_unit_get_state( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + capture_unit_state_t *state); + +static inline void acquisition_unit_get_state( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + acquisition_unit_state_t *state); + +static inline void ctrl_unit_get_state( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + ctrl_unit_state_t *state); + +static inline void mipi_port_get_state( + const rx_ID_t ID, + const enum mipi_port_id port_ID, + mipi_port_state_t *state); + +static inline void rx_channel_get_state( + const rx_ID_t ID, + const unsigned int ch_id, + rx_channel_state_t *state); + +static void gp_device_rst(const gp_device_ID_t ID); + +static void input_selector_cfg_for_sensor(const gp_device_ID_t ID); + +static void input_switch_rst(const gp_device_ID_t ID); + +static void input_switch_cfg( + const gp_device_ID_t ID, + const input_switch_cfg_t *const cfg +); + +void input_system_get_state( + const input_system_ID_t ID, + input_system_state_t *state) +{ + sub_system_ID_t sub_id; + + assert(ID < N_INPUT_SYSTEM_ID); + assert(state); + + state->str_multicastA_sel = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_A_IDX); + state->str_multicastB_sel = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_B_IDX); + state->str_multicastC_sel = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_C_IDX); + state->str_mux_sel = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MUX_IDX); + state->str_mon_status = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_STRMON_STAT_IDX); + state->str_mon_irq_cond = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_STRMON_COND_IDX); + state->str_mon_irq_en = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_STRMON_IRQ_EN_IDX); + state->isys_srst = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_SRST_IDX); + state->isys_slv_reg_srst = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_SLV_REG_SRST_IDX); + state->str_deint_portA_cnt = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_REG_PORT_A_IDX); + state->str_deint_portB_cnt = input_system_sub_system_reg_load(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_REG_PORT_B_IDX); + + for (sub_id = CAPTURE_UNIT0_ID; sub_id < CAPTURE_UNIT0_ID + N_CAPTURE_UNIT_ID; + sub_id++) { + capture_unit_get_state(ID, sub_id, + &state->capture_unit[sub_id - CAPTURE_UNIT0_ID]); + } + for (sub_id = ACQUISITION_UNIT0_ID; + sub_id < ACQUISITION_UNIT0_ID + N_ACQUISITION_UNIT_ID; sub_id++) { + acquisition_unit_get_state(ID, sub_id, + &state->acquisition_unit[sub_id - ACQUISITION_UNIT0_ID]); + } + for (sub_id = CTRL_UNIT0_ID; sub_id < CTRL_UNIT0_ID + N_CTRL_UNIT_ID; + sub_id++) { + ctrl_unit_get_state(ID, sub_id, + &state->ctrl_unit_state[sub_id - CTRL_UNIT0_ID]); + } + + return; +} + +void receiver_get_state( + const rx_ID_t ID, + receiver_state_t *state) +{ + enum mipi_port_id port_id; + unsigned int ch_id; + + assert(ID < N_RX_ID); + assert(state); + + state->fs_to_ls_delay = (uint8_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_FS_TO_LS_DELAY_REG_IDX); + state->ls_to_data_delay = (uint8_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_LS_TO_DATA_DELAY_REG_IDX); + state->data_to_le_delay = (uint8_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_DATA_TO_LE_DELAY_REG_IDX); + state->le_to_fe_delay = (uint8_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_LE_TO_FE_DELAY_REG_IDX); + state->fe_to_fs_delay = (uint8_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_FE_TO_FS_DELAY_REG_IDX); + state->le_to_fs_delay = (uint8_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_LE_TO_LS_DELAY_REG_IDX); + state->is_two_ppc = (bool)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_TWO_PIXEL_EN_REG_IDX); + state->backend_rst = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BACKEND_RST_REG_IDX); + state->raw18 = (uint16_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_RAW18_REG_IDX); + state->force_raw8 = (bool)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_FORCE_RAW8_REG_IDX); + state->raw16 = (uint16_t)receiver_reg_load(ID, + _HRT_CSS_RECEIVER_RAW16_REG_IDX); + + for (port_id = (enum mipi_port_id)0; port_id < N_MIPI_PORT_ID; port_id++) { + mipi_port_get_state(ID, port_id, + &state->mipi_port_state[port_id]); + } + for (ch_id = 0U; ch_id < N_RX_CHANNEL_ID; ch_id++) { + rx_channel_get_state(ID, ch_id, + &state->rx_channel_state[ch_id]); + } + + state->be_gsp_acc_ovl = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_GSP_ACC_OVL_REG_IDX); + state->be_srst = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_SRST_REG_IDX); + state->be_is_two_ppc = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_TWO_PPC_REG_IDX); + state->be_comp_format0 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_COMP_FORMAT_REG0_IDX); + state->be_comp_format1 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_COMP_FORMAT_REG1_IDX); + state->be_comp_format2 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_COMP_FORMAT_REG2_IDX); + state->be_comp_format3 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_COMP_FORMAT_REG3_IDX); + state->be_sel = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_SEL_REG_IDX); + state->be_raw16_config = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_RAW16_CONFIG_REG_IDX); + state->be_raw18_config = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_RAW18_CONFIG_REG_IDX); + state->be_force_raw8 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_FORCE_RAW8_REG_IDX); + state->be_irq_status = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_IRQ_STATUS_REG_IDX); + state->be_irq_clear = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_BE_IRQ_CLEAR_REG_IDX); + + return; +} + +bool is_mipi_format_yuv420( + const mipi_format_t mipi_format) +{ + bool is_yuv420 = ( + (mipi_format == MIPI_FORMAT_YUV420_8) || + (mipi_format == MIPI_FORMAT_YUV420_10) || + (mipi_format == MIPI_FORMAT_YUV420_8_SHIFT) || + (mipi_format == MIPI_FORMAT_YUV420_10_SHIFT)); + /* MIPI_FORMAT_YUV420_8_LEGACY is not YUV420 */ + + return is_yuv420; +} + +void receiver_set_compression( + const rx_ID_t ID, + const unsigned int cfg_ID, + const mipi_compressor_t comp, + const mipi_predictor_t pred) +{ + const unsigned int field_id = cfg_ID % N_MIPI_FORMAT_CUSTOM; + const unsigned int ch_id = cfg_ID / N_MIPI_FORMAT_CUSTOM; + hrt_data val; + hrt_address addr = 0; + hrt_data reg; + + assert(ID < N_RX_ID); + assert(cfg_ID < N_MIPI_COMPRESSOR_CONTEXT); + assert(field_id < N_MIPI_FORMAT_CUSTOM); + assert(ch_id < N_RX_CHANNEL_ID); + assert(comp < N_MIPI_COMPRESSOR_METHODS); + assert(pred < N_MIPI_PREDICTOR_TYPES); + + val = (((uint8_t)pred) << 3) | comp; + + switch (ch_id) { + case 0: + addr = ((field_id < 6) ? _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC0_REG0_IDX : + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC0_REG1_IDX); + break; + case 1: + addr = ((field_id < 6) ? _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC1_REG0_IDX : + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC1_REG1_IDX); + break; + case 2: + addr = ((field_id < 6) ? _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC2_REG0_IDX : + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC2_REG1_IDX); + break; + case 3: + addr = ((field_id < 6) ? _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC3_REG0_IDX : + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC3_REG1_IDX); + break; + default: + /* should not happen */ + assert(false); + return; + } + + reg = ((field_id < 6) ? (val << (field_id * 5)) : (val << (( + field_id - 6) * 5))); + receiver_reg_store(ID, addr, reg); + + return; +} + +void receiver_port_enable( + const rx_ID_t ID, + const enum mipi_port_id port_ID, + const bool cnd) +{ + hrt_data reg = receiver_port_reg_load(ID, port_ID, + _HRT_CSS_RECEIVER_DEVICE_READY_REG_IDX); + + if (cnd) { + reg |= 0x01; + } else { + reg &= ~0x01; + } + + receiver_port_reg_store(ID, port_ID, + _HRT_CSS_RECEIVER_DEVICE_READY_REG_IDX, reg); + return; +} + +bool is_receiver_port_enabled( + const rx_ID_t ID, + const enum mipi_port_id port_ID) +{ + hrt_data reg = receiver_port_reg_load(ID, port_ID, + _HRT_CSS_RECEIVER_DEVICE_READY_REG_IDX); + return ((reg & 0x01) != 0); +} + +void receiver_irq_enable( + const rx_ID_t ID, + const enum mipi_port_id port_ID, + const rx_irq_info_t irq_info) +{ + receiver_port_reg_store(ID, + port_ID, _HRT_CSS_RECEIVER_IRQ_ENABLE_REG_IDX, irq_info); + return; +} + +rx_irq_info_t receiver_get_irq_info( + const rx_ID_t ID, + const enum mipi_port_id port_ID) +{ + return receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_IRQ_STATUS_REG_IDX); +} + +void receiver_irq_clear( + const rx_ID_t ID, + const enum mipi_port_id port_ID, + const rx_irq_info_t irq_info) +{ + receiver_port_reg_store(ID, + port_ID, _HRT_CSS_RECEIVER_IRQ_STATUS_REG_IDX, irq_info); + return; +} + +static inline void capture_unit_get_state( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + capture_unit_state_t *state) +{ + assert(/*(sub_id >= CAPTURE_UNIT0_ID) &&*/ (sub_id <= CAPTURE_UNIT2_ID)); + assert(state); + + state->StartMode = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_START_MODE_REG_ID); + state->Start_Addr = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_START_ADDR_REG_ID); + state->Mem_Region_Size = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_MEM_REGION_SIZE_REG_ID); + state->Num_Mem_Regions = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_NUM_MEM_REGIONS_REG_ID); +// AM: Illegal read from following registers. + /* state->Init = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_INIT_REG_ID); + state->Start = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_START_REG_ID); + state->Stop = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_STOP_REG_ID); + */ + state->Packet_Length = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_PACKET_LENGTH_REG_ID); + state->Received_Length = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_RECEIVED_LENGTH_REG_ID); + state->Received_Short_Packets = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_RECEIVED_SHORT_PACKETS_REG_ID); + state->Received_Long_Packets = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_RECEIVED_LONG_PACKETS_REG_ID); + state->Last_Command = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_LAST_COMMAND_REG_ID); + state->Next_Command = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_NEXT_COMMAND_REG_ID); + state->Last_Acknowledge = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_LAST_ACKNOWLEDGE_REG_ID); + state->Next_Acknowledge = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_NEXT_ACKNOWLEDGE_REG_ID); + state->FSM_State_Info = input_system_sub_system_reg_load(ID, + sub_id, + CAPT_FSM_STATE_INFO_REG_ID); + + return; +} + +static inline void acquisition_unit_get_state( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + acquisition_unit_state_t *state) +{ + assert(sub_id == ACQUISITION_UNIT0_ID); + assert(state); + + state->Start_Addr = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_START_ADDR_REG_ID); + state->Mem_Region_Size = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_MEM_REGION_SIZE_REG_ID); + state->Num_Mem_Regions = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_NUM_MEM_REGIONS_REG_ID); +// AM: Illegal read from following registers. + /* state->Init = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_INIT_REG_ID); + */ + state->Received_Short_Packets = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_RECEIVED_SHORT_PACKETS_REG_ID); + state->Received_Long_Packets = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_RECEIVED_LONG_PACKETS_REG_ID); + state->Last_Command = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_LAST_COMMAND_REG_ID); + state->Next_Command = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_NEXT_COMMAND_REG_ID); + state->Last_Acknowledge = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_LAST_ACKNOWLEDGE_REG_ID); + state->Next_Acknowledge = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_NEXT_ACKNOWLEDGE_REG_ID); + state->FSM_State_Info = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_FSM_STATE_INFO_REG_ID); + state->Int_Cntr_Info = input_system_sub_system_reg_load(ID, + sub_id, + ACQ_INT_CNTR_INFO_REG_ID); + + return; +} + +static inline void ctrl_unit_get_state( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + ctrl_unit_state_t *state) +{ + assert(sub_id == CTRL_UNIT0_ID); + assert(state); + + state->captA_start_addr = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_START_ADDR_A_REG_ID); + state->captB_start_addr = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_START_ADDR_B_REG_ID); + state->captC_start_addr = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_START_ADDR_C_REG_ID); + state->captA_mem_region_size = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_MEM_REGION_SIZE_A_REG_ID); + state->captB_mem_region_size = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_MEM_REGION_SIZE_B_REG_ID); + state->captC_mem_region_size = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_MEM_REGION_SIZE_C_REG_ID); + state->captA_num_mem_regions = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_NUM_MEM_REGIONS_A_REG_ID); + state->captB_num_mem_regions = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_NUM_MEM_REGIONS_B_REG_ID); + state->captC_num_mem_regions = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_NUM_MEM_REGIONS_C_REG_ID); + state->acq_start_addr = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_ACQ_START_ADDR_REG_ID); + state->acq_mem_region_size = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_ACQ_MEM_REGION_SIZE_REG_ID); + state->acq_num_mem_regions = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_ACQ_NUM_MEM_REGIONS_REG_ID); +// AM: Illegal read from following registers. + /* state->ctrl_init = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_INIT_REG_ID); + */ + state->last_cmd = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_LAST_COMMAND_REG_ID); + state->next_cmd = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_NEXT_COMMAND_REG_ID); + state->last_ack = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_LAST_ACKNOWLEDGE_REG_ID); + state->next_ack = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_NEXT_ACKNOWLEDGE_REG_ID); + state->top_fsm_state = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_FSM_STATE_INFO_REG_ID); + state->captA_fsm_state = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_A_FSM_STATE_INFO_REG_ID); + state->captB_fsm_state = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_B_FSM_STATE_INFO_REG_ID); + state->captC_fsm_state = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_C_FSM_STATE_INFO_REG_ID); + state->acq_fsm_state = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_ACQ_FSM_STATE_INFO_REG_ID); + state->capt_reserve_one_mem_region = input_system_sub_system_reg_load(ID, + sub_id, + ISYS_CTRL_CAPT_RESERVE_ONE_MEM_REGION_REG_ID); + + return; +} + +static inline void mipi_port_get_state( + const rx_ID_t ID, + const enum mipi_port_id port_ID, + mipi_port_state_t *state) +{ + int i; + + assert(ID < N_RX_ID); + assert(port_ID < N_MIPI_PORT_ID); + assert(state); + + state->device_ready = receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_DEVICE_READY_REG_IDX); + state->irq_status = receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_IRQ_STATUS_REG_IDX); + state->irq_enable = receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_IRQ_ENABLE_REG_IDX); + state->timeout_count = receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_TIMEOUT_COUNT_REG_IDX); + state->init_count = (uint16_t)receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_INIT_COUNT_REG_IDX); + state->raw16_18 = (uint16_t)receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_RAW16_18_DATAID_REG_IDX); + state->sync_count = receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_SYNC_COUNT_REG_IDX); + state->rx_count = receiver_port_reg_load(ID, + port_ID, _HRT_CSS_RECEIVER_RX_COUNT_REG_IDX); + + for (i = 0; i < MIPI_4LANE_CFG ; i++) { + state->lane_sync_count[i] = (uint8_t)((state->sync_count) >> (i * 8)); + state->lane_rx_count[i] = (uint8_t)((state->rx_count) >> (i * 8)); + } + + return; +} + +static inline void rx_channel_get_state( + const rx_ID_t ID, + const unsigned int ch_id, + rx_channel_state_t *state) +{ + int i; + + assert(ID < N_RX_ID); + assert(ch_id < N_RX_CHANNEL_ID); + assert(state); + + switch (ch_id) { + case 0: + state->comp_scheme0 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC0_REG0_IDX); + state->comp_scheme1 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC0_REG1_IDX); + break; + case 1: + state->comp_scheme0 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC1_REG0_IDX); + state->comp_scheme1 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC1_REG1_IDX); + break; + case 2: + state->comp_scheme0 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC2_REG0_IDX); + state->comp_scheme1 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC2_REG1_IDX); + break; + case 3: + state->comp_scheme0 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC3_REG0_IDX); + state->comp_scheme1 = receiver_reg_load(ID, + _HRT_CSS_RECEIVER_2400_COMP_SCHEME_VC3_REG1_IDX); + break; + } + + /* See Table 7.1.17,..., 7.1.24 */ + for (i = 0; i < 6; i++) { + u8 val = (uint8_t)((state->comp_scheme0) >> (i * 5)) & 0x1f; + + state->comp[i] = (mipi_compressor_t)(val & 0x07); + state->pred[i] = (mipi_predictor_t)((val & 0x18) >> 3); + } + for (i = 6; i < N_MIPI_FORMAT_CUSTOM; i++) { + u8 val = (uint8_t)((state->comp_scheme0) >> ((i - 6) * 5)) & 0x1f; + + state->comp[i] = (mipi_compressor_t)(val & 0x07); + state->pred[i] = (mipi_predictor_t)((val & 0x18) >> 3); + } + + return; +} + +// MW: "2400" in the name is not good, but this is to avoid a naming conflict +static input_system_cfg2400_t config; + +static void receiver_rst( + const rx_ID_t ID) +{ + enum mipi_port_id port_id; + + assert(ID < N_RX_ID); + +// Disable all ports. + for (port_id = MIPI_PORT0_ID; port_id < N_MIPI_PORT_ID; port_id++) { + receiver_port_enable(ID, port_id, false); + } + + // AM: Additional actions for stopping receiver? + + return; +} + +//Single function to reset all the devices mapped via GP_DEVICE. +static void gp_device_rst(const gp_device_ID_t ID) +{ + assert(ID < N_GP_DEVICE_ID); + + gp_device_reg_store(ID, _REG_GP_SYNCGEN_ENABLE_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNCGEN_FREE_RUNNING_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNCGEN_PAUSE_ADDR, ONE); + // gp_device_reg_store(ID, _REG_GP_NR_FRAMES_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNGEN_NR_PIX_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNGEN_NR_PIX_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNGEN_NR_LINES_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNGEN_HBLANK_CYCLES_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNGEN_VBLANK_CYCLES_ADDR, ZERO); +// AM: Following calls cause strange warnings. Probably they should not be initialized. +// gp_device_reg_store(ID, _REG_GP_ISEL_SOF_ADDR, ZERO); +// gp_device_reg_store(ID, _REG_GP_ISEL_EOF_ADDR, ZERO); +// gp_device_reg_store(ID, _REG_GP_ISEL_SOL_ADDR, ZERO); +// gp_device_reg_store(ID, _REG_GP_ISEL_EOL_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_LFSR_ENABLE_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_LFSR_ENABLE_B_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_LFSR_RESET_VALUE_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_ENABLE_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_ENABLE_B_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_HOR_CNT_MASK_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_VER_CNT_MASK_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_XY_CNT_MASK_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_HOR_CNT_DELTA_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_VER_CNT_DELTA_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_MODE_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_RED1_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_GREEN1_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_BLUE1_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_RED2_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_GREEN2_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_TPG_BLUE2_ADDR, ZERO); + //gp_device_reg_store(ID, _REG_GP_ISEL_CH_ID_ADDR, ZERO); + //gp_device_reg_store(ID, _REG_GP_ISEL_FMT_TYPE_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_DATA_SEL_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_SBAND_SEL_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_SYNC_SEL_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNCGEN_HOR_CNT_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNCGEN_VER_CNT_ADDR, ZERO); + // gp_device_reg_store(ID, _REG_GP_SYNCGEN_FRAME_CNT_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_SOFT_RESET_ADDR, + ZERO); // AM: Maybe this soft reset is not safe. + + return; +} + +static void input_selector_cfg_for_sensor(const gp_device_ID_t ID) +{ + assert(ID < N_GP_DEVICE_ID); + + gp_device_reg_store(ID, _REG_GP_ISEL_SOF_ADDR, ONE); + gp_device_reg_store(ID, _REG_GP_ISEL_EOF_ADDR, ONE); + gp_device_reg_store(ID, _REG_GP_ISEL_SOL_ADDR, ONE); + gp_device_reg_store(ID, _REG_GP_ISEL_EOL_ADDR, ONE); + gp_device_reg_store(ID, _REG_GP_ISEL_CH_ID_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_FMT_TYPE_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_DATA_SEL_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_SBAND_SEL_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_ISEL_SYNC_SEL_ADDR, ZERO); + gp_device_reg_store(ID, _REG_GP_SOFT_RESET_ADDR, ZERO); + + return; +} + +static void input_switch_rst(const gp_device_ID_t ID) +{ + int addr; + + assert(ID < N_GP_DEVICE_ID); + + // Initialize the data&hsync LUT. + for (addr = _REG_GP_IFMT_input_switch_lut_reg0; + addr <= _REG_GP_IFMT_input_switch_lut_reg7; addr += SIZEOF_HRT_REG) { + gp_device_reg_store(ID, addr, ZERO); + } + + // Initialize the vsync LUT. + gp_device_reg_store(ID, + _REG_GP_IFMT_input_switch_fsync_lut, + ZERO); + + return; +} + +static void input_switch_cfg( + const gp_device_ID_t ID, + const input_switch_cfg_t *const cfg) +{ + int addr_offset; + + assert(ID < N_GP_DEVICE_ID); + assert(cfg); + + // Initialize the data&hsync LUT. + for (addr_offset = 0; addr_offset < N_RX_CHANNEL_ID * 2; addr_offset++) { + assert(addr_offset * SIZEOF_HRT_REG + _REG_GP_IFMT_input_switch_lut_reg0 <= + _REG_GP_IFMT_input_switch_lut_reg7); + gp_device_reg_store(ID, + _REG_GP_IFMT_input_switch_lut_reg0 + addr_offset * SIZEOF_HRT_REG, + cfg->hsync_data_reg[addr_offset]); + } + + // Initialize the vsync LUT. + gp_device_reg_store(ID, + _REG_GP_IFMT_input_switch_fsync_lut, + cfg->vsync_data_reg); + + return; +} + +static void input_system_network_rst(const input_system_ID_t ID) +{ + unsigned int sub_id; + + // Reset all 3 multicasts. + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_A_IDX, + INPUT_SYSTEM_DISCARD_ALL); + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_B_IDX, + INPUT_SYSTEM_DISCARD_ALL); + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_C_IDX, + INPUT_SYSTEM_DISCARD_ALL); + + // Reset stream mux. + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MUX_IDX, + N_INPUT_SYSTEM_MULTIPLEX); + + // Reset 3 capture units. + for (sub_id = CAPTURE_UNIT0_ID; sub_id < CAPTURE_UNIT0_ID + N_CAPTURE_UNIT_ID; + sub_id++) { + input_system_sub_system_reg_store(ID, + sub_id, + CAPT_INIT_REG_ID, + 1U << CAPT_INIT_RST_REG_BIT); + } + + // Reset acquisition unit. + for (sub_id = ACQUISITION_UNIT0_ID; + sub_id < ACQUISITION_UNIT0_ID + N_ACQUISITION_UNIT_ID; sub_id++) { + input_system_sub_system_reg_store(ID, + sub_id, + ACQ_INIT_REG_ID, + 1U << ACQ_INIT_RST_REG_BIT); + } + + // DMA unit reset is not needed. + + // Reset controller units. + // NB: In future we need to keep part of ctrl_state for split capture and + for (sub_id = CTRL_UNIT0_ID; sub_id < CTRL_UNIT0_ID + N_CTRL_UNIT_ID; + sub_id++) { + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_INIT_REG_ID, + 1U); //AM: Is there any named constant? + } + + return; +} + +// Function that resets current configuration. +input_system_error_t input_system_configuration_reset(void) +{ + unsigned int i; + + receiver_rst(RX0_ID); + + input_system_network_rst(INPUT_SYSTEM0_ID); + + gp_device_rst(INPUT_SYSTEM0_ID); + + input_switch_rst(INPUT_SYSTEM0_ID); + + //target_rst(); + + // Reset IRQ_CTRLs. + + // Reset configuration data structures. + for (i = 0; i < N_CHANNELS; i++) { + config.ch_flags[i] = INPUT_SYSTEM_CFG_FLAG_RESET; + config.target_isp_flags[i] = INPUT_SYSTEM_CFG_FLAG_RESET; + config.target_sp_flags[i] = INPUT_SYSTEM_CFG_FLAG_RESET; + config.target_strm2mem_flags[i] = INPUT_SYSTEM_CFG_FLAG_RESET; + } + + for (i = 0; i < N_CSI_PORTS; i++) { + config.csi_buffer_flags[i] = INPUT_SYSTEM_CFG_FLAG_RESET; + config.multicast[i] = INPUT_SYSTEM_CFG_FLAG_RESET; + } + + config.source_type_flags = INPUT_SYSTEM_CFG_FLAG_RESET; + config.acquisition_buffer_unique_flags = INPUT_SYSTEM_CFG_FLAG_RESET; + config.unallocated_ib_mem_words = IB_CAPACITY_IN_WORDS; + //config.acq_allocated_ib_mem_words = 0; + + // Set the start of the session cofiguration. + config.session_flags = INPUT_SYSTEM_CFG_FLAG_REQUIRED; + + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +// MW: Comments are good, but doxygen is required, place it at the declaration +// Function that appends the channel to current configuration. +static input_system_error_t input_system_configure_channel( + const channel_cfg_t channel) +{ + input_system_error_t error = INPUT_SYSTEM_ERR_NO_ERROR; + // Check if channel is not already configured. + if (config.ch_flags[channel.ch_id] & INPUT_SYSTEM_CFG_FLAG_SET) { + return INPUT_SYSTEM_ERR_CHANNEL_ALREADY_SET; + } else { + switch (channel.source_type) { + case INPUT_SYSTEM_SOURCE_SENSOR: + error = input_system_configure_channel_sensor(channel); + break; + case INPUT_SYSTEM_SOURCE_TPG: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + case INPUT_SYSTEM_SOURCE_PRBS: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + case INPUT_SYSTEM_SOURCE_FIFO: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + default: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + } + + if (error != INPUT_SYSTEM_ERR_NO_ERROR) return error; + // Input switch channel configurations must be combined in united config. + config.input_switch_cfg.hsync_data_reg[channel.source_cfg.csi_cfg.csi_port * 2] + = + channel.target_cfg.input_switch_channel_cfg.hsync_data_reg[0]; + config.input_switch_cfg.hsync_data_reg[channel.source_cfg.csi_cfg.csi_port * 2 + + 1] = + channel.target_cfg.input_switch_channel_cfg.hsync_data_reg[1]; + config.input_switch_cfg.vsync_data_reg |= + (channel.target_cfg.input_switch_channel_cfg.vsync_data_reg & 0x7) << + (channel.source_cfg.csi_cfg.csi_port * 3); + + // Other targets are just copied and marked as set. + config.target_isp[channel.source_cfg.csi_cfg.csi_port] = + channel.target_cfg.target_isp_cfg; + config.target_sp[channel.source_cfg.csi_cfg.csi_port] = + channel.target_cfg.target_sp_cfg; + config.target_strm2mem[channel.source_cfg.csi_cfg.csi_port] = + channel.target_cfg.target_strm2mem_cfg; + config.target_isp_flags[channel.source_cfg.csi_cfg.csi_port] |= + INPUT_SYSTEM_CFG_FLAG_SET; + config.target_sp_flags[channel.source_cfg.csi_cfg.csi_port] |= + INPUT_SYSTEM_CFG_FLAG_SET; + config.target_strm2mem_flags[channel.source_cfg.csi_cfg.csi_port] |= + INPUT_SYSTEM_CFG_FLAG_SET; + + config.ch_flags[channel.ch_id] = INPUT_SYSTEM_CFG_FLAG_SET; + } + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +// Function that partitions input buffer space with determining addresses. +static input_system_error_t input_buffer_configuration(void) +{ + u32 current_address = 0; + u32 unallocated_memory = IB_CAPACITY_IN_WORDS; + + ib_buffer_t candidate_buffer_acq = IB_BUFFER_NULL; + u32 size_requested; + input_system_config_flags_t acq_already_specified = INPUT_SYSTEM_CFG_FLAG_RESET; + input_system_csi_port_t port; + + for (port = INPUT_SYSTEM_PORT_A; port < N_INPUT_SYSTEM_PORTS; port++) { + csi_cfg_t source = config.csi_value[port];//.csi_cfg; + + if (config.csi_flags[port] & INPUT_SYSTEM_CFG_FLAG_SET) { + // Check and set csi buffer in input buffer. + switch (source.buffering_mode) { + case INPUT_SYSTEM_FIFO_CAPTURE: + case INPUT_SYSTEM_XMEM_ACQUIRE: + config.csi_buffer_flags[port] = + INPUT_SYSTEM_CFG_FLAG_BLOCKED; // Well, not used. + break; + + case INPUT_SYSTEM_FIFO_CAPTURE_WITH_COUNTING: + case INPUT_SYSTEM_SRAM_BUFFERING: + case INPUT_SYSTEM_XMEM_BUFFERING: + case INPUT_SYSTEM_XMEM_CAPTURE: + size_requested = source.csi_buffer.mem_reg_size * + source.csi_buffer.nof_mem_regs; + if (source.csi_buffer.mem_reg_size > 0 + && source.csi_buffer.nof_mem_regs > 0 + && size_requested <= unallocated_memory + ) { + config.csi_buffer[port].mem_reg_addr = current_address; + config.csi_buffer[port].mem_reg_size = source.csi_buffer.mem_reg_size; + config.csi_buffer[port].nof_mem_regs = source.csi_buffer.nof_mem_regs; + current_address += size_requested; + unallocated_memory -= size_requested; + config.csi_buffer_flags[port] = INPUT_SYSTEM_CFG_FLAG_SET; + } else { + config.csi_buffer_flags[port] |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + break; + + default: + config.csi_buffer_flags[port] |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + } + + // Check acquisition buffer specified but set it later since it has to be unique. + switch (source.buffering_mode) { + case INPUT_SYSTEM_FIFO_CAPTURE: + case INPUT_SYSTEM_SRAM_BUFFERING: + case INPUT_SYSTEM_XMEM_CAPTURE: + // Nothing to do. + break; + + case INPUT_SYSTEM_FIFO_CAPTURE_WITH_COUNTING: + case INPUT_SYSTEM_XMEM_BUFFERING: + case INPUT_SYSTEM_XMEM_ACQUIRE: + if (acq_already_specified == INPUT_SYSTEM_CFG_FLAG_RESET) { + size_requested = source.acquisition_buffer.mem_reg_size + * source.acquisition_buffer.nof_mem_regs; + if (source.acquisition_buffer.mem_reg_size > 0 + && source.acquisition_buffer.nof_mem_regs > 0 + && size_requested <= unallocated_memory + ) { + candidate_buffer_acq = source.acquisition_buffer; + acq_already_specified = INPUT_SYSTEM_CFG_FLAG_SET; + } + } else { + // Check if specified acquisition buffer is the same as specified before. + if (source.acquisition_buffer.mem_reg_size != candidate_buffer_acq.mem_reg_size + || source.acquisition_buffer.nof_mem_regs != candidate_buffer_acq.nof_mem_regs + ) { + config.acquisition_buffer_unique_flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + } + break; + + default: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + } + } else { + config.csi_buffer_flags[port] = INPUT_SYSTEM_CFG_FLAG_BLOCKED; + } + } // end of for ( port ) + + // Set the acquisition buffer at the end. + size_requested = candidate_buffer_acq.mem_reg_size * + candidate_buffer_acq.nof_mem_regs; + if (acq_already_specified == INPUT_SYSTEM_CFG_FLAG_SET + && size_requested <= unallocated_memory) { + config.acquisition_buffer_unique.mem_reg_addr = current_address; + config.acquisition_buffer_unique.mem_reg_size = + candidate_buffer_acq.mem_reg_size; + config.acquisition_buffer_unique.nof_mem_regs = + candidate_buffer_acq.nof_mem_regs; + current_address += size_requested; + unallocated_memory -= size_requested; + config.acquisition_buffer_unique_flags = INPUT_SYSTEM_CFG_FLAG_SET; + + assert(current_address <= IB_CAPACITY_IN_WORDS); + } + + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +static void capture_unit_configure( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + const ib_buffer_t *const cfg) +{ + assert(ID < N_INPUT_SYSTEM_ID); + assert(/*(sub_id >= CAPTURE_UNIT0_ID) &&*/ (sub_id <= + CAPTURE_UNIT2_ID)); // Commented part is always true. + assert(cfg); + + input_system_sub_system_reg_store(ID, + sub_id, + CAPT_START_ADDR_REG_ID, + cfg->mem_reg_addr); + input_system_sub_system_reg_store(ID, + sub_id, + CAPT_MEM_REGION_SIZE_REG_ID, + cfg->mem_reg_size); + input_system_sub_system_reg_store(ID, + sub_id, + CAPT_NUM_MEM_REGIONS_REG_ID, + cfg->nof_mem_regs); + + return; +} + +static void acquisition_unit_configure( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + const ib_buffer_t *const cfg) +{ + assert(ID < N_INPUT_SYSTEM_ID); + assert(sub_id == ACQUISITION_UNIT0_ID); + assert(cfg); + + input_system_sub_system_reg_store(ID, + sub_id, + ACQ_START_ADDR_REG_ID, + cfg->mem_reg_addr); + input_system_sub_system_reg_store(ID, + sub_id, + ACQ_NUM_MEM_REGIONS_REG_ID, + cfg->nof_mem_regs); + input_system_sub_system_reg_store(ID, + sub_id, + ACQ_MEM_REGION_SIZE_REG_ID, + cfg->mem_reg_size); + + return; +} + +static void ctrl_unit_configure( + const input_system_ID_t ID, + const sub_system_ID_t sub_id, + const ctrl_unit_cfg_t *const cfg) +{ + assert(ID < N_INPUT_SYSTEM_ID); + assert(sub_id == CTRL_UNIT0_ID); + assert(cfg); + + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_START_ADDR_A_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT0_ID].mem_reg_addr); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_MEM_REGION_SIZE_A_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT0_ID].mem_reg_size); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_NUM_MEM_REGIONS_A_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT0_ID].nof_mem_regs); + + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_START_ADDR_B_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT1_ID].mem_reg_addr); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_MEM_REGION_SIZE_B_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT1_ID].mem_reg_size); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_NUM_MEM_REGIONS_B_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT1_ID].nof_mem_regs); + + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_START_ADDR_C_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT2_ID].mem_reg_addr); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_MEM_REGION_SIZE_C_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT2_ID].mem_reg_size); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_NUM_MEM_REGIONS_C_REG_ID, + cfg->buffer_mipi[CAPTURE_UNIT2_ID].nof_mem_regs); + + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_ACQ_START_ADDR_REG_ID, + cfg->buffer_acquire[ACQUISITION_UNIT0_ID - ACQUISITION_UNIT0_ID].mem_reg_addr); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_ACQ_MEM_REGION_SIZE_REG_ID, + cfg->buffer_acquire[ACQUISITION_UNIT0_ID - ACQUISITION_UNIT0_ID].mem_reg_size); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_ACQ_NUM_MEM_REGIONS_REG_ID, + cfg->buffer_acquire[ACQUISITION_UNIT0_ID - ACQUISITION_UNIT0_ID].nof_mem_regs); + input_system_sub_system_reg_store(ID, + sub_id, + ISYS_CTRL_CAPT_RESERVE_ONE_MEM_REGION_REG_ID, + 0); + return; +} + +static void input_system_network_configure( + const input_system_ID_t ID, + const input_system_network_cfg_t *const cfg) +{ + u32 sub_id; + + assert(ID < N_INPUT_SYSTEM_ID); + assert(cfg); + + // Set all 3 multicasts. + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_A_IDX, + cfg->multicast_cfg[CAPTURE_UNIT0_ID]); + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_B_IDX, + cfg->multicast_cfg[CAPTURE_UNIT1_ID]); + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MULTICAST_C_IDX, + cfg->multicast_cfg[CAPTURE_UNIT2_ID]); + + // Set stream mux. + input_system_sub_system_reg_store(ID, + GPREGS_UNIT0_ID, + HIVE_ISYS_GPREG_MUX_IDX, + cfg->mux_cfg); + + // Set capture units. + for (sub_id = CAPTURE_UNIT0_ID; sub_id < CAPTURE_UNIT0_ID + N_CAPTURE_UNIT_ID; + sub_id++) { + capture_unit_configure(ID, + sub_id, + &cfg->ctrl_unit_cfg[ID].buffer_mipi[sub_id - CAPTURE_UNIT0_ID]); + } + + // Set acquisition units. + for (sub_id = ACQUISITION_UNIT0_ID; + sub_id < ACQUISITION_UNIT0_ID + N_ACQUISITION_UNIT_ID; sub_id++) { + acquisition_unit_configure(ID, + sub_id, + &cfg->ctrl_unit_cfg[sub_id - ACQUISITION_UNIT0_ID].buffer_acquire[sub_id - + ACQUISITION_UNIT0_ID]); + } + + // No DMA configuration needed. Ctrl_unit will fully control it. + + // Set controller units. + for (sub_id = CTRL_UNIT0_ID; sub_id < CTRL_UNIT0_ID + N_CTRL_UNIT_ID; + sub_id++) { + ctrl_unit_configure(ID, + sub_id, + &cfg->ctrl_unit_cfg[sub_id - CTRL_UNIT0_ID]); + } + + return; +} + +static input_system_error_t configuration_to_registers(void) +{ + input_system_network_cfg_t input_system_network_cfg; + int i; + + assert(config.source_type_flags & INPUT_SYSTEM_CFG_FLAG_SET); + + switch (config.source_type) { + case INPUT_SYSTEM_SOURCE_SENSOR: + + // Determine stream multicasts setting based on the mode of csi_cfg_t. + // AM: This should be moved towards earlier function call, e.g. in + // the commit function. + for (i = MIPI_PORT0_ID; i < N_MIPI_PORT_ID; i++) { + if (config.csi_flags[i] & INPUT_SYSTEM_CFG_FLAG_SET) { + switch (config.csi_value[i].buffering_mode) { + case INPUT_SYSTEM_FIFO_CAPTURE: + config.multicast[i] = INPUT_SYSTEM_CSI_BACKEND; + break; + + case INPUT_SYSTEM_XMEM_CAPTURE: + case INPUT_SYSTEM_SRAM_BUFFERING: + case INPUT_SYSTEM_XMEM_BUFFERING: + config.multicast[i] = INPUT_SYSTEM_INPUT_BUFFER; + break; + + case INPUT_SYSTEM_FIFO_CAPTURE_WITH_COUNTING: + config.multicast[i] = INPUT_SYSTEM_MULTICAST; + break; + + case INPUT_SYSTEM_XMEM_ACQUIRE: + config.multicast[i] = INPUT_SYSTEM_DISCARD_ALL; + break; + + default: + config.multicast[i] = INPUT_SYSTEM_DISCARD_ALL; + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + //break; + } + } else { + config.multicast[i] = INPUT_SYSTEM_DISCARD_ALL; + } + + input_system_network_cfg.multicast_cfg[i] = config.multicast[i]; + + } // for + + input_system_network_cfg.mux_cfg = config.multiplexer; + + input_system_network_cfg.ctrl_unit_cfg[CTRL_UNIT0_ID - + CTRL_UNIT0_ID].buffer_mipi[CAPTURE_UNIT0_ID] = + config.csi_buffer[MIPI_PORT0_ID]; + input_system_network_cfg.ctrl_unit_cfg[CTRL_UNIT0_ID - + CTRL_UNIT0_ID].buffer_mipi[CAPTURE_UNIT1_ID] = + config.csi_buffer[MIPI_PORT1_ID]; + input_system_network_cfg.ctrl_unit_cfg[CTRL_UNIT0_ID - + CTRL_UNIT0_ID].buffer_mipi[CAPTURE_UNIT2_ID] = + config.csi_buffer[MIPI_PORT2_ID]; + input_system_network_cfg.ctrl_unit_cfg[CTRL_UNIT0_ID - + CTRL_UNIT0_ID].buffer_acquire[ACQUISITION_UNIT0_ID - + ACQUISITION_UNIT0_ID] = + config.acquisition_buffer_unique; + + // First set input network around CSI receiver. + input_system_network_configure(INPUT_SYSTEM0_ID, &input_system_network_cfg); + + // Set the CSI receiver. + //... + break; + + case INPUT_SYSTEM_SOURCE_TPG: + + break; + + case INPUT_SYSTEM_SOURCE_PRBS: + + break; + + case INPUT_SYSTEM_SOURCE_FIFO: + break; + + default: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + + } // end of switch (source_type) + + // Set input selector. + input_selector_cfg_for_sensor(INPUT_SYSTEM0_ID); + + // Set input switch. + input_switch_cfg(INPUT_SYSTEM0_ID, &config.input_switch_cfg); + + // Set input formatters. + // AM: IF are set dynamically. + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +// Function that applies the whole configuration. +input_system_error_t input_system_configuration_commit(void) +{ + // The last configuration step is to configure the input buffer. + input_system_error_t error = input_buffer_configuration(); + + if (error != INPUT_SYSTEM_ERR_NO_ERROR) { + return error; + } + + // Translate the whole configuration into registers. + error = configuration_to_registers(); + if (error != INPUT_SYSTEM_ERR_NO_ERROR) { + return error; + } + + // Translate the whole configuration into ctrl commands etc. + + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +// FIFO + +input_system_error_t input_system_csi_fifo_channel_cfg( + u32 ch_id, + input_system_csi_port_t port, + backend_channel_cfg_t backend_ch, + target_cfg2400_t target +) +{ + channel_cfg_t channel; + + channel.ch_id = ch_id; + channel.backend_ch = backend_ch; + channel.source_type = INPUT_SYSTEM_SOURCE_SENSOR; + //channel.source + channel.source_cfg.csi_cfg.csi_port = port; + channel.source_cfg.csi_cfg.buffering_mode = INPUT_SYSTEM_FIFO_CAPTURE; + channel.source_cfg.csi_cfg.csi_buffer = IB_BUFFER_NULL; + channel.source_cfg.csi_cfg.acquisition_buffer = IB_BUFFER_NULL; + channel.source_cfg.csi_cfg.nof_xmem_buffers = 0; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +input_system_error_t input_system_csi_fifo_channel_with_counting_cfg( + u32 ch_id, + u32 nof_frames, + input_system_csi_port_t port, + backend_channel_cfg_t backend_ch, + u32 csi_mem_reg_size, + u32 csi_nof_mem_regs, + target_cfg2400_t target +) +{ + channel_cfg_t channel; + + channel.ch_id = ch_id; + channel.backend_ch = backend_ch; + channel.source_type = INPUT_SYSTEM_SOURCE_SENSOR; + //channel.source + channel.source_cfg.csi_cfg.csi_port = port; + channel.source_cfg.csi_cfg.buffering_mode = + INPUT_SYSTEM_FIFO_CAPTURE_WITH_COUNTING; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_size = csi_mem_reg_size; + channel.source_cfg.csi_cfg.csi_buffer.nof_mem_regs = csi_nof_mem_regs; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_addr = 0; + channel.source_cfg.csi_cfg.acquisition_buffer = IB_BUFFER_NULL; + channel.source_cfg.csi_cfg.nof_xmem_buffers = nof_frames; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +// SRAM + +input_system_error_t input_system_csi_sram_channel_cfg( + u32 ch_id, + input_system_csi_port_t port, + backend_channel_cfg_t backend_ch, + u32 csi_mem_reg_size, + u32 csi_nof_mem_regs, + // uint32_t acq_mem_reg_size, + // uint32_t acq_nof_mem_regs, + target_cfg2400_t target +) +{ + channel_cfg_t channel; + + channel.ch_id = ch_id; + channel.backend_ch = backend_ch; + channel.source_type = INPUT_SYSTEM_SOURCE_SENSOR; + //channel.source + channel.source_cfg.csi_cfg.csi_port = port; + channel.source_cfg.csi_cfg.buffering_mode = INPUT_SYSTEM_SRAM_BUFFERING; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_size = csi_mem_reg_size; + channel.source_cfg.csi_cfg.csi_buffer.nof_mem_regs = csi_nof_mem_regs; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_addr = 0; + channel.source_cfg.csi_cfg.acquisition_buffer = IB_BUFFER_NULL; + channel.source_cfg.csi_cfg.nof_xmem_buffers = 0; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +//XMEM + +// Collects all parameters and puts them in channel_cfg_t. +input_system_error_t input_system_csi_xmem_channel_cfg( + u32 ch_id, + input_system_csi_port_t port, + backend_channel_cfg_t backend_ch, + u32 csi_mem_reg_size, + u32 csi_nof_mem_regs, + u32 acq_mem_reg_size, + u32 acq_nof_mem_regs, + target_cfg2400_t target, + uint32_t nof_xmem_buffers +) +{ + channel_cfg_t channel; + + channel.ch_id = ch_id; + channel.backend_ch = backend_ch; + channel.source_type = INPUT_SYSTEM_SOURCE_SENSOR; + //channel.source + channel.source_cfg.csi_cfg.csi_port = port; + channel.source_cfg.csi_cfg.buffering_mode = INPUT_SYSTEM_XMEM_BUFFERING; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_size = csi_mem_reg_size; + channel.source_cfg.csi_cfg.csi_buffer.nof_mem_regs = csi_nof_mem_regs; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_addr = 0; + channel.source_cfg.csi_cfg.acquisition_buffer.mem_reg_size = acq_mem_reg_size; + channel.source_cfg.csi_cfg.acquisition_buffer.nof_mem_regs = acq_nof_mem_regs; + channel.source_cfg.csi_cfg.acquisition_buffer.mem_reg_addr = 0; + channel.source_cfg.csi_cfg.nof_xmem_buffers = nof_xmem_buffers; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +input_system_error_t input_system_csi_xmem_acquire_only_channel_cfg( + u32 ch_id, + u32 nof_frames, + input_system_csi_port_t port, + backend_channel_cfg_t backend_ch, + u32 acq_mem_reg_size, + u32 acq_nof_mem_regs, + target_cfg2400_t target) +{ + channel_cfg_t channel; + + channel.ch_id = ch_id; + channel.backend_ch = backend_ch; + channel.source_type = INPUT_SYSTEM_SOURCE_SENSOR; + //channel.source + channel.source_cfg.csi_cfg.csi_port = port; + channel.source_cfg.csi_cfg.buffering_mode = INPUT_SYSTEM_XMEM_ACQUIRE; + channel.source_cfg.csi_cfg.csi_buffer = IB_BUFFER_NULL; + channel.source_cfg.csi_cfg.acquisition_buffer.mem_reg_size = acq_mem_reg_size; + channel.source_cfg.csi_cfg.acquisition_buffer.nof_mem_regs = acq_nof_mem_regs; + channel.source_cfg.csi_cfg.acquisition_buffer.mem_reg_addr = 0; + channel.source_cfg.csi_cfg.nof_xmem_buffers = nof_frames; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +input_system_error_t input_system_csi_xmem_capture_only_channel_cfg( + u32 ch_id, + u32 nof_frames, + input_system_csi_port_t port, + u32 csi_mem_reg_size, + u32 csi_nof_mem_regs, + u32 acq_mem_reg_size, + u32 acq_nof_mem_regs, + target_cfg2400_t target) +{ + channel_cfg_t channel; + + channel.ch_id = ch_id; + //channel.backend_ch = backend_ch; + channel.source_type = INPUT_SYSTEM_SOURCE_SENSOR; + //channel.source + channel.source_cfg.csi_cfg.csi_port = port; + //channel.source_cfg.csi_cfg.backend_ch = backend_ch; + channel.source_cfg.csi_cfg.buffering_mode = INPUT_SYSTEM_XMEM_CAPTURE; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_size = csi_mem_reg_size; + channel.source_cfg.csi_cfg.csi_buffer.nof_mem_regs = csi_nof_mem_regs; + channel.source_cfg.csi_cfg.csi_buffer.mem_reg_addr = 0; + channel.source_cfg.csi_cfg.acquisition_buffer.mem_reg_size = acq_mem_reg_size; + channel.source_cfg.csi_cfg.acquisition_buffer.nof_mem_regs = acq_nof_mem_regs; + channel.source_cfg.csi_cfg.acquisition_buffer.mem_reg_addr = 0; + channel.source_cfg.csi_cfg.nof_xmem_buffers = nof_frames; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +// Non - CSI + +input_system_error_t input_system_prbs_channel_cfg( + u32 ch_id, + u32 nof_frames,//not used yet + u32 seed, + u32 sync_gen_width, + u32 sync_gen_height, + u32 sync_gen_hblank_cycles, + u32 sync_gen_vblank_cycles, + target_cfg2400_t target +) +{ + channel_cfg_t channel; + + (void)nof_frames; + + channel.ch_id = ch_id; + channel.source_type = INPUT_SYSTEM_SOURCE_PRBS; + + channel.source_cfg.prbs_cfg.seed = seed; + channel.source_cfg.prbs_cfg.sync_gen_cfg.width = sync_gen_width; + channel.source_cfg.prbs_cfg.sync_gen_cfg.height = sync_gen_height; + channel.source_cfg.prbs_cfg.sync_gen_cfg.hblank_cycles = sync_gen_hblank_cycles; + channel.source_cfg.prbs_cfg.sync_gen_cfg.vblank_cycles = sync_gen_vblank_cycles; + + channel.target_cfg = target; + + return input_system_configure_channel(channel); +} + +input_system_error_t input_system_tpg_channel_cfg( + u32 ch_id, + u32 nof_frames,//not used yet + u32 x_mask, + u32 y_mask, + u32 x_delta, + u32 y_delta, + u32 xy_mask, + u32 sync_gen_width, + u32 sync_gen_height, + u32 sync_gen_hblank_cycles, + u32 sync_gen_vblank_cycles, + target_cfg2400_t target +) +{ + channel_cfg_t channel; + + (void)nof_frames; + + channel.ch_id = ch_id; + channel.source_type = INPUT_SYSTEM_SOURCE_TPG; + + channel.source_cfg.tpg_cfg.x_mask = x_mask; + channel.source_cfg.tpg_cfg.y_mask = y_mask; + channel.source_cfg.tpg_cfg.x_delta = x_delta; + channel.source_cfg.tpg_cfg.y_delta = y_delta; + channel.source_cfg.tpg_cfg.xy_mask = xy_mask; + channel.source_cfg.tpg_cfg.sync_gen_cfg.width = sync_gen_width; + channel.source_cfg.tpg_cfg.sync_gen_cfg.height = sync_gen_height; + channel.source_cfg.tpg_cfg.sync_gen_cfg.hblank_cycles = sync_gen_hblank_cycles; + channel.source_cfg.tpg_cfg.sync_gen_cfg.vblank_cycles = sync_gen_vblank_cycles; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +// MW: Don't use system specific names, (even in system specific files) "cfg2400" -> cfg +input_system_error_t input_system_gpfifo_channel_cfg( + u32 ch_id, + u32 nof_frames, //not used yet + + target_cfg2400_t target) +{ + channel_cfg_t channel; + + (void)nof_frames; + + channel.ch_id = ch_id; + channel.source_type = INPUT_SYSTEM_SOURCE_FIFO; + + channel.target_cfg = target; + return input_system_configure_channel(channel); +} + +/////////////////////////////////////////////////////////////////////////// +// +// Private specialized functions for channel setting. +// +/////////////////////////////////////////////////////////////////////////// + +// Fills the parameters to config.csi_value[port] +static input_system_error_t input_system_configure_channel_sensor( + const channel_cfg_t channel) +{ + const u32 port = channel.source_cfg.csi_cfg.csi_port; + input_system_error_t status = INPUT_SYSTEM_ERR_NO_ERROR; + + input_system_multiplex_t mux; + + if (port >= N_INPUT_SYSTEM_PORTS) + return INPUT_SYSTEM_ERR_GENERIC; + + //check if port > N_INPUT_SYSTEM_MULTIPLEX + + status = set_source_type(&config.source_type, channel.source_type, + &config.source_type_flags); + if (status != INPUT_SYSTEM_ERR_NO_ERROR) return status; + + // Check for conflicts on source (implicitly on multicast, capture unit and input buffer). + + status = set_csi_cfg(&config.csi_value[port], &channel.source_cfg.csi_cfg, + &config.csi_flags[port]); + if (status != INPUT_SYSTEM_ERR_NO_ERROR) return status; + + switch (channel.source_cfg.csi_cfg.buffering_mode) { + case INPUT_SYSTEM_FIFO_CAPTURE: + + // Check for conflicts on mux. + mux = INPUT_SYSTEM_MIPI_PORT0 + port; + status = input_system_multiplexer_cfg(&config.multiplexer, mux, + &config.multiplexer_flags); + if (status != INPUT_SYSTEM_ERR_NO_ERROR) return status; + config.multicast[port] = INPUT_SYSTEM_CSI_BACKEND; + + // Shared resource, so it should be blocked. + //config.mux_flags |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + //config.csi_buffer_flags[port] |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + //config.acquisition_buffer_unique_flags |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + + break; + case INPUT_SYSTEM_SRAM_BUFFERING: + + // Check for conflicts on mux. + mux = INPUT_SYSTEM_ACQUISITION_UNIT; + status = input_system_multiplexer_cfg(&config.multiplexer, mux, + &config.multiplexer_flags); + if (status != INPUT_SYSTEM_ERR_NO_ERROR) return status; + config.multicast[port] = INPUT_SYSTEM_INPUT_BUFFER; + + // Shared resource, so it should be blocked. + //config.mux_flags |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + //config.csi_buffer_flags[port] |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + //config.acquisition_buffer_unique_flags |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + + break; + case INPUT_SYSTEM_XMEM_BUFFERING: + + // Check for conflicts on mux. + mux = INPUT_SYSTEM_ACQUISITION_UNIT; + status = input_system_multiplexer_cfg(&config.multiplexer, mux, + &config.multiplexer_flags); + if (status != INPUT_SYSTEM_ERR_NO_ERROR) return status; + config.multicast[port] = INPUT_SYSTEM_INPUT_BUFFER; + + // Shared resource, so it should be blocked. + //config.mux_flags |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + //config.csi_buffer_flags[port] |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + //config.acquisition_buffer_unique_flags |= INPUT_SYSTEM_CFG_FLAG_BLOCKED; + + break; + case INPUT_SYSTEM_FIFO_CAPTURE_WITH_COUNTING: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + case INPUT_SYSTEM_XMEM_CAPTURE: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + case INPUT_SYSTEM_XMEM_ACQUIRE: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + default: + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + break; + } + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +// Test flags and set structure. +static input_system_error_t set_source_type( + input_system_source_t *const lhs, + const input_system_source_t rhs, + input_system_config_flags_t *const flags) +{ + // MW: Not enough asserts + assert(lhs); + assert(flags); + + if ((*flags) & INPUT_SYSTEM_CFG_FLAG_BLOCKED) { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + + if ((*flags) & INPUT_SYSTEM_CFG_FLAG_SET) { + // Check for consistency with already set value. + if ((*lhs) == (rhs)) { + return INPUT_SYSTEM_ERR_NO_ERROR; + } else { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + } + // Check the value (individually). + if (rhs >= N_INPUT_SYSTEM_SOURCE) { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + // Set the value. + *lhs = rhs; + + *flags |= INPUT_SYSTEM_CFG_FLAG_SET; + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +// Test flags and set structure. +static input_system_error_t set_csi_cfg( + csi_cfg_t *const lhs, + const csi_cfg_t *const rhs, + input_system_config_flags_t *const flags) +{ + u32 memory_required; + u32 acq_memory_required; + + assert(lhs); + assert(flags); + + if ((*flags) & INPUT_SYSTEM_CFG_FLAG_BLOCKED) { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + + if (*flags & INPUT_SYSTEM_CFG_FLAG_SET) { + // check for consistency with already set value. + if (/*lhs->backend_ch == rhs.backend_ch + &&*/ lhs->buffering_mode == rhs->buffering_mode + && lhs->csi_buffer.mem_reg_size == rhs->csi_buffer.mem_reg_size + && lhs->csi_buffer.nof_mem_regs == rhs->csi_buffer.nof_mem_regs + && lhs->acquisition_buffer.mem_reg_size == rhs->acquisition_buffer.mem_reg_size + && lhs->acquisition_buffer.nof_mem_regs == rhs->acquisition_buffer.nof_mem_regs + && lhs->nof_xmem_buffers == rhs->nof_xmem_buffers + ) { + return INPUT_SYSTEM_ERR_NO_ERROR; + } else { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + } + // Check the value (individually). + // no check for backend_ch + // no check for nof_xmem_buffers + memory_required = rhs->csi_buffer.mem_reg_size * rhs->csi_buffer.nof_mem_regs; + acq_memory_required = rhs->acquisition_buffer.mem_reg_size * + rhs->acquisition_buffer.nof_mem_regs; + if (rhs->buffering_mode >= N_INPUT_SYSTEM_BUFFERING_MODE + || + // Check if required memory is available in input buffer (SRAM). + (memory_required + acq_memory_required) > config.unallocated_ib_mem_words + + ) { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + // Set the value. + //lhs[port]->backend_ch = rhs.backend_ch; + lhs->buffering_mode = rhs->buffering_mode; + lhs->nof_xmem_buffers = rhs->nof_xmem_buffers; + + lhs->csi_buffer.mem_reg_size = rhs->csi_buffer.mem_reg_size; + lhs->csi_buffer.nof_mem_regs = rhs->csi_buffer.nof_mem_regs; + lhs->acquisition_buffer.mem_reg_size = rhs->acquisition_buffer.mem_reg_size; + lhs->acquisition_buffer.nof_mem_regs = rhs->acquisition_buffer.nof_mem_regs; + // ALX: NB: Here we just set buffer parameters, but still not allocate it + // (no addresses determined). That will be done during commit. + + // FIXIT: acq_memory_required is not deducted, since it can be allocated multiple times. + config.unallocated_ib_mem_words -= memory_required; +//assert(config.unallocated_ib_mem_words >=0); + *flags |= INPUT_SYSTEM_CFG_FLAG_SET; + return INPUT_SYSTEM_ERR_NO_ERROR; +} + +// Test flags and set structure. +static input_system_error_t input_system_multiplexer_cfg( + input_system_multiplex_t *const lhs, + const input_system_multiplex_t rhs, + input_system_config_flags_t *const flags) +{ + assert(lhs); + assert(flags); + + if ((*flags) & INPUT_SYSTEM_CFG_FLAG_BLOCKED) { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + + if ((*flags) & INPUT_SYSTEM_CFG_FLAG_SET) { + // Check for consistency with already set value. + if ((*lhs) == (rhs)) { + return INPUT_SYSTEM_ERR_NO_ERROR; + } else { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_CONFLICT_ON_RESOURCE; + } + } + // Check the value (individually). + if (rhs >= N_INPUT_SYSTEM_MULTIPLEX) { + *flags |= INPUT_SYSTEM_CFG_FLAG_CONFLICT; + return INPUT_SYSTEM_ERR_PARAMETER_NOT_SUPPORTED; + } + // Set the value. + *lhs = rhs; + + *flags |= INPUT_SYSTEM_CFG_FLAG_SET; + return INPUT_SYSTEM_ERR_NO_ERROR; +} +#endif |