/* * axi lite register access driver * Xianjun jiao. putaoshu@msn.com; xianjun.jiao@imec.be */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../hw_def.h" static void __iomem *base_addr; // to store driver specific base address needed for mmu to translate virtual address to physical address in our FPGA design /* IO accessors */ static inline u32 reg_read(u32 reg) { return ioread32(base_addr + reg); } static inline void reg_write(u32 reg, u32 value) { iowrite32(value, base_addr + reg); } static inline void XPU_REG_MULTI_RST_write(u32 Data) { reg_write(XPU_REG_MULTI_RST_ADDR, Data); } static inline u32 XPU_REG_MULTI_RST_read(void){ return reg_read(XPU_REG_MULTI_RST_ADDR); } static inline void XPU_REG_SRC_SEL_write(u32 Data) { reg_write(XPU_REG_SRC_SEL_ADDR, Data); } static inline u32 XPU_REG_SRC_SEL_read(void){ return reg_read(XPU_REG_SRC_SEL_ADDR); } static inline void XPU_REG_RECV_ACK_COUNT_TOP0_write(u32 Data) { reg_write(XPU_REG_RECV_ACK_COUNT_TOP0_ADDR, Data); } static inline u32 XPU_REG_RECV_ACK_COUNT_TOP0_read(void){ return reg_read(XPU_REG_RECV_ACK_COUNT_TOP0_ADDR); } static inline void XPU_REG_RECV_ACK_COUNT_TOP1_write(u32 Data) { reg_write(XPU_REG_RECV_ACK_COUNT_TOP1_ADDR, Data); } static inline u32 XPU_REG_RECV_ACK_COUNT_TOP1_read(void){ return reg_read(XPU_REG_RECV_ACK_COUNT_TOP1_ADDR); } static inline void XPU_REG_SEND_ACK_WAIT_TOP_write(u32 Data) { reg_write(XPU_REG_SEND_ACK_WAIT_TOP_ADDR, Data); } static inline u32 XPU_REG_SEND_ACK_WAIT_TOP_read(void){ return reg_read(XPU_REG_SEND_ACK_WAIT_TOP_ADDR); } static inline void XPU_REG_FILTER_FLAG_write(u32 Data) { reg_write(XPU_REG_FILTER_FLAG_ADDR, Data); } static inline u32 XPU_REG_FILTER_FLAG_read(void){ return reg_read(XPU_REG_FILTER_FLAG_ADDR); } static inline void XPU_REG_CTS_TO_RTS_CONFIG_write(u32 Data) { reg_write(XPU_REG_CTS_TO_RTS_CONFIG_ADDR, Data); } static inline u32 XPU_REG_CTS_TO_RTS_CONFIG_read(void){ return reg_read(XPU_REG_CTS_TO_RTS_CONFIG_ADDR); } static inline void XPU_REG_MAC_ADDR_LOW_write(u32 Data) { reg_write(XPU_REG_MAC_ADDR_LOW_ADDR, Data); } static inline u32 XPU_REG_MAC_ADDR_LOW_read(void){ return reg_read(XPU_REG_MAC_ADDR_LOW_ADDR); } static inline void XPU_REG_MAC_ADDR_HIGH_write(u32 Data) { reg_write(XPU_REG_MAC_ADDR_HIGH_ADDR, Data); } static inline u32 XPU_REG_MAC_ADDR_HIGH_read(void){ return reg_read(XPU_REG_MAC_ADDR_HIGH_ADDR); } static inline void XPU_REG_BSSID_FILTER_LOW_write(u32 Data) { reg_write(XPU_REG_BSSID_FILTER_LOW_ADDR, Data); } static inline u32 XPU_REG_BSSID_FILTER_LOW_read(void){ return reg_read(XPU_REG_BSSID_FILTER_LOW_ADDR); } static inline void XPU_REG_BSSID_FILTER_HIGH_write(u32 Data) { reg_write(XPU_REG_BSSID_FILTER_HIGH_ADDR, Data); } static inline u32 XPU_REG_BSSID_FILTER_HIGH_read(void){ return reg_read(XPU_REG_BSSID_FILTER_HIGH_ADDR); } static inline void XPU_REG_BAND_CHANNEL_write(u32 Data) { reg_write(XPU_REG_BAND_CHANNEL_ADDR, Data); } static inline u32 XPU_REG_BAND_CHANNEL_read(void){ return reg_read(XPU_REG_BAND_CHANNEL_ADDR); } static inline u32 XPU_REG_TRX_STATUS_read(void){ return reg_read(XPU_REG_TRX_STATUS_ADDR); } static inline u32 XPU_REG_TX_RESULT_read(void){ return reg_read(XPU_REG_TX_RESULT_ADDR); } static inline u32 XPU_REG_TSF_RUNTIME_VAL_LOW_read(void){ return reg_read(XPU_REG_TSF_RUNTIME_VAL_LOW_ADDR); } static inline u32 XPU_REG_TSF_RUNTIME_VAL_HIGH_read(void){ return reg_read(XPU_REG_TSF_RUNTIME_VAL_HIGH_ADDR); } static inline void XPU_REG_TSF_LOAD_VAL_LOW_write(u32 value){ reg_write(XPU_REG_TSF_LOAD_VAL_LOW_ADDR, value); } static inline void XPU_REG_TSF_LOAD_VAL_HIGH_write(u32 value){ reg_write(XPU_REG_TSF_LOAD_VAL_HIGH_ADDR, value); } static inline void XPU_REG_TSF_LOAD_VAL_write(u32 high_value, u32 low_value){ XPU_REG_TSF_LOAD_VAL_LOW_write(low_value); XPU_REG_TSF_LOAD_VAL_HIGH_write(high_value|0x80000000); // msb high XPU_REG_TSF_LOAD_VAL_HIGH_write(high_value&(~0x80000000)); // msb low } static inline u32 XPU_REG_FC_DI_read(void){ return reg_read(XPU_REG_FC_DI_ADDR); } static inline u32 XPU_REG_ADDR1_LOW_read(void){ return reg_read(XPU_REG_ADDR1_LOW_ADDR); } static inline u32 XPU_REG_ADDR1_HIGH_read(void){ return reg_read(XPU_REG_ADDR1_HIGH_ADDR); } static inline u32 XPU_REG_ADDR2_LOW_read(void){ return reg_read(XPU_REG_ADDR2_LOW_ADDR); } static inline u32 XPU_REG_ADDR2_HIGH_read(void){ return reg_read(XPU_REG_ADDR2_HIGH_ADDR); } // static inline void XPU_REG_LBT_TH_write(u32 value, u32 en_flag) { // if (en_flag) { // reg_write(XPU_REG_LBT_TH_ADDR, value&0x7FFFFFFF); // } else { // reg_write(XPU_REG_LBT_TH_ADDR, value|0x80000000); // } // } static inline void XPU_REG_LBT_TH_write(u32 value) { reg_write(XPU_REG_LBT_TH_ADDR, value); } static inline u32 XPU_REG_RSSI_DB_CFG_read(void){ return reg_read(XPU_REG_RSSI_DB_CFG_ADDR); } static inline void XPU_REG_RSSI_DB_CFG_write(u32 Data) { reg_write(XPU_REG_RSSI_DB_CFG_ADDR, Data); } static inline u32 XPU_REG_LBT_TH_read(void){ return reg_read(XPU_REG_LBT_TH_ADDR); } static inline void XPU_REG_CSMA_DEBUG_write(u32 value){ reg_write(XPU_REG_CSMA_DEBUG_ADDR, value); } static inline u32 XPU_REG_CSMA_DEBUG_read(void){ return reg_read(XPU_REG_CSMA_DEBUG_ADDR); } static inline void XPU_REG_CSMA_CFG_write(u32 value){ reg_write(XPU_REG_CSMA_CFG_ADDR, value); } static inline u32 XPU_REG_CSMA_CFG_read(void){ return reg_read(XPU_REG_CSMA_CFG_ADDR); } static inline void XPU_REG_SLICE_COUNT_TOTAL0_write(u32 value){ reg_write(XPU_REG_SLICE_COUNT_TOTAL0_ADDR, value); } static inline void XPU_REG_SLICE_COUNT_START0_write(u32 value){ reg_write(XPU_REG_SLICE_COUNT_START0_ADDR, value); } static inline void XPU_REG_SLICE_COUNT_END0_write(u32 value){ reg_write(XPU_REG_SLICE_COUNT_END0_ADDR, value); } static inline void XPU_REG_SLICE_COUNT_TOTAL1_write(u32 value){ reg_write(XPU_REG_SLICE_COUNT_TOTAL1_ADDR, value); } static inline void XPU_REG_SLICE_COUNT_START1_write(u32 value){ reg_write(XPU_REG_SLICE_COUNT_START1_ADDR, value); } static inline void XPU_REG_SLICE_COUNT_END1_write(u32 value){ reg_write(XPU_REG_SLICE_COUNT_END1_ADDR, value); } static inline u32 XPU_REG_SLICE_COUNT_TOTAL0_read(void){ return reg_read(XPU_REG_SLICE_COUNT_TOTAL0_ADDR); } static inline u32 XPU_REG_SLICE_COUNT_START0_read(void){ return reg_read(XPU_REG_SLICE_COUNT_START0_ADDR); } static inline u32 XPU_REG_SLICE_COUNT_END0_read(void){ return reg_read(XPU_REG_SLICE_COUNT_END0_ADDR); } static inline u32 XPU_REG_SLICE_COUNT_TOTAL1_read(void){ return reg_read(XPU_REG_SLICE_COUNT_TOTAL1_ADDR); } static inline u32 XPU_REG_SLICE_COUNT_START1_read(void){ return reg_read(XPU_REG_SLICE_COUNT_START1_ADDR); } static inline u32 XPU_REG_SLICE_COUNT_END1_read(void){ return reg_read(XPU_REG_SLICE_COUNT_END1_ADDR); } static inline void XPU_REG_BB_RF_DELAY_write(u32 value){ reg_write(XPU_REG_BB_RF_DELAY_ADDR, value); } static inline void XPU_REG_MAX_NUM_RETRANS_write(u32 value){ reg_write(XPU_REG_MAX_NUM_RETRANS_ADDR, value); } static inline void XPU_REG_MAC_ADDR_write(u8 *mac_addr) {//, u32 en_flag){ XPU_REG_MAC_ADDR_LOW_write( *( (u32*)(mac_addr) ) ); XPU_REG_MAC_ADDR_HIGH_write( *( (u16*)(mac_addr + 4) ) ); #if 0 if (en_flag) { XPU_REG_MAC_ADDR_HIGH_write( (*( (u16*)(mac_addr + 4) )) | 0x80000000 ); // 0x80000000 by default we turn on mac addr filter } else { XPU_REG_MAC_ADDR_HIGH_write( (*( (u16*)(mac_addr + 4) )) & 0x7FFFFFFF ); } #endif } static const struct of_device_id dev_of_ids[] = { { .compatible = "sdr,xpu", }, {} }; MODULE_DEVICE_TABLE(of, dev_of_ids); static struct xpu_driver_api xpu_driver_api_inst; static struct xpu_driver_api *xpu_api = &xpu_driver_api_inst; EXPORT_SYMBOL(xpu_api); static inline u32 hw_init(enum xpu_mode mode){ int err=0, rssi_half_db_th, rssi_half_db_offset, agc_gain_delay; u32 reg_val; u32 filter_flag = 0; printk("%s hw_init mode %d\n", xpu_compatible_str, mode); //rst internal module for (reg_val=0;reg_val<32;reg_val++) xpu_api->XPU_REG_MULTI_RST_write(0xFFFFFFFF); xpu_api->XPU_REG_MULTI_RST_write(0); // http://www.studioreti.it/slide/802-11-Frame_E_C.pdf // https://mrncciew.com/2014/10/14/cwap-802-11-phy-ppdu/ // https://mrncciew.com/2014/09/27/cwap-mac-header-frame-control/ // https://mrncciew.com/2014/10/25/cwap-mac-header-durationid/ // https://mrncciew.com/2014/11/01/cwap-mac-header-sequence-control/ // https://witestlab.poly.edu/blog/802-11-wireless-lan-2/ // phy_rx byte idx: // 5(3 sig + 2 service), -- PHY // 2 frame control, 2 duration/conn ID, --MAC PDU // 6 receiver address, 6 destination address, 6 transmitter address // 2 sequence control // 6 source address // reg_val = 5 + 0; // xpu_api->XPU_REG_PHY_RX_PKT_READ_OFFSET_write(reg_val); // printk("%s hw_init XPU_REG_PHY_RX_PKT_READ_OFFSET_write %d\n", xpu_compatible_str, reg_val); // by default turn off filter, because all register are zeros // let's filter out packet according to: enum ieee80211_filter_flags at: https://www.kernel.org/doc/html/v4.9/80211/mac80211.html #if 0 // define in FPGA localparam [13:0] FIF_ALLMULTI = 14b00000000000010, //get all mac addr like 01:00:5E:xx:xx:xx and 33:33:xx:xx:xx:xx through to ARM FIF_FCSFAIL = 14b00000000000100, //not support FIF_PLCPFAIL = 14b00000000001000, //not support FIF_BCN_PRBRESP_PROMISC= 14b00000000010000, FIF_CONTROL = 14b00000000100000, FIF_OTHER_BSS = 14b00000001000000, FIF_PSPOLL = 14b00000010000000, FIF_PROBE_REQ = 14b00000100000000, UNICAST_FOR_US = 14b00001000000000, BROADCAST_ALL_ONE = 14b00010000000000, BROADCAST_ALL_ZERO = 14b00100000000000, MY_BEACON = 14b01000000000000, MONITOR_ALL = 14b10000000000000; #endif filter_flag = (FIF_ALLMULTI|FIF_FCSFAIL|FIF_PLCPFAIL|FIF_BCN_PRBRESP_PROMISC|FIF_CONTROL|FIF_OTHER_BSS|FIF_PSPOLL|FIF_PROBE_REQ|UNICAST_FOR_US|BROADCAST_ALL_ONE|BROADCAST_ALL_ZERO|MY_BEACON|MONITOR_ALL); xpu_api->XPU_REG_FILTER_FLAG_write(filter_flag); xpu_api->XPU_REG_CTS_TO_RTS_CONFIG_write(0xB<<16);//6M 1011:0xB ////set up FC type filter for packet needs ACK -- no use, FPGA handle by itself //xpu_api->XPU_REG_ACK_FC_FILTER_write((3<<(2+16))|(2<<2)); // low 16 bits target FC 16 bits; high 16 bits -- mask // after send data frame wait for ACK, this will be set in real time in function ad9361_rf_set_channel // xpu_api->XPU_REG_RECV_ACK_COUNT_TOP1_write( (((51+2)*200)<<16) | 200 ); // high 16 bits to cover sig valid of ACK packet, low 16 bits is adjustment of fcs valid waiting time. let's add 2us for those device that is really "slow"! // xpu_api->XPU_REG_SEND_ACK_WAIT_TOP_write( 1200 ); // +6 = 16us for 5GHz //xpu_api->XPU_REG_MAX_NUM_RETRANS_write(3); // if this > 0, it will override mac80211 set value, and set static retransmission limit xpu_api->XPU_REG_BB_RF_DELAY_write(975); xpu_api->XPU_REG_SLICE_COUNT_TOTAL0_write(50000-1); // total 50ms xpu_api->XPU_REG_SLICE_COUNT_START0_write(0); //start 0ms xpu_api->XPU_REG_SLICE_COUNT_END0_write(50000-1); //end 10ms xpu_api->XPU_REG_SLICE_COUNT_TOTAL1_write(50000-1); // total 50ms xpu_api->XPU_REG_SLICE_COUNT_START1_write(0000); //start 0ms xpu_api->XPU_REG_SLICE_COUNT_END1_write(1000-1); //end 1ms switch(mode) { case XPU_TEST: printk("%s hw_init mode XPU_TEST\n", xpu_compatible_str); break; case XPU_NORMAL: printk("%s hw_init mode XPU_NORMAL\n", xpu_compatible_str); break; default: printk("%s hw_init mode %d is wrong!\n", xpu_compatible_str, mode); err=1; } xpu_api->XPU_REG_BAND_CHANNEL_write((false<<24)|(BAND_5_8GHZ<<16)|44);//use_short_slot==false; 5.8GHz; channel 44 -- default setting to sync with priv->band/channel/use_short_slot agc_gain_delay = 50; //samples rssi_half_db_offset = 75<<1; xpu_api->XPU_REG_RSSI_DB_CFG_write(0x80000000|((rssi_half_db_offset<<16)|agc_gain_delay) ); xpu_api->XPU_REG_RSSI_DB_CFG_write((~0x80000000)&((rssi_half_db_offset<<16)|agc_gain_delay) ); //rssi_half_db_th = 70<<1; // with splitter rssi_half_db_th = 87<<1; // -62dBm xpu_api->XPU_REG_LBT_TH_write(rssi_half_db_th); // set IQ rssi th step .5dB to xxx and enable it //xpu_api->XPU_REG_CSMA_DEBUG_write((1<<31)|(20<<24)|(4<<19)|(3<<14)|(10<<7)|(5)); xpu_api->XPU_REG_CSMA_DEBUG_write(0); //xpu_api->XPU_REG_CSMA_CFG_write(3); //normal CSMA xpu_api->XPU_REG_CSMA_CFG_write(0xe0000000); //high priority xpu_api->XPU_REG_SEND_ACK_WAIT_TOP_write( ((1030-238)<<16)|0 );//high 16bit 5GHz; low 16 bit 2.4GHz (Attention, current tx core has around 1.19us starting delay that makes the ack fall behind 10us SIFS in 2.4GHz! Need to improve TX in 2.4GHz!) //xpu_api->XPU_REG_RECV_ACK_COUNT_TOP0_write( (((45+2+2)*200)<<16) | 400 );//2.4GHz //xpu_api->XPU_REG_RECV_ACK_COUNT_TOP1_write( (((51+2+2)*200)<<16) | 400 );//5GHz // // value from openwifi-preo csma_test xpu_api->XPU_REG_RECV_ACK_COUNT_TOP0_write( (((45+2+6)*200)<<16) | 200 );//2.4GHz, still need to find out why sometimes the PI in ad-hoc 2.4GHz mode give ack so slow: 18us xpu_api->XPU_REG_RECV_ACK_COUNT_TOP1_write( (((51+2)*200)<<16) | 200 );//5GHz printk("%s hw_init err %d\n", xpu_compatible_str, err); return(err); } static int dev_probe(struct platform_device *pdev) { struct device_node *np = pdev->dev.of_node; struct resource *io; u32 test_us0, test_us1, test_us2; int err=1; printk("\n"); if (np) { const struct of_device_id *match; match = of_match_node(dev_of_ids, np); if (match) { printk("%s dev_probe match!\n", xpu_compatible_str); err = 0; } } if (err) return err; xpu_api->hw_init=hw_init; xpu_api->reg_read=reg_read; xpu_api->reg_write=reg_write; xpu_api->XPU_REG_MULTI_RST_write=XPU_REG_MULTI_RST_write; xpu_api->XPU_REG_MULTI_RST_read=XPU_REG_MULTI_RST_read; xpu_api->XPU_REG_SRC_SEL_write=XPU_REG_SRC_SEL_write; xpu_api->XPU_REG_SRC_SEL_read=XPU_REG_SRC_SEL_read; xpu_api->XPU_REG_RECV_ACK_COUNT_TOP0_write=XPU_REG_RECV_ACK_COUNT_TOP0_write; xpu_api->XPU_REG_RECV_ACK_COUNT_TOP0_read=XPU_REG_RECV_ACK_COUNT_TOP0_read; xpu_api->XPU_REG_RECV_ACK_COUNT_TOP1_write=XPU_REG_RECV_ACK_COUNT_TOP1_write; xpu_api->XPU_REG_RECV_ACK_COUNT_TOP1_read=XPU_REG_RECV_ACK_COUNT_TOP1_read; xpu_api->XPU_REG_SEND_ACK_WAIT_TOP_write=XPU_REG_SEND_ACK_WAIT_TOP_write; xpu_api->XPU_REG_SEND_ACK_WAIT_TOP_read=XPU_REG_SEND_ACK_WAIT_TOP_read; xpu_api->XPU_REG_MAC_ADDR_LOW_write=XPU_REG_MAC_ADDR_LOW_write; xpu_api->XPU_REG_MAC_ADDR_LOW_read=XPU_REG_MAC_ADDR_LOW_read; xpu_api->XPU_REG_MAC_ADDR_HIGH_write=XPU_REG_MAC_ADDR_HIGH_write; xpu_api->XPU_REG_MAC_ADDR_HIGH_read=XPU_REG_MAC_ADDR_HIGH_read; xpu_api->XPU_REG_FILTER_FLAG_write=XPU_REG_FILTER_FLAG_write; xpu_api->XPU_REG_FILTER_FLAG_read=XPU_REG_FILTER_FLAG_read; xpu_api->XPU_REG_CTS_TO_RTS_CONFIG_write=XPU_REG_CTS_TO_RTS_CONFIG_write; xpu_api->XPU_REG_CTS_TO_RTS_CONFIG_read=XPU_REG_CTS_TO_RTS_CONFIG_read; xpu_api->XPU_REG_BSSID_FILTER_LOW_write=XPU_REG_BSSID_FILTER_LOW_write; xpu_api->XPU_REG_BSSID_FILTER_LOW_read=XPU_REG_BSSID_FILTER_LOW_read; xpu_api->XPU_REG_BSSID_FILTER_HIGH_write=XPU_REG_BSSID_FILTER_HIGH_write; xpu_api->XPU_REG_BSSID_FILTER_HIGH_read=XPU_REG_BSSID_FILTER_HIGH_read; xpu_api->XPU_REG_BAND_CHANNEL_write=XPU_REG_BAND_CHANNEL_write; xpu_api->XPU_REG_BAND_CHANNEL_read=XPU_REG_BAND_CHANNEL_read; xpu_api->XPU_REG_TRX_STATUS_read=XPU_REG_TRX_STATUS_read; xpu_api->XPU_REG_TX_RESULT_read=XPU_REG_TX_RESULT_read; xpu_api->XPU_REG_TSF_RUNTIME_VAL_LOW_read=XPU_REG_TSF_RUNTIME_VAL_LOW_read; xpu_api->XPU_REG_TSF_RUNTIME_VAL_HIGH_read=XPU_REG_TSF_RUNTIME_VAL_HIGH_read; xpu_api->XPU_REG_TSF_LOAD_VAL_LOW_write=XPU_REG_TSF_LOAD_VAL_LOW_write; xpu_api->XPU_REG_TSF_LOAD_VAL_HIGH_write=XPU_REG_TSF_LOAD_VAL_HIGH_write; xpu_api->XPU_REG_TSF_LOAD_VAL_write=XPU_REG_TSF_LOAD_VAL_write; xpu_api->XPU_REG_FC_DI_read=XPU_REG_FC_DI_read; xpu_api->XPU_REG_ADDR1_LOW_read=XPU_REG_ADDR1_LOW_read; xpu_api->XPU_REG_ADDR1_HIGH_read=XPU_REG_ADDR1_HIGH_read; xpu_api->XPU_REG_ADDR2_LOW_read=XPU_REG_ADDR2_LOW_read; xpu_api->XPU_REG_ADDR2_HIGH_read=XPU_REG_ADDR2_HIGH_read; xpu_api->XPU_REG_LBT_TH_write=XPU_REG_LBT_TH_write; xpu_api->XPU_REG_LBT_TH_read=XPU_REG_LBT_TH_read; xpu_api->XPU_REG_RSSI_DB_CFG_read=XPU_REG_RSSI_DB_CFG_read; xpu_api->XPU_REG_RSSI_DB_CFG_write=XPU_REG_RSSI_DB_CFG_write; xpu_api->XPU_REG_CSMA_DEBUG_write=XPU_REG_CSMA_DEBUG_write; xpu_api->XPU_REG_CSMA_DEBUG_read=XPU_REG_CSMA_DEBUG_read; xpu_api->XPU_REG_CSMA_CFG_write=XPU_REG_CSMA_CFG_write; xpu_api->XPU_REG_CSMA_CFG_read=XPU_REG_CSMA_CFG_read; xpu_api->XPU_REG_SLICE_COUNT_TOTAL0_write=XPU_REG_SLICE_COUNT_TOTAL0_write; xpu_api->XPU_REG_SLICE_COUNT_START0_write=XPU_REG_SLICE_COUNT_START0_write; xpu_api->XPU_REG_SLICE_COUNT_END0_write=XPU_REG_SLICE_COUNT_END0_write; xpu_api->XPU_REG_SLICE_COUNT_TOTAL1_write=XPU_REG_SLICE_COUNT_TOTAL1_write; xpu_api->XPU_REG_SLICE_COUNT_START1_write=XPU_REG_SLICE_COUNT_START1_write; xpu_api->XPU_REG_SLICE_COUNT_END1_write=XPU_REG_SLICE_COUNT_END1_write; xpu_api->XPU_REG_SLICE_COUNT_TOTAL0_read=XPU_REG_SLICE_COUNT_TOTAL0_read; xpu_api->XPU_REG_SLICE_COUNT_START0_read=XPU_REG_SLICE_COUNT_START0_read; xpu_api->XPU_REG_SLICE_COUNT_END0_read=XPU_REG_SLICE_COUNT_END0_read; xpu_api->XPU_REG_SLICE_COUNT_TOTAL1_read=XPU_REG_SLICE_COUNT_TOTAL1_read; xpu_api->XPU_REG_SLICE_COUNT_START1_read=XPU_REG_SLICE_COUNT_START1_read; xpu_api->XPU_REG_SLICE_COUNT_END1_read=XPU_REG_SLICE_COUNT_END1_read; xpu_api->XPU_REG_BB_RF_DELAY_write=XPU_REG_BB_RF_DELAY_write; xpu_api->XPU_REG_MAX_NUM_RETRANS_write=XPU_REG_MAX_NUM_RETRANS_write; xpu_api->XPU_REG_MAC_ADDR_write=XPU_REG_MAC_ADDR_write; /* Request and map I/O memory */ io = platform_get_resource(pdev, IORESOURCE_MEM, 0); base_addr = devm_ioremap_resource(&pdev->dev, io); if (IS_ERR(base_addr)) return PTR_ERR(base_addr); printk("%s dev_probe io start 0x%08x end 0x%08x name %s flags 0x%08x desc 0x%08x\n", xpu_compatible_str,io->start,io->end,io->name,(u32)io->flags,(u32)io->desc); printk("%s dev_probe base_addr 0x%08x\n", xpu_compatible_str,(u32)base_addr); printk("%s dev_probe xpu_driver_api_inst 0x%08x\n", xpu_compatible_str, (u32)&xpu_driver_api_inst); printk("%s dev_probe xpu_api 0x%08x\n", xpu_compatible_str, (u32)xpu_api); printk("%s dev_probe reset tsf timer\n", xpu_compatible_str); xpu_api->XPU_REG_TSF_LOAD_VAL_write(0,0); test_us0 = xpu_api->XPU_REG_TSF_RUNTIME_VAL_LOW_read(); mdelay(33); test_us1 = xpu_api->XPU_REG_TSF_RUNTIME_VAL_LOW_read(); mdelay(67); test_us2 = xpu_api->XPU_REG_TSF_RUNTIME_VAL_LOW_read(); printk("%s dev_probe XPU_REG_TSF_RUNTIME_VAL_LOW_read %d %d %dus\n", xpu_compatible_str, test_us0, test_us1, test_us2); printk("%s dev_probe succeed!\n", xpu_compatible_str); err = hw_init(XPU_NORMAL); return err; } static int dev_remove(struct platform_device *pdev) { printk("\n"); printk("%s dev_remove base_addr 0x%08x\n", xpu_compatible_str,(u32)base_addr); printk("%s dev_remove xpu_driver_api_inst 0x%08x\n", xpu_compatible_str, (u32)&xpu_driver_api_inst); printk("%s dev_remove xpu_api 0x%08x\n", xpu_compatible_str, (u32)xpu_api); printk("%s dev_remove succeed!\n", xpu_compatible_str); return 0; } static struct platform_driver dev_driver = { .driver = { .name = "sdr,xpu", .owner = THIS_MODULE, .of_match_table = dev_of_ids, }, .probe = dev_probe, .remove = dev_remove, }; module_platform_driver(dev_driver); MODULE_AUTHOR("Xianjun Jiao"); MODULE_DESCRIPTION("sdr,xpu"); MODULE_LICENSE("GPL v2");