// SPDX-License-Identifier: GPL-2.0 /* * Support for Intel Camera Imaging ISP subsystem. * Copyright (c) 2010-2015, 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" #ifndef ISP2401 #include "input_formatter.h" #include #include "gp_device.h" #include "assert_support.h" #ifndef __INLINE_INPUT_FORMATTER__ #include "input_formatter_private.h" #endif /* __INLINE_INPUT_FORMATTER__ */ static const unsigned int input_formatter_alignment[N_INPUT_FORMATTER_ID] = { ISP_VEC_ALIGN, ISP_VEC_ALIGN, HIVE_ISP_CTRL_DATA_BYTES }; const hrt_address HIVE_IF_SRST_ADDRESS[N_INPUT_FORMATTER_ID] = { INPUT_FORMATTER0_SRST_OFFSET, INPUT_FORMATTER1_SRST_OFFSET, INPUT_FORMATTER2_SRST_OFFSET, INPUT_FORMATTER3_SRST_OFFSET }; const hrt_data HIVE_IF_SRST_MASK[N_INPUT_FORMATTER_ID] = { INPUT_FORMATTER0_SRST_MASK, INPUT_FORMATTER1_SRST_MASK, INPUT_FORMATTER2_SRST_MASK, INPUT_FORMATTER3_SRST_MASK }; const u8 HIVE_IF_SWITCH_CODE[N_INPUT_FORMATTER_ID] = { HIVE_INPUT_SWITCH_SELECT_IF_PRIM, HIVE_INPUT_SWITCH_SELECT_IF_PRIM, HIVE_INPUT_SWITCH_SELECT_IF_SEC, HIVE_INPUT_SWITCH_SELECT_STR_TO_MEM }; /* MW Should be part of system_global.h, where we have the main enumeration */ static const bool HIVE_IF_BIN_COPY[N_INPUT_FORMATTER_ID] = { false, false, false, true }; void input_formatter_rst( const input_formatter_ID_t ID) { hrt_address addr; hrt_data rst; assert(ID < N_INPUT_FORMATTER_ID); addr = HIVE_IF_SRST_ADDRESS[ID]; rst = HIVE_IF_SRST_MASK[ID]; /* TEMPORARY HACK: THIS RESET BREAKS THE METADATA FEATURE * WICH USES THE STREAM2MEMRY BLOCK. * MUST BE FIXED PROPERLY */ if (!HIVE_IF_BIN_COPY[ID]) { input_formatter_reg_store(ID, addr, rst); } return; } unsigned int input_formatter_get_alignment( const input_formatter_ID_t ID) { assert(ID < N_INPUT_FORMATTER_ID); return input_formatter_alignment[ID]; } void input_formatter_set_fifo_blocking_mode( const input_formatter_ID_t ID, const bool enable) { assert(ID < N_INPUT_FORMATTER_ID); /* cnd_input_formatter_reg_store() */ if (!HIVE_IF_BIN_COPY[ID]) { input_formatter_reg_store(ID, HIVE_IF_BLOCK_FIFO_NO_REQ_ADDRESS, enable); } return; } void input_formatter_get_switch_state( const input_formatter_ID_t ID, input_formatter_switch_state_t *state) { assert(ID < N_INPUT_FORMATTER_ID); assert(state); /* We'll change this into an intelligent function to get switch info per IF */ (void)ID; state->if_input_switch_lut_reg[0] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg0); state->if_input_switch_lut_reg[1] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg1); state->if_input_switch_lut_reg[2] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg2); state->if_input_switch_lut_reg[3] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg3); state->if_input_switch_lut_reg[4] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg4); state->if_input_switch_lut_reg[5] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg5); state->if_input_switch_lut_reg[6] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg6); state->if_input_switch_lut_reg[7] = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_lut_reg7); state->if_input_switch_fsync_lut = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_fsync_lut); state->if_input_switch_ch_id_fmt_type = gp_device_reg_load(GP_DEVICE0_ID, _REG_GP_IFMT_input_switch_ch_id_fmt_type); return; } void input_formatter_get_state( const input_formatter_ID_t ID, input_formatter_state_t *state) { assert(ID < N_INPUT_FORMATTER_ID); assert(state); /* state->reset = input_formatter_reg_load(ID, HIVE_IF_RESET_ADDRESS); */ state->start_line = input_formatter_reg_load(ID, HIVE_IF_START_LINE_ADDRESS); state->start_column = input_formatter_reg_load(ID, HIVE_IF_START_COLUMN_ADDRESS); state->cropped_height = input_formatter_reg_load(ID, HIVE_IF_CROPPED_HEIGHT_ADDRESS); state->cropped_width = input_formatter_reg_load(ID, HIVE_IF_CROPPED_WIDTH_ADDRESS); state->ver_decimation = input_formatter_reg_load(ID, HIVE_IF_VERTICAL_DECIMATION_ADDRESS); state->hor_decimation = input_formatter_reg_load(ID, HIVE_IF_HORIZONTAL_DECIMATION_ADDRESS); state->hor_deinterleaving = input_formatter_reg_load(ID, HIVE_IF_H_DEINTERLEAVING_ADDRESS); state->left_padding = input_formatter_reg_load(ID, HIVE_IF_LEFTPADDING_WIDTH_ADDRESS); state->eol_offset = input_formatter_reg_load(ID, HIVE_IF_END_OF_LINE_OFFSET_ADDRESS); state->vmem_start_address = input_formatter_reg_load(ID, HIVE_IF_VMEM_START_ADDRESS_ADDRESS); state->vmem_end_address = input_formatter_reg_load(ID, HIVE_IF_VMEM_END_ADDRESS_ADDRESS); state->vmem_increment = input_formatter_reg_load(ID, HIVE_IF_VMEM_INCREMENT_ADDRESS); state->is_yuv420 = input_formatter_reg_load(ID, HIVE_IF_YUV_420_FORMAT_ADDRESS); state->vsync_active_low = input_formatter_reg_load(ID, HIVE_IF_VSYNCK_ACTIVE_LOW_ADDRESS); state->hsync_active_low = input_formatter_reg_load(ID, HIVE_IF_HSYNCK_ACTIVE_LOW_ADDRESS); state->allow_fifo_overflow = input_formatter_reg_load(ID, HIVE_IF_ALLOW_FIFO_OVERFLOW_ADDRESS); state->block_fifo_when_no_req = input_formatter_reg_load(ID, HIVE_IF_BLOCK_FIFO_NO_REQ_ADDRESS); state->ver_deinterleaving = input_formatter_reg_load(ID, HIVE_IF_V_DEINTERLEAVING_ADDRESS); /* FSM */ state->fsm_sync_status = input_formatter_reg_load(ID, HIVE_IF_FSM_SYNC_STATUS); state->fsm_sync_counter = input_formatter_reg_load(ID, HIVE_IF_FSM_SYNC_COUNTER); state->fsm_crop_status = input_formatter_reg_load(ID, HIVE_IF_FSM_CROP_STATUS); state->fsm_crop_line_counter = input_formatter_reg_load(ID, HIVE_IF_FSM_CROP_LINE_COUNTER); state->fsm_crop_pixel_counter = input_formatter_reg_load(ID, HIVE_IF_FSM_CROP_PIXEL_COUNTER); state->fsm_deinterleaving_index = input_formatter_reg_load(ID, HIVE_IF_FSM_DEINTERLEAVING_IDX); state->fsm_dec_h_counter = input_formatter_reg_load(ID, HIVE_IF_FSM_DECIMATION_H_COUNTER); state->fsm_dec_v_counter = input_formatter_reg_load(ID, HIVE_IF_FSM_DECIMATION_V_COUNTER); state->fsm_dec_block_v_counter = input_formatter_reg_load(ID, HIVE_IF_FSM_DECIMATION_BLOCK_V_COUNTER); state->fsm_padding_status = input_formatter_reg_load(ID, HIVE_IF_FSM_PADDING_STATUS); state->fsm_padding_elem_counter = input_formatter_reg_load(ID, HIVE_IF_FSM_PADDING_ELEMENT_COUNTER); state->fsm_vector_support_error = input_formatter_reg_load(ID, HIVE_IF_FSM_VECTOR_SUPPORT_ERROR); state->fsm_vector_buffer_full = input_formatter_reg_load(ID, HIVE_IF_FSM_VECTOR_SUPPORT_BUFF_FULL); state->vector_support = input_formatter_reg_load(ID, HIVE_IF_FSM_VECTOR_SUPPORT); state->sensor_data_lost = input_formatter_reg_load(ID, HIVE_IF_FIFO_SENSOR_STATUS); return; } void input_formatter_bin_get_state( const input_formatter_ID_t ID, input_formatter_bin_state_t *state) { assert(ID < N_INPUT_FORMATTER_ID); assert(state); state->reset = input_formatter_reg_load(ID, HIVE_STR2MEM_SOFT_RESET_REG_ADDRESS); state->input_endianness = input_formatter_reg_load(ID, HIVE_STR2MEM_INPUT_ENDIANNESS_REG_ADDRESS); state->output_endianness = input_formatter_reg_load(ID, HIVE_STR2MEM_OUTPUT_ENDIANNESS_REG_ADDRESS); state->bitswap = input_formatter_reg_load(ID, HIVE_STR2MEM_BIT_SWAPPING_REG_ADDRESS); state->block_synch = input_formatter_reg_load(ID, HIVE_STR2MEM_BLOCK_SYNC_LEVEL_REG_ADDRESS); state->packet_synch = input_formatter_reg_load(ID, HIVE_STR2MEM_PACKET_SYNC_LEVEL_REG_ADDRESS); state->readpostwrite_synch = input_formatter_reg_load(ID, HIVE_STR2MEM_READ_POST_WRITE_SYNC_ENABLE_REG_ADDRESS); state->is_2ppc = input_formatter_reg_load(ID, HIVE_STR2MEM_DUAL_BYTE_INPUTS_ENABLED_REG_ADDRESS); state->en_status_update = input_formatter_reg_load(ID, HIVE_STR2MEM_EN_STAT_UPDATE_ADDRESS); return; } #endif