FreeCalypso > hg > fc-magnetite
view src/g23m-fad/ra/ra_rlp.c @ 629:3231dd9b38c1
armio.c: make GPIOs 8 & 13 outputs driving 1 on all "classic" targets
Calypso GPIOs 8 & 13 are pinmuxed with MCUEN1 & MCUEN2, respectively,
and on powerup these pins are MCUEN, i.e., outputs driving 1. TI's code
for C-Sample and earlier turns them into GPIOs configured as outputs also
driving 1 - so far, so good - but TI's code for BOARD 41 (which covers
D-Sample, Leonardo and all real world Calypso devices derived from the
latter) switches them from MCUEN to GPIOs, but then leaves them as inputs.
Given that the hardware powerup state of these two pins is outputs driving 1,
every Calypso board design MUST be compatible with such driving; typically
these GPIO signals will be either unused and unconnected or connected as
outputs driving some peripheral. Turning these pins into GPIO inputs will
result in floating inputs on every reasonably-wired board, thus I am
convinced that this configuration is nothing but a bug on the part of
whoever wrote this code at TI.
This floating input bug had already been fixed earlier for GTA modem and
FCDEV3B targets; the present change makes the fix unconditional for all
"classic" targets. The newly affected targets are D-Sample, Leonardo,
Tango and GTM900.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Thu, 02 Jan 2020 05:38:26 +0000 |
| parents | 90eb61ecd093 |
| children |
line wrap: on
line source
/* +----------------------------------------------------------------------------- | Project : GSM-F&D (8411) | Modul : RA_RLP +----------------------------------------------------------------------------- | Copyright 2002 Texas Instruments Berlin, AG | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments Berlin, AG | The receipt of or possession of this file does not convey | any rights to reproduce or disclose its contents or to | manufacture, use, or sell anything it may describe, in | whole, or in part, without the specific written consent of | Texas Instruments Berlin, AG. +----------------------------------------------------------------------------- | Purpose : This Modul defines the functions for the non-transparent | data model (RLP) for the component RA of the mobile | station +----------------------------------------------------------------------------- */ #ifndef RA_RLP_C #define RA_RLP_C #endif #define ENTITY_RA /*==== INCLUDES ===================================================*/ #include <string.h> #include "typedefs.h" #include "vsi.h" #include "macdef.h" #include "pconst.cdg" #include "custom.h" #include "gsm.h" #include "cnf_ra.h" #include "prim.h" #include "pei.h" #include "tok.h" #include "ccdapi.h" #include "ra.h" /*==== CONST ======================================================*/ /*==== TYPES ======================================================*/ /*==== VARIABLES ==================================================*/ /*==== FUNCTIONS ==================================================*/ /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_RLP | | STATE : code ROUTINE : rlp_init | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void rlp_init(void) { TRACE_FUNCTION("rlp_init()"); memset(ra_data->rlp, 0, sizeof(T_RLP)); hCommRLP = vsi_c_open ( VSI_CALLER RLP_NAME ); hCommMMI = vsi_c_open ( VSI_CALLER ACI_NAME ); } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_RLP | | STATE : code ROUTINE : rlp_idle | +--------------------------------------------------------------------+ PURPOSE : IDLE processing fpr uplink and downlink non-transparent mode */ GLOBAL void rlp_idle(void) { TRACE_FUNCTION("rlp_idle()"); } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_RLP | | STATE : code ROUTINE : rlp_ul_null | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void rlp_ul_null(void) { T_RLP *drlp = ra_data->rlp; UBYTE i; TRACE_FUNCTION("rlp_ul_null()"); if (ra_data->activated) { #ifdef TRACE_RA_RLP drlp->fcs_error = 0L; #endif /* * setup the communication parameters */ shm_set_dsp_value (conf_b_itc, V_ITC_DATA); shm_set_dsp_value (conf_b_ce, V_CE_NON_TRANSP); switch (ra_data->tra_rate) { case TRA_FULLRATE_14400: shm_set_dsp_value (conf_b_ur, V_UR_14400); shm_set_dsp_value (conf_b_ct, V_CT_FR); break; case TRA_FULLRATE_9600: shm_set_dsp_value (conf_b_ur, V_UR_9600); shm_set_dsp_value (conf_b_ct, V_CT_FR); break; case TRA_FULLRATE_4800: shm_set_dsp_value (conf_b_ur, V_UR_4800); shm_set_dsp_value (conf_b_ct, V_CT_FR); break; case TRA_HALFRATE_4800: shm_set_dsp_value (conf_b_ur, V_UR_4800); shm_set_dsp_value (conf_b_ct, V_CT_HR); break; default: break; } shm_set_dsp_value (ntu_M1, 0); shm_set_dsp_value (ntu_M2, 0); shm_set_dsp_value (ntu_empty, 1); shm_set_dsp_value (ntu_byte_cnt, 2); /* * initialize the non-transparent mode data */ drlp->ul_data_pending = FALSE; drlp->m1 = 0; ra_data->ra_data_ind.fr_type = FR_RLP; ra_data->ra_data_ind.sdu.o_buf = 0; ra_data->ra_data_ind.sdu.l_buf = 0; ra_data->ra_ready_ind[0].req_frames = 1; cl_ribu_init(&drlp->ulq, RLP_UL_QSIZE); for (i = 0; i < drlp->ulq.depth; i++) { cl_set_frame_desc_0(&drlp->ul_frame_desc[i], NULL, 0); } cl_set_frame_desc_0(&ra_data->rlp->dl_frame_desc, NULL, 0); shm_set_dsp_value (act_b_init, 1); INIT_STATE (KER, RLP_INIT_L1); #ifdef HO_WORKAROUND /* rlp_ul_null */ _act_d_ra_conf = *ra_data->shm.shm_addr[d_ra_conf]; TRACE_EVENT("d_ra_conf saved"); #endif } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_RLP | | STATE : code ROUTINE : rlp_ul_init_l1 | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void rlp_ul_init_l1(void) { TRACE_FUNCTION("rlp_ul_init_l1()"); if (shm_get_dsp_value (act_b_init) EQ 0) { /* * initialisation finished -> enter the data transmission state */ l1i_ra_activate_cnf(); SET_STATE (KER, RLP_DATA_TRANS); } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_RLP | | STATE : code ROUTINE : rlp_ul_data_trans | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void rlp_ul_data_trans(void) { T_RLP *drlp = ra_data->rlp; TRACE_FUNCTION("rlp_ul_data_trans()"); if (drlp->ul_data_pending) /* a frame is ready to be sent */ { USHORT len = 0; switch (ra_data->tra_rate) { case TRA_FULLRATE_9600: case TRA_HALFRATE_4800: len = NT_DATA_SIZE; drlp->ul_data_pending = FALSE; break; case TRA_FULLRATE_4800: /* S844: 1=1st half, 0=2nd half */ if (shm_get_dsp_value (act_b_f48blk_ul) EQ 1) { TRACE_FUNCTION("send 4800 first half"); len = NT_DATA_SIZE_4800_FR_A; drlp->ul_48_first_half_sent = TRUE; } else { if (drlp->ul_48_first_half_sent) { TRACE_FUNCTION("send 4800 second half"); len = NT_DATA_SIZE_4800_FR_B; drlp->ul_data_pending = FALSE; drlp->ul_frame_desc[drlp->ulq.ri].Adr[0] += NT_DATA_SIZE_4800_FR_A; } else { TRACE_FUNCTION("wait for 4800 first half"); len = 0; } } break; case TRA_FULLRATE_14400: shm_set_dsp_value (ntu_M1, drlp->m1); /* S844: 0 = first half, 1 = second half */ if (drlp->m1 EQ 0) { len = NT_DATA_SIZE_14400_A; drlp->m1 = 1; } else { len = NT_DATA_SIZE_14400_B; drlp->ul_data_pending = FALSE; drlp->ul_frame_desc[drlp->ulq.ri].Adr[0] += NT_DATA_SIZE_14400_A; } break; } if (len > 0) { shm_set_dsp_buffer(&drlp->ul_frame_desc[drlp->ulq.ri], ra_data->shm.shm_addr[adr_ntu_data]+wof_ntu_data, 0, len); shm_set_dsp_value (ntu_empty, 0); shm_set_dsp_value (ntu_byte_cnt, (len+2)); if (!drlp->ul_data_pending) { cl_ribu_read_index(&drlp->ulq); /* PZ 22.7.99 */ drlp->ul_data_pending = (drlp->ulq.ri NEQ drlp->ulq.wi); /* PZ 22.7.99 */ } } else { shm_set_dsp_value (ntu_M1, 0); shm_set_dsp_value (ntu_empty, 1); shm_set_dsp_value (ntu_byte_cnt, 2); } } else { /* no frame is ready to be sent */ shm_set_dsp_value (ntu_M1, 0); shm_set_dsp_value (ntu_empty, 1); shm_set_dsp_value (ntu_byte_cnt, 2); } if (!drlp->ul_data_pending) { l1i_ra_ready_ind(hCommRLP, 0); } } /* +--------------------------------------------------------------------+ | PROJECT : GSM-F&D (8411) MODULE : RA_RLP | | STATE : code ROUTINE : rlp_dl_data_trans | +--------------------------------------------------------------------+ PURPOSE : */ GLOBAL void rlp_dl_data_trans(void) { BOOL frame_complete = FALSE; TRACE_FUNCTION("rlp_dl_data_trans()"); #ifdef HO_WORKAROUND /* rlp_dl_data_trans */ if (*ra_data->shm.shm_addr[d_ra_conf] NEQ _act_d_ra_conf) { *ra_data->shm.shm_addr[d_ra_conf] = _act_d_ra_conf; /* rlp_dl_data_trans */ TRACE_EVENT("HO_REFRESH rlp_dl_data_trans"); } #endif /* * read out the received downlink data */ if (shm_get_dsp_value (ntd_byte_cnt) > 0) { USHORT len = 0; switch (ra_data->tra_rate) { case TRA_FULLRATE_9600: case TRA_HALFRATE_4800: if (shm_get_dsp_value (ntd_fcs_ok) EQ 0) { frame_complete = TRUE; len = NT_DATA_SIZE; #ifdef _SIMULATION_ cl_set_frame_desc_0(&ra_data->rlp->dl_frame_desc, ra_data->rlp->dl_buf, NT_DATA_SIZE); ra_data->ra_data_ind.sdu.l_buf = NT_DATA_SIZE << 3; #else rlp_rbm_get_next_buffer(&ra_data->rlp->dl_frame_desc); #endif } else { #ifdef TRACE_RA_RLP TRACE_EVENT("FCS-Error"); ra_data->rlp->fcs_error++; #endif frame_complete = FALSE; len = 0; } break; case TRA_FULLRATE_4800: /* S844: 0=1st half, 1=2nd half */ if (shm_get_dsp_value (act_b_f48blk_dl) EQ 0) { len = NT_DATA_SIZE_4800_FR_A; frame_complete = FALSE; #ifdef _SIMULATION_ cl_set_frame_desc_0(&ra_data->rlp->dl_frame_desc, ra_data->rlp->dl_buf, NT_DATA_SIZE_4800_FR_A+NT_DATA_SIZE_4800_FR_B); ra_data->ra_data_ind.sdu.l_buf = (NT_DATA_SIZE_4800_FR_A+NT_DATA_SIZE_4800_FR_B) << 3; #else rlp_rbm_get_next_buffer(&ra_data->rlp->dl_frame_desc); #endif } else if (shm_get_dsp_value (ntd_fcs_ok) EQ 0) { frame_complete = TRUE; len = NT_DATA_SIZE_4800_FR_B; ra_data->rlp->dl_frame_desc.Adr[0] += NT_DATA_SIZE_4800_FR_A; } else { #ifdef TRACE_RA_RLP TRACE_EVENT("FCS-Error"); ra_data->rlp->fcs_error++; #endif frame_complete = FALSE; len = 0; } break; case TRA_FULLRATE_14400: /* S844: 0 = first half, 1 = second half */ if (shm_get_dsp_value (ntd_M1) EQ 0) { frame_complete = FALSE; len = NT_DATA_SIZE_14400_A; #ifdef _SIMULATION_ cl_set_frame_desc_0(&ra_data->rlp->dl_frame_desc, ra_data->rlp->dl_buf, NT_DATA_SIZE_14400_A + NT_DATA_SIZE_14400_B); ra_data->ra_data_ind.sdu.l_buf = (NT_DATA_SIZE_14400_A + NT_DATA_SIZE_14400_B) << 3; #else rlp_rbm_get_next_buffer(&ra_data->rlp->dl_frame_desc); #endif } else if (shm_get_dsp_value (ntd_fcs_ok) EQ 0) { frame_complete = TRUE; len = NT_DATA_SIZE_14400_B; ra_data->rlp->dl_frame_desc.Adr[0] += NT_DATA_SIZE_14400_A; } else { #ifdef TRACE_RA_RLP TRACE_EVENT("FCS-Error"); ra_data->rlp->fcs_error++; #endif frame_complete = FALSE; len = 0; } break; } if (len > 0) { shm_get_dsp_buffer(&ra_data->rlp->dl_frame_desc, ra_data->shm.shm_addr[adr_ntd_data]+wof_ntd_data, len); shm_set_dsp_value (ntd_byte_cnt, 0); if (frame_complete) { l1i_ra_data_ind(hCommRLP); } } } }