/** * Copyright (C) 2008, Creative Technology Ltd. All Rights Reserved. * * This source file is released under GPL v2 license (no other versions). * See the COPYING file included in the main directory of this source * distribution for the license terms and conditions. * * @File ctdaio.c * * @Brief * This file contains the implementation of Digital Audio Input Output * resource management object. * * @Author Liu Chun * @Date May 23 2008 * */ #include "ctdaio.h" #include "cthardware.h" #include "ctimap.h" #include #include #define DAIO_OUT_MAX SPDIFOO struct daio_usage { unsigned short data; }; struct daio_rsc_idx { unsigned short left; unsigned short right; }; static struct daio_rsc_idx idx_20k1[NUM_DAIOTYP] = { [LINEO1] = {.left = 0x00, .right = 0x01}, [LINEO2] = {.left = 0x18, .right = 0x19}, [LINEO3] = {.left = 0x08, .right = 0x09}, [LINEO4] = {.left = 0x10, .right = 0x11}, [LINEIM] = {.left = 0x1b5, .right = 0x1bd}, [SPDIFOO] = {.left = 0x20, .right = 0x21}, [SPDIFIO] = {.left = 0x15, .right = 0x1d}, [SPDIFI1] = {.left = 0x95, .right = 0x9d}, }; static struct daio_rsc_idx idx_20k2[NUM_DAIOTYP] = { [LINEO1] = {.left = 0x40, .right = 0x41}, [LINEO2] = {.left = 0x60, .right = 0x61}, [LINEO3] = {.left = 0x50, .right = 0x51}, [LINEO4] = {.left = 0x70, .right = 0x71}, [LINEIM] = {.left = 0x45, .right = 0xc5}, [MIC] = {.left = 0x55, .right = 0xd5}, [SPDIFOO] = {.left = 0x00, .right = 0x01}, [SPDIFIO] = {.left = 0x05, .right = 0x85}, }; static int daio_master(struct rsc *rsc) { /* Actually, this is not the resource index of DAIO. * For DAO, it is the input mapper index. And, for DAI, * it is the output time-slot index. */ return rsc->conj = rsc->idx; } static int daio_index(const struct rsc *rsc) { return rsc->conj; } static int daio_out_next_conj(struct rsc *rsc) { return rsc->conj += 2; } static int daio_in_next_conj_20k1(struct rsc *rsc) { return rsc->conj += 0x200; } static int daio_in_next_conj_20k2(struct rsc *rsc) { return rsc->conj += 0x100; } static struct rsc_ops daio_out_rsc_ops = { .master = daio_master, .next_conj = daio_out_next_conj, .index = daio_index, .output_slot = NULL, }; static struct rsc_ops daio_in_rsc_ops_20k1 = { .master = daio_master, .next_conj = daio_in_next_conj_20k1, .index = NULL, .output_slot = daio_index, }; static struct rsc_ops daio_in_rsc_ops_20k2 = { .master = daio_master, .next_conj = daio_in_next_conj_20k2, .index = NULL, .output_slot = daio_index, }; static unsigned int daio_device_index(enum DAIOTYP type, struct hw *hw) { switch (hw->chip_type) { case ATC20K1: switch (type) { case SPDIFOO: return 0; case SPDIFIO: return 0; case SPDIFI1: return 1; case LINEO1: return 4; case LINEO2: return 7; case LINEO3: return 5; case LINEO4: return 6; case LINEIM: return 7; default: return -EINVAL; } case ATC20K2: switch (type) { case SPDIFOO: return 0; case SPDIFIO: return 0; case LINEO1: return 4; case LINEO2: return 7; case LINEO3: return 5; case LINEO4: return 6; case LINEIM: return 4; case MIC: return 5; default: return -EINVAL; } default: return -EINVAL; } } static int dao_rsc_reinit(struct dao *dao, const struct dao_desc *desc); static int dao_spdif_get_spos(struct dao *dao, unsigned int *spos) { ((struct hw *)dao->hw)->dao_get_spos(dao->ctrl_blk, spos); return 0; } static int dao_spdif_set_spos(struct dao *dao, unsigned int spos) { ((struct hw *)dao->hw)->dao_set_spos(dao->ctrl_blk, spos); return 0; } static int dao_commit_write(struct dao *dao) { ((struct hw *)dao->hw)->dao_commit_write(dao->hw, daio_device_index(dao->daio.type, dao->hw), dao->ctrl_blk); return 0; } static int dao_set_left_input(struct dao *dao, struct rsc *input) { struct imapper *entry; struct daio *daio = &dao->daio; int i; entry = kzalloc((sizeof(*entry) * daio->rscl.msr), GFP_KERNEL); if (!entry) return -ENOMEM; dao->ops->clear_left_input(dao); /* Program master and conjugate resources */ input->ops->master(input); daio->rscl.ops->master(&daio->rscl); for (i = 0; i < daio->rscl.msr; i++, entry++) { entry->slot = input->ops->output_slot(input); entry->user = entry->addr = daio->rscl.ops->index(&daio->rscl); dao->mgr->imap_add(dao->mgr, entry); dao->imappers[i] = entry; input->ops->next_conj(input); daio->rscl.ops->next_conj(&daio->rscl); } input->ops->master(input); daio->rscl.ops->master(&daio->rscl); return 0; } static int dao_set_right_input(struct dao *dao, struct rsc *input) { struct imapper *entry; struct daio *daio = &dao->daio; int i; entry = kzalloc((sizeof(*entry) * daio->rscr.msr), GFP_KERNEL); if (!entry) return -ENOMEM; dao->ops->clear_right_input(dao); /* Program master and conjugate resources */ input->ops->master(input); daio->rscr.ops->master(&daio->rscr); for (i = 0; i < daio->rscr.msr; i++, entry++) { entry->slot = input->ops->output_slot(input); entry->user = entry->addr = daio->rscr.ops->index(&daio->rscr); dao->mgr->imap_add(dao->mgr, entry); dao->imappers[daio->rscl.msr + i] = entry; input->ops->next_conj(input); daio->rscr.ops->next_conj(&daio->rscr); } input->ops->master(input); daio->rscr.ops->master(&daio->rscr); return 0; } static int dao_clear_left_input(struct dao *dao) { struct imapper *entry; struct daio *daio = &dao->daio; int i; if (!dao->imappers[0]) return 0; entry = dao->imappers[0]; dao->mgr->imap_delete(dao->mgr, entry); /* Program conjugate resources */ for (i = 1; i < daio->rscl.msr; i++) { entry = dao->imappers[i]; dao->mgr->imap_delete(dao->mgr, entry); dao->imappers[i] = NULL; } kfree(dao->imappers[0]); dao->imappers[0] = NULL; return 0; } static int dao_clear_right_input(struct dao *dao) { struct imapper *entry; struct daio *daio = &dao->daio; int i; if (!dao->imappers[daio->rscl.msr]) return 0; entry = dao->imappers[daio->rscl.msr]; dao->mgr->imap_delete(dao->mgr, entry); /* Program conjugate resources */ for (i = 1; i < daio->rscr.msr; i++) { entry = dao->imappers[daio->rscl.msr + i]; dao->mgr->imap_delete(dao->mgr, entry); dao->imappers[daio->rscl.msr + i] = NULL; } kfree(dao->imappers[daio->rscl.msr]); dao->imappers[daio->rscl.msr] = NULL; return 0; } static struct dao_rsc_ops dao_ops = { .set_spos = dao_spdif_set_spos, .commit_write = dao_commit_write, .get_spos = dao_spdif_get_spos, .reinit = dao_rsc_reinit, .set_left_input = dao_set_left_input, .set_right_input = dao_set_right_input, .clear_left_input = dao_clear_left_input, .clear_right_input = dao_clear_right_input, }; static int dai_set_srt_srcl(struct dai *dai, struct rsc *src) { src->ops->master(src); ((struct hw *)dai->hw)->dai_srt_set_srcm(dai->ctrl_blk, src->ops->index(src)); return 0; } static int dai_set_srt_srcr(struct dai *dai, struct rsc *src) { src->ops->master(src); ((struct hw *)dai->hw)->dai_srt_set_srco(dai->ctrl_blk, src->ops->index(src)); return 0; } static int dai_set_srt_msr(struct dai *dai, unsigned int msr) { unsigned int rsr; for (rsr = 0; msr > 1; msr >>= 1) rsr++; ((struct hw *)dai->hw)->dai_srt_set_rsr(dai->ctrl_blk, rsr); return 0; } static int dai_set_enb_src(struct dai *dai, unsigned int enb) { ((struct hw *)dai->hw)->dai_srt_set_ec(dai->ctrl_blk, enb); return 0; } static int dai_set_enb_srt(struct dai *dai, unsigned int enb) { ((struct hw *)dai->hw)->dai_srt_set_et(dai->ctrl_blk, enb); return 0; } static int dai_commit_write(struct dai *dai) { ((struct hw *)dai->hw)->dai_commit_write(dai->hw, daio_device_index(dai->daio.type, dai->hw), dai->ctrl_blk); return 0; } static struct dai_rsc_ops dai_ops = { .set_srt_srcl = dai_set_srt_srcl, .set_srt_srcr = dai_set_srt_srcr, .set_srt_msr = dai_set_srt_msr, .set_enb_src = dai_set_enb_src, .set_enb_srt = dai_set_enb_srt, .commit_write = dai_commit_write, }; static int daio_rsc_init(struct daio *daio, const struct daio_desc *desc, void *hw) { int err; unsigned int idx_l, idx_r; switch (((struct hw *)hw)->chip_type) { case ATC20K1: idx_l = idx_20k1[desc->type].left; idx_r = idx_20k1[desc->type].right; break; case ATC20K2: idx_l = idx_20k2[desc->type].left; idx_r = idx_20k2[desc->type].right; break; default: return -EINVAL; } err = rsc_init(&daio->rscl, idx_l, DAIO, desc->msr, hw); if (err) return err; err = rsc_init(&daio->rscr, idx_r, DAIO, desc->msr, hw); if (err) goto error1; /* Set daio->rscl/r->ops to daio specific ones */ if (desc->type <= DAIO_OUT_MAX) { daio->rscl.ops = daio->rscr.ops = &daio_out_rsc_ops; } else { switch (((struct hw *)hw)->chip_type) { case ATC20K1: daio->rscl.ops = daio->rscr.ops = &daio_in_rsc_ops_20k1; break; case ATC20K2: daio->rscl.ops = daio->rscr.ops = &daio_in_rsc_ops_20k2; break; default: break; } } daio->type = desc->type; return 0; error1: rsc_uninit(&daio->rscl); return err; } static int daio_rsc_uninit(struct daio *daio) { rsc_uninit(&daio->rscl); rsc_uninit(&daio->rscr); return 0; } static int dao_rsc_init(struct dao *dao, const struct daio_desc *desc, struct daio_mgr *mgr) { struct hw *hw = mgr->mgr.hw; unsigned int conf; int err; err = daio_rsc_init(&dao->daio, desc, mgr->mgr.hw); if (err) return err; dao->imappers = kzalloc(sizeof(void *)*desc->msr*2, GFP_KERNEL); if (!dao->imappers) { err = -ENOMEM; goto error1; } dao->ops = &dao_ops; dao->mgr = mgr; dao->hw = hw; err = hw->dao_get_ctrl_blk(&dao->ctrl_blk); if (err) goto error2; hw->daio_mgr_dsb_dao(mgr->mgr.ctrl_blk, daio_device_index(dao->daio.type, hw)); hw->daio_mgr_commit_write(hw, mgr->mgr.ctrl_blk); conf = (desc->msr & 0x7) | (desc->passthru << 3); hw->daio_mgr_dao_init(mgr->mgr.ctrl_blk, daio_device_index(dao->daio.type, hw), conf); hw->daio_mgr_enb_dao(mgr->mgr.ctrl_blk, daio_device_index(dao->daio.type, hw)); hw->daio_mgr_commit_write(hw, mgr->mgr.ctrl_blk); return 0; error2: kfree(dao->imappers); dao->imappers = NULL; error1: daio_rsc_uninit(&dao->daio); return err; } static int dao_rsc_uninit(struct dao *dao) { if (dao->imappers) { if (dao->imappers[0]) dao_clear_left_input(dao); if (dao->imappers[dao->daio.rscl.msr]) dao_clear_right_input(dao); kfree(dao->imappers); dao->imappers = NULL; } ((struct hw *)dao->hw)->dao_put_ctrl_blk(dao->ctrl_blk); dao->hw = dao->ctrl_blk = NULL; daio_rsc_uninit(&dao->daio); return 0; } static int dao_rsc_reinit(struct dao *dao, const struct dao_desc *desc) { struct daio_mgr *mgr = dao->mgr; struct daio_desc dsc = {0}; dsc.type = dao->daio.type; dsc.msr = desc->msr; dsc.passthru = desc->passthru; dao_rsc_uninit(dao); return dao_rsc_init(dao, &dsc, mgr); } static int dai_rsc_init(struct dai *dai, const struct daio_desc *desc, struct daio_mgr *mgr) { int err; struct hw *hw = mgr->mgr.hw; unsigned int rsr, msr; err = daio_rsc_init(&dai->daio, desc, mgr->mgr.hw); if (err) return err; dai->ops = &dai_ops; dai->hw = mgr->mgr.hw; err = hw->dai_get_ctrl_blk(&dai->ctrl_blk); if (err) goto error1; for (rsr = 0, msr = desc->msr; msr > 1; msr >>= 1) rsr++; hw->dai_srt_set_rsr(dai->ctrl_blk, rsr); hw->dai_srt_set_drat(dai->ctrl_blk, 0); /* default to disabling control of a SRC */ hw->dai_srt_set_ec(dai->ctrl_blk, 0); hw->dai_srt_set_et(dai->ctrl_blk, 0); /* default to disabling SRT */ hw->dai_commit_write(hw, daio_device_index(dai->daio.type, dai->hw), dai->ctrl_blk); return 0; error1: daio_rsc_uninit(&dai->daio); return err; } static int dai_rsc_uninit(struct dai *dai) { ((struct hw *)dai->hw)->dai_put_ctrl_blk(dai->ctrl_blk); dai->hw = dai->ctrl_blk = NULL; daio_rsc_uninit(&dai->daio); return 0; } static int daio_mgr_get_rsc(struct rsc_mgr *mgr, enum DAIOTYP type) { if (((struct daio_usage *)mgr->rscs)->data & (0x1 << type)) return -ENOENT; ((struct daio_usage *)mgr->rscs)->data |= (0x1 << type); return 0; } static int daio_mgr_put_rsc(struct rsc_mgr *mgr, enum DAIOTYP type) { ((struct daio_usage *)mgr->rscs)->data &= ~(0x1 << type); return 0; } static int get_daio_rsc(struct daio_mgr *mgr, const struct daio_desc *desc, struct daio **rdaio) { int err; struct dai *dai = NULL; struct dao *dao = NULL; unsigned long flags; *rdaio = NULL; /* Check whether there are sufficient daio resources to meet request. */ spin_lock_irqsave(&mgr->mgr_lock, flags); err = daio_mgr_get_rsc(&mgr->mgr, desc->type); spin_unlock_irqrestore(&mgr->mgr_lock, flags); if (err) { pr_err("Can't meet DAIO resource request!\n"); return err; } /* Allocate mem for daio resource */ if (desc->type <= DAIO_OUT_MAX) { dao = kzalloc(sizeof(*dao), GFP_KERNEL); if (!dao) { err = -ENOMEM; goto error; } err = dao_rsc_init(dao, desc, mgr); if (err) goto error; *rdaio = &dao->daio; } else { dai = kzalloc(sizeof(*dai), GFP_KERNEL); if (!dai) { err = -ENOMEM; goto error; } err = dai_rsc_init(dai, desc, mgr); if (err) goto error; *rdaio = &dai->daio; } mgr->daio_enable(mgr, *rdaio); mgr->commit_write(mgr); return 0; error: if (dao) kfree(dao); else if (dai) kfree(dai); spin_lock_irqsave(&mgr->mgr_lock, flags); daio_mgr_put_rsc(&mgr->mgr, desc->type); spin_unlock_irqrestore(&mgr->mgr_lock, flags); return err; } static int put_daio_rsc(struct daio_mgr *mgr, struct daio *daio) { unsigned long flags; mgr->daio_disable(mgr, daio); mgr->commit_write(mgr); spin_lock_irqsave(&mgr->mgr_lock, flags); daio_mgr_put_rsc(&mgr->mgr, daio->type); spin_unlock_irqrestore(&mgr->mgr_lock, flags); if (daio->type <= DAIO_OUT_MAX) { dao_rsc_uninit(container_of(daio, struct dao, daio)); kfree(container_of(daio, struct dao, daio)); } else { dai_rsc_uninit(container_of(daio, struct dai, daio)); kfree(container_of(daio, struct dai, daio)); } return 0; } static int daio_mgr_enb_daio(struct daio_mgr *mgr, struct daio *daio) { struct hw *hw = mgr->mgr.hw; if (DAIO_OUT_MAX >= daio->type) { hw->daio_mgr_enb_dao(mgr->mgr.ctrl_blk, daio_device_index(daio->type, hw)); } else { hw->daio_mgr_enb_dai(mgr->mgr.ctrl_blk, daio_device_index(daio->type, hw)); } return 0; } static int daio_mgr_dsb_daio(struct daio_mgr *mgr, struct daio *daio) { struct hw *hw = mgr->mgr.hw; if (DAIO_OUT_MAX >= daio->type) { hw->daio_mgr_dsb_dao(mgr->mgr.ctrl_blk, daio_device_index(daio->type, hw)); } else { hw->daio_mgr_dsb_dai(mgr->mgr.ctrl_blk, daio_device_index(daio->type, hw)); } return 0; } static int daio_map_op(void *data, struct imapper *entry) { struct rsc_mgr *mgr = &((struct daio_mgr *)data)->mgr; struct hw *hw = mgr->hw; hw->daio_mgr_set_imaparc(mgr->ctrl_blk, entry->slot); hw->daio_mgr_set_imapnxt(mgr->ctrl_blk, entry->next); hw->daio_mgr_set_imapaddr(mgr->ctrl_blk, entry->addr); hw->daio_mgr_commit_write(mgr->hw, mgr->ctrl_blk); return 0; } static int daio_imap_add(struct daio_mgr *mgr, struct imapper *entry) { unsigned long flags; int err; spin_lock_irqsave(&mgr->imap_lock, flags); if (!entry->addr && mgr->init_imap_added) { input_mapper_delete(&mgr->imappers, mgr->init_imap, daio_map_op, mgr); mgr->init_imap_added = 0; } err = input_mapper_add(&mgr->imappers, entry, daio_map_op, mgr); spin_unlock_irqrestore(&mgr->imap_lock, flags); return err; } static int daio_imap_delete(struct daio_mgr *mgr, struct imapper *entry) { unsigned long flags; int err; spin_lock_irqsave(&mgr->imap_lock, flags); err = input_mapper_delete(&mgr->imappers, entry, daio_map_op, mgr); if (list_empty(&mgr->imappers)) { input_mapper_add(&mgr->imappers, mgr->init_imap, daio_map_op, mgr); mgr->init_imap_added = 1; } spin_unlock_irqrestore(&mgr->imap_lock, flags); return err; } static int daio_mgr_commit_write(struct daio_mgr *mgr) { struct hw *hw = mgr->mgr.hw; hw->daio_mgr_commit_write(hw, mgr->mgr.ctrl_blk); return 0; } int daio_mgr_create(void *hw, struct daio_mgr **rdaio_mgr) { int err, i; struct daio_mgr *daio_mgr; struct imapper *entry; *rdaio_mgr = NULL; daio_mgr = kzalloc(sizeof(*daio_mgr), GFP_KERNEL); if (!daio_mgr) return -ENOMEM; err = rsc_mgr_init(&daio_mgr->mgr, DAIO, NUM_DAIOTYP, hw); if (err) goto error1; spin_lock_init(&daio_mgr->mgr_lock); spin_lock_init(&daio_mgr->imap_lock); INIT_LIST_HEAD(&daio_mgr->imappers); entry = kzalloc(sizeof(*entry), GFP_KERNEL); if (!entry) { err = -ENOMEM; goto error2; } entry->slot = entry->addr = entry->next = entry->user = 0; list_add(&entry->list, &daio_mgr->imappers); daio_mgr->init_imap = entry; daio_mgr->init_imap_added = 1; daio_mgr->get_daio = get_daio_rsc; daio_mgr->put_daio = put_daio_rsc; daio_mgr->daio_enable = daio_mgr_enb_daio; daio_mgr->daio_disable = daio_mgr_dsb_daio; daio_mgr->imap_add = daio_imap_add; daio_mgr->imap_delete = daio_imap_delete; daio_mgr->commit_write = daio_mgr_commit_write; for (i = 0; i < 8; i++) { ((struct hw *)hw)->daio_mgr_dsb_dao(daio_mgr->mgr.ctrl_blk, i); ((struct hw *)hw)->daio_mgr_dsb_dai(daio_mgr->mgr.ctrl_blk, i); } ((struct hw *)hw)->daio_mgr_commit_write(hw, daio_mgr->mgr.ctrl_blk); *rdaio_mgr = daio_mgr; return 0; error2: rsc_mgr_uninit(&daio_mgr->mgr); error1: kfree(daio_mgr); return err; } int daio_mgr_destroy(struct daio_mgr *daio_mgr) { unsigned long flags; /* free daio input mapper list */ spin_lock_irqsave(&daio_mgr->imap_lock, flags); free_input_mapper_list(&daio_mgr->imappers); spin_unlock_irqrestore(&daio_mgr->imap_lock, flags); rsc_mgr_uninit(&daio_mgr->mgr); kfree(daio_mgr); return 0; }