FreeCalypso > hg > fc-selenite
view src/cs/services/etm/etm_tmcore.c @ 192:4f40ae165be4
abb.c & init.c: sync with Magnetite for Luna additions
These Luna target-specific additions are conditionalized on CONFIG_TARGET_LUNA,
a C preprocessor symbol that will never be defined in Selenite, hence this
change has exactly zero impact on FC Selenite. However, they are being pulled
in as a sync in order to keep the diff between Magnetite and Selenite to a
minimum; keeping this diff to a minimum increases our opportunities for
possible evolution of future FC firmwares.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Sat, 23 May 2020 07:03:46 +0000 |
parents | b6a5e36de839 |
children |
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/******************************************************************************** * Enhanced TestMode (ETM) * @file tmcore.c * * @author Kim T. Peteren (ktp@ti.com) * @version 0.1 * * * History: * * Date Modification * ------------------------------------ * 16/06/2003 Creation * 02/07/2003 Removed l1_config.TestMode check from CODEC Write * 17/03/2004 Updated etm_version * 30/03/2004 Updated etm_dieID_read() func. regarding get die id for 16 bits * instead of 8 bits. * * (C) Copyright 2003 by Texas Instruments Incorporated, All Rights Reserved *********************************************************************************/ #include "rv/rv_defined_swe.h" #include "rv/rv_general.h" #include "etm/etm.h" #include "etm/etm_api.h" #include "etm/etm_trace.h" #include "etm/etm_version.h" #include "abb/abb.h" #include "spi/spi_drv.h" extern void tr_etm_init(unsigned int mask); // Version of the ETM CORE module // See the file etm_version.h /****************************************************************************** * DIE ID settings *****************************************************************************/ #define BE_STREAM_TO_ARRAY(a, p, l) {register INT32 i; for (i = 0; i < l; i++) a[i] = *(UINT8*)(p)++;} /* DIE ID register */ #if ((CHIPSET == 8) || (CHIPSET == 10) || (CHIPSET == 11)) //For D-Sample: $CHIPSET = 8 (=10 for D-sample AMR, 11 for GSMLITE). #define DIE_ID_REG (MEM_DEV_ID0 | 0xF010) //+ 0xFFFEF010 for Calypso #else #if (CHIPSET == 12) //For E-Sample: $CHIPSET = 12. #define DIE_ID_REG (0xFFFE0000 | 0xF004) //+ 0xFFFEF004 for Calypso Plus #endif #endif /* DIE ID SIZE is 4 words (16 bits)long */ #define DIE_ID_SIZE 4 //Copied from rv_general.h: //#define BE_STREAM_TO_ARRAY(a, p, l) {register INT32 i; for (i = 0; i < l; i++) a[i] = *(UINT16*)(p)++;} /****************************************************************************** * Internal prototypes *****************************************************************************/ T_ETM_PKT *etm_core_setup(uint8 fid); int etm_core(uint8 *buf, int size); /****************************************************************************** * Register the Core Module to the ETM database *****************************************************************************/ int etm_core_init(void) { int result; result = etm_register("CORE", ETM_CORE, 0, 0, etm_core); return result; } /****************************************************************************** * Memory read/write Functions *****************************************************************************/ // Describe the payload of the mem protocol !!!!!! // |--type(1)-|--partnum(1)-|--addr(4)-|--data(?)-| int etm_mem(T_ETM_PKT *pkt, uint8 *buf) { int num, unitsize, error; uint8 type, param; uint8 *mem8; uint16 *mem16; uint32 *mem32; uint32 addr, tmp; static unsigned char test_buf[64]; param = unitsize = *buf & 0x3; if (unitsize == 0) unitsize = 4; type = *buf & 0x10; buf++; num = *buf++; addr = etm_get32(buf); buf += 4; tr_etm(TgTrCore, "ETM CORE: _mem: type(0x%x) addr(0x%x) partnum(%d)", type, addr, num); // Put 'parameter' in return packet if ((error = etm_pkt_put8(pkt, param)) < 0) { return error; } switch (type) { case 0: // READ(0x00) switch (unitsize) { case 1: mem8 = (uint8 *) addr; while (num--) { if ((error = etm_pkt_put8(pkt, *mem8++)) < 0) break; } break; case 2: mem16 = (uint16 *) addr; while (num--) { if ((error = etm_pkt_put16(pkt, *mem16++)) < 0) break; } break; case 4: mem32 = (uint32 *) addr; while (num--) { if ((error = etm_pkt_put32(pkt, *mem32++)) < 0) break; } break; } break; case 16: // WRITE(0x10) switch (unitsize) { case 1: mem8 = (uint8 *) addr; while (num--) { *mem8++ = etm_get8(buf); buf += 1; } break; case 2: mem16 = (uint16 *) addr; while (num--) { *mem16++ = tmp = etm_get16(buf); buf += 2; } break; case 4: mem32 = (uint32 *) addr; while (num--) { *mem32++ = etm_get32(buf); buf += 4; } break; } break; default: return ETM_NOSYS; } if (error < 0) return error; return ETM_OK; } /****************************************************************************** * CODEC Functions *****************************************************************************/ // ETM sends both page value and register address in one byte. // Bit field is: PPPR RRRR // where P = page bit, R = register address bits and X = don't care bits. int etm_codec_write(T_ETM_PKT *pkt, uint8 *buf) { extern void ABB_Write_Register_on_page(SYS_UWORD16 page, SYS_UWORD16 reg_id, SYS_UWORD16 value); uint16 page, reg, data; int result, reg_data; reg_data = *buf++; if ((result = etm_pkt_put8(pkt, reg_data)) < 0) return result; page = (reg_data >> 5) & 0x3; reg = reg_data & 0x1F; data = etm_get16(buf); tr_etm(TgTrCore, "ETM CORE: _codec_write: page(%d) reg(%d) data(0x%x)", page, reg, (data & 0x3ff)); if (page > 7 && reg > 32) return ETM_INVAL; else { // The function below expects a 1 for page 0 and a 2 for page 1. // The register address value is left-shifted by 1 since LSB is read/write command bit. // The value is written in the 10 MSB's of register. ABB_Write_Register_on_page(page + 1, reg << 1, (data & 0x3ff)); } return ETM_OK; } int etm_codec_read(T_ETM_PKT *pkt, uint8 *buf) { extern SYS_UWORD16 ABB_Read_Register_on_page(SYS_UWORD16 page, SYS_UWORD16 reg_id); volatile uint16 value; uint16 page, reg; int result, reg_data; reg_data = *buf; if ((result = etm_pkt_put8(pkt, reg_data)) < 0) return result; page = (reg_data >> 5) & 0x3; reg = reg_data & 0x1F; if (page > 7 && reg > 32) return ETM_INVAL; // The function below expects a 1 for page 0 and a 2 for page 1. // The register value is left-shifted by 1 since LSB is read/write command bit. value = ABB_Read_Register_on_page(page + 1, (reg << 1)); tr_etm(TgTrCore, "ETM CORE: _codec_read: page(%d) reg(%d) value(0x%x)", page, reg, value); result = etm_pkt_put16(pkt, value); return result; } /****************************************************************************** * Echo and Reset Functions *****************************************************************************/ //structur of data dl: |delay|recvsize|num| = 3x2 bytes int etm_echo(T_ETM_PKT *pkt, uint8 *data) { int delay, sendsize, i, num, count; tr_etm(TgTrCore, "etm_echo:"); delay = etm_get16(data); data += 2; sendsize = etm_get16(data); if (sendsize > 240) return ETM_INVAL; data += 2; num = etm_get16(data); tr_etm(TgTrCore, "ETM CORE: _echo: delay(%d) sendsize(%d) num(%d)", delay, sendsize, num); if (delay > 0) { rvf_delay((delay + 32) * 14 / 64); } for (i = 0; i < sendsize; i++) { pkt->data[i+1] = i; // data[0] = fid } pkt->size = sendsize; return ETM_OK; } int etm_reset(void) { // The reset code is taken form Fluid->cmd.c int i; tr_etm(TgTrCore, "ETM CORE: _reset: Target is Reset"); // Setup watchdog timer and let it timeout to make a reset *(volatile uint16*) 0xfffff804 = 0xFFFF; // Timer to watchdog *(volatile uint16*) 0xfffff800 = 0x0080; // Start timer // Apparently works it only if we read this register? i = *(volatile uint16*) 0xfffff802; *(volatile uint16*) 0xfffff802 = 0x0001; // Load timer return ETM_OK; } /****************************************************************************** * Set Test Controls *****************************************************************************/ int etm_debug(T_ETM_PKT *pkt, uint8 *buf) { int type, error, data; static char *p; type = *buf & 0x0F; buf++; data = etm_get32(buf); tr_etm(TgTrCore, "ETM CORE: _debug: type(%d) data(0x%x)", type, data); switch (type) { case 0: // (0x00) Allocate Test Buffer if ((p = etm_malloc(data)) == NULL) error = ETM_NOMEM; error = etm_pkt_put32(pkt, (int) p); break; case 1: // (0x01) Free Test Buffer. p = (char *) data; etm_free(p); break; case 2: // (0x02) Set ETM Trace mask tr_etm_init(data); break; case 3: // (0x03) Set read all mem banks stat rvf_dump_mem(); rvf_dump_pool(); rvf_dump_tasks(); break; default: error = ETM_NOSYS; } if (error < 0) return error; return ETM_OK; } /****************************************************************************** * Get Version of ... *****************************************************************************/ // This is in development ... int etm_version(T_ETM_PKT *pkt, uint8 *buf) { extern uint16 etm_audio_revision; extern uint16 etm_task_revision; int error, fid, ffs_tm_version; volatile int revision = 0; T_VERSION *l1s_version; fid = etm_get32(buf); tr_etm(TgTrCore, "ETM CORE: _version: fid(0x%x)", fid); l1s_version = (T_VERSION*) l1s_get_version(); switch (fid) { // Code Versions related to ETM modules case SW_REV_ETM_CORE: error = etm_pkt_put32(pkt, ETM_CORE_VERSION); break; case SW_REV_ETM_AUDIO: error = etm_pkt_put32(pkt, ETM_AUDIO_VERSION); break; // case SW_REV_ETM_FFS: // ffs_query(Q_FFS_TM_VERSION, &ffs_tm_version); // error = etm_pkt_put32(pkt, ffs_tm_version); break; // case SW_REV_ETM_RF: // Layer1 Testmode Version // error = etm_pkt_put32(pkt, TESTMODEVERSION); // break; case SW_REV_ETM_PWR: error = etm_pkt_put32(pkt, ETM_PWR_VERSION); break; case SW_REV_ETM_BT: error = ETM_NOSYS; break; case SW_REV_ETM_TASK: error = etm_pkt_put32(pkt, ETM_VERSION); break; case SW_REV_ETM_API: error = etm_pkt_put32(pkt, ETM_API_VERSION); break; // Code Versions related to L1, see in l1_defty.h // Get the version on this way "revision = l1s.version.dsp_code_version;" // doesn't work because of struct aligment -> compile flag -mw !!!! case SW_DSP_CODE_VERSION: revision = ((T_VERSION*) l1s_version)->dsp_code_version; error = etm_pkt_put32(pkt, revision); break; case SW_DSP_PATCH_VERSION: revision = ((T_VERSION*) l1s_version)->dsp_patch_version; error = etm_pkt_put32(pkt, revision); break; case SW_MCU_TCS_PROGRAM_RELEASE: revision = ((T_VERSION*) l1s_version)->mcu_tcs_program_release; error = etm_pkt_put32(pkt, revision); break; case SW_MCU_TCS_OFFICIAL: // This version allso identify version of Layer1 revision = ((T_VERSION*) l1s_version)->mcu_tcs_official; error = etm_pkt_put32(pkt, revision); break; case SW_MCU_TCS_INTERNAL: revision = ((T_VERSION*) l1s_version)->mcu_tcs_internal; error = etm_pkt_put32(pkt, revision); break; case SW_MCU_TM_VERSION: revision = ((T_VERSION*) l1s_version)->mcu_tm_version; error = etm_pkt_put32(pkt, revision); break; default: error = ETM_NOSYS; } tr_etm(TgTrCore, "ETM CORE: _version: version(%d)", revision); if (error < 0) return error; return ETM_OK; } /****************************************************************************** * Function for reading the Die-ID from base band processor. *****************************************************************************/ int etm_dieID_read(T_ETM_PKT *pkt, uint8 *inbuf) { T_RV_RET result; int8 byteCount; UINT16 dieID[DIE_ID_SIZE]; int16 index; volatile UINT16 *reg_p = (UINT16 *) DIE_ID_REG; tr_etm(TgTrCore, "ETM CORE: _dieID_read: started - Die-ID address(0x%x)", DIE_ID_REG); BE_STREAM_TO_ARRAY(dieID, reg_p, DIE_ID_SIZE); for (byteCount = 0; byteCount < DIE_ID_SIZE; byteCount++) { tr_etm(TgTrCore, "ETM CORE: Die-ID[%i] Byte Read(0x%x)", byteCount, (UINT16)dieID[byteCount]); result = etm_pkt_put16(pkt, (UINT8)(((dieID[byteCount]) & 0xFFFF))); if (result < 0) return result; } return ETM_OK; } /****************************************************************************** * ETM CORE Main Function - Module *****************************************************************************/ int etm_core(uint8 *buf, int size) { // Structur of protocol data dl-link: |fid|index|data| uint8 mid; uint8 fid; int error = 0; T_ETM_PKT *pkt = NULL; fid = *buf++; tr_etm(TgTrCore, "ETM CORE: _core: fid(%c):", fid); /* Create TestMode return Packet */ if ((pkt = (T_ETM_PKT *) etm_malloc(sizeof(T_ETM_PKT))) == NULL) { return ETM_NOMEM; } // Init. of return packet pkt->mid = ETM_CORE; pkt->status = ETM_OK; pkt->size = 0; pkt->index = 0; etm_pkt_put8(pkt, fid); switch (fid) { #ifdef RVM_ATP_SWE case 0x60: // old 'G' error = etm_at(pkt, (char *) buf); break; #endif case 0x61: // old 'M' error = etm_mem(pkt, buf); break; case 0x62: // old 'E' error = etm_echo(pkt, buf); break; case 0x63: // old 'R' error = etm_reset(); break; case 0x64: // old 'T' error = etm_debug(pkt, buf); break; case 0x65: // old 'V' error = etm_version(pkt, buf); break; case 0x66: // old 'C' error = etm_codec_read(pkt, buf); break; case 0x67: // old 'D' error = etm_codec_write(pkt, buf); break; case 0x68: // old 'd' error = etm_dieID_read(pkt, buf); break; default: tr_etm(TgTrCore,"ETM CORE: _core: fid ERROR"); error = ETM_NOSYS; break; } if (error < 0) { tr_etm(TgTrCore,"ETM CORE: _core: FAILED"); pkt->status = -error; } // etm_at(): send func. is controlled by primitive if (fid == 'G' && error >= RV_OK) {} else etm_pkt_send(pkt); etm_free(pkt); return ETM_OK; }